JP7390752B2 - gaming machine - Google Patents

Description

The present invention relates to a gaming machine.

Conventionally, a gaming machine called a pachinko gaming machine has been known, and this pachinko gaming machine generally has a gaming area in which game balls fired onto the gaming board can roll, and a starting area provided in this gaming area. , a symbol display device, and variable display control means for controlling the symbol display device. In such a gaming machine, when a predetermined condition such as the game ball passing through the starting area (the game ball enters the starting hole) is satisfied, the variable display control means controls the symbol display device to display the symbol display device. Identification information (for example, special symbols to be described later) is displayed in a variable manner on the display area. Then, when the identification information finally derived and displayed on the display area of the symbol display device becomes a predetermined combination (specific display mode), the gaming state becomes a jackpot gaming state advantageous to the player (so-called "jackpot"). ”).

Furthermore, conventionally, a pachinko gaming machine is known that is equipped with a plurality of symbol display devices (display areas) and has a function that allows the plurality of symbol display devices to simultaneously display identification information in a variable manner (for example, see Patent Document 1). ).

Japanese Patent Application Publication No. 2015-150303

By the way, the gaming machine described above usually has a main control board on which a circuit (main control circuit) for controlling main gaming operations such as determination of identification information is mounted, and a circuit (main control circuit) for controlling performance operations such as displaying images. and a sub-control board on which a sub-control circuit (sub-control circuit) is mounted. The gaming operation is controlled by a CPU (Central Processing Unit) installed in the main control circuit. At this time, under the control of the CPU, programs and various table data stored in the ROM (Read Only Memory) of the main control circuit are expanded to the RAM (Random Access Memory) of the main control circuit, and processing related to various gaming operations is executed. be done. In recent years, in such gaming machines, there has been a demand for reducing the capacity of processing programs managed by the main control circuit.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a gaming machine that can reduce the capacity of processing programs managed by a main control circuit.

In order to achieve the above object, the present invention provides the following gaming machine.

Triggered by the establishment of a predetermined starting condition (for example, winning of the first starting hole 6044 or second starting hole 6045 described later), identification information (for example, the first special symbol or second special symbol described later) is displayed in a variable manner. Identification information display means (for example, a first special symbol display device 6061 or a second special symbol display device 6062 described later),
a first arithmetic processing means (for example, a main CPU 6101 to be described later) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
a storage means (for example, a main RAM 6103 described below) in which information necessary for the execution of the arithmetic processing by the first arithmetic processing means is stored;
a storage means (for example, an IY register to be described later) capable of storing specific information when the first arithmetic processing means executes the arithmetic processing;
When the first arithmetic processing means performs arithmetic processing for controlling the operation of changing display of the identification information, the first arithmetic processing means stores a part of the area in the storage means in which information used for the arithmetic processing is stored. (For example, a special symbol work area table described below) is stored in the storage means, and based on the address information stored in the storage means, information necessary for the arithmetic processing is read from the storage means;
The information used for the arithmetic processing stored in a part of the storage means includes a count value of a timer that manages a fluctuating display time of the identification information,
Unlike the first arithmetic processing means, the apparatus further includes a second arithmetic processing means (for example, a sub-control circuit 200 described below) capable of performing arithmetic processing according to the result of the arithmetic processing of the first arithmetic processing means. ,
The second arithmetic processing means
It is possible to generate input information based on the input state of the operating means and to manage the generated input information,
After the input information is generated, the input information can be generated as long as the input state of the operating means continues for a predetermined period of time (for example, 4 frames described below);
Specific control can be executed on the condition that the input information has been generated,
The generation of the input information and the bank flip of the frame buffer are performed within a specific process (for example, a sub-control main process to be described later) that can be repeatedly executed at a predetermined cycle (for example, an FPS cycle to be described later),
A gaming machine characterized in that the generation of the input information can be executed within one time of the specific processing before a bank flip of the frame buffer is completed.

According to the gaming machine of the present invention having the above configuration, it is possible to reduce the capacity of the processing program managed by the main control circuit.

1 is an example of a perspective view showing the appearance of a pachinko gaming machine according to a first embodiment of the present invention. 1 is an example of an exploded perspective view showing the external appearance of a pachinko gaming machine according to a first embodiment of the present invention. 1 is an example of a diagram showing a group of operation buttons of the pachinko game machine according to the first embodiment of the present invention. 1 is a perspective view showing a pachinko game machine according to a first embodiment of the present invention from the back side. 1 is an example of a front view showing the appearance of a game board unit in a pachinko game machine according to a first embodiment of the present invention. 1 is an example showing an external perspective view of a game board unit in a pachinko game machine according to a first embodiment of the present invention. It is an example which shows the front exploded perspective view of the game board unit in the pachinko game machine based on the 1st embodiment of this invention seen from diagonally upper right. It is an example of the front view which shows the LED unit containing the 1st and 2nd special symbol display part. It is an example of a block diagram showing a main control circuit. FIG. 2 is a block diagram showing the internal configuration of a sub-control circuit of the pachinko gaming machine according to the first embodiment of the present invention. FIG. 2 is a block diagram showing the internal configuration of the audio/LED control circuit of the pachinko gaming machine according to the first embodiment of the present invention. FIG. 3 is a diagram for explaining an example of an output signal of the audio/LED control circuit in the pachinko gaming machine according to the first embodiment of the present invention. FIG. 2 is a control block diagram for explaining an example of volume control by the host control circuit in the pachinko gaming machine according to the first embodiment of the present invention. 1 is a schematic connection configuration diagram between a built-in relay board and a speaker of a pachinko game machine according to a first embodiment of the present invention; FIG. 1 is a block diagram showing the internal configuration of a display control circuit of a pachinko gaming machine according to a first embodiment of the present invention. FIG. FIG. 2 is a schematic connection configuration diagram between a sub-board and a CGROM board (NOR type) of the pachinko gaming machine according to the first embodiment of the present invention. 1 is a schematic connection configuration diagram between a sub-board and a CGROM board (NAND type) of a pachinko gaming machine according to a first embodiment of the present invention. It is a truth table for explaining the operation of the AND circuit provided on the sub-board of the pachinko game machine according to the first embodiment of the present invention. It is a truth table for explaining the operation of the bidirectional balance transceiver provided on the sub-board of the pachinko game machine according to the first embodiment of the present invention. It is a diagram showing a functional flow of the pachinko gaming machine according to the first embodiment of the present invention. It is a diagram showing an example of a table showing the probability of a jackpot in a pachinko game machine. It is a diagram showing an example of the selection rate of the main symbol when the result of the jackpot determination of the special symbol is a jackpot. It is a diagram showing an example of a special symbol variation time determination table stored in the main ROM. It is a figure which shows an example of the decorative pattern determination table memorize|stored in the sub main ROM of a sub control circuit. It is a figure which shows the other example of the variation time determination table of a special symbol memorize|stored in main ROM. It is a diagram showing a first modification regarding the selection rate of the main symbol when the result of the jackpot determination of the special symbol is a jackpot. It is a diagram showing a second modification regarding the selection rate of the main symbol when the result of the jackpot determination of the special symbol is a jackpot. This is a modification of the decorative symbol determination table stored in the sub-main ROM of the sub-control circuit. FIG. 2 is a diagram for explaining an overview of drawing control processing in the pachinko gaming machine according to the first embodiment of the present invention. 3 is a flowchart illustrating an example of power-on processing by the main CPU. 3 is a flowchart illustrating an example of power-on processing. It is a flowchart showing an example of game permission processing. (a) A flowchart showing an example of a setting process, and (b) a flowchart showing another example of a setting process. 3 is a flowchart illustrating an example of a setting change process. 3 is a flowchart illustrating an example of backup clear processing. 3 is a flowchart illustrating an example of setting confirmation processing. It is a flowchart showing an example of game return processing. It is a flowchart which shows an example of abnormality processing. 3 is a flowchart illustrating an example of processing when a power outage occurs. 3 is a flowchart illustrating an example of system timer interrupt processing by the main CPU. 3 is a flowchart illustrating an example of switch input detection processing performed by the main CPU. It is a flowchart showing an example of starting opening winning detection processing by the main CPU. 3 is a flowchart illustrating an example of a setting check process performed by the main CPU. 3 is a flowchart illustrating an example of main control main processing by a main CPU. It is a flowchart showing an example of special symbol control processing by the main CPU. It is a flowchart showing an example of special symbol storage check processing by the main CPU. It is a flowchart showing an example of special symbol display time management processing by the main CPU. It is a flowchart which shows an example of time saving number subtraction processing by a main CPU. It is a flowchart showing an example of jackpot end interval processing by the main CPU. 3 is a flowchart illustrating an example of a variation pattern table setting process by the main CPU. It is a flowchart showing an example of normal symbol control processing by the main CPU. 3 is a flowchart illustrating an example of sub-control main processing executed by a host control circuit (sub-control circuit). 3 is a flowchart illustrating an example of command analysis processing executed by a host control circuit (sub control circuit). 3 is a flowchart illustrating an example of a command transmission process executed by a host control circuit (sub control circuit). 3 is a flowchart illustrating an example of message setting processing executed by a host control circuit (sub control circuit). 3 is a flowchart illustrating an example of a directory table registration process executed by a host control circuit (sub control circuit). 3 is a flowchart illustrating an example of message transmission processing executed by a host control circuit (sub control circuit). It is a table showing an example of the selection rate of the limiter number of times in the pachinko game machine of expansion example 1 for each set value. In the Pachinko game machine of Expansion Example 4, it is a diagram showing an example of a mode in which a game ball passes through the accessory continuous operation right gate. In the Pachinko game machine of Expansion Example 4, it is a diagram showing an example of a mode in which a game ball passes through the accessory continuous operation left gate. It is a flowchart showing an example of sub-control main processing executed by the host control circuit (sub-control circuit) in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of timer interrupt processing executed by the host control circuit (sub control circuit) in the pachinko gaming machine according to the first embodiment of the present invention. FIG. 2 is a diagram illustrating an example of sub-device input discrimination information created in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of sub-device input processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of sub-device input ON edge information (with repeat function) processing in the pachinko gaming machine according to the first embodiment of the present invention. This is a flowchart continuing from FIG. 65, showing an example of sub-device input ON edge information (with repeat function) processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a diagram for conceptually explaining backlight control processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flow chart showing an example of backlight control processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of timer interrupt processing in accordance with a modified example of backlight control processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing a modification of backlight control processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of timer interrupt processing showing backlight control processing in the pachinko gaming machine according to the first embodiment of the present invention. In the pachinko gaming machine according to the first embodiment of the present invention, sub-control main processing (overall flow) executed by the host control circuit to explain the first example of the processing for adjusting the brightness of the backlight and various LEDs. It is. In the pachinko gaming machine according to the first embodiment of the present invention, sub-control main processing (overall flow) executed by the host control circuit for explaining a second embodiment of the processing of brightness adjustment of the backlight and various LEDs It is. In the pachinko game machine according to the first embodiment of the present invention, sub-control main processing (overall flow) executed by the host control circuit for explaining the third embodiment of the processing for adjusting the brightness of the backlight and various LEDs It is. It is a flowchart showing an example of RTC acquisition processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of animation control main processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of composition playback control processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of sound amplifier check processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of normal amplifier check processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flow chart showing an example of deep bass amplifier check processing in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of a sound amplifier check process for performing a normal amplifier/deep bass amplifier (batch) check process in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of a more preferable form of sound amplifier check processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of a more preferable form of normal amplifier/deep bass amplifier check processing in the pachinko game machine according to the first embodiment of the present invention. 83 is a flowchart continuing from FIG. 83, showing an example of a more preferred form of normal amplifier/deep bass amplifier check processing in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of sound request control processing when there are multiple sound requests for the same channel in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing a first example of sound request control processing when volume adjustment is performed in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing a second example of sound request control processing when volume adjustment is performed in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing a third example of sound request control processing when volume adjustment is performed in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing a fourth example of sound request control processing when volume adjustment is performed in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing a fifth example of sound request control processing when volume adjustment is performed in the pachinko game machine according to the first embodiment of the present invention. In the pachinko game machine according to the first embodiment of the present invention, it is an attenuation table showing an example of brightness attenuation values of each color (red, green, blue) according to the light emission intensity of strong, medium, and weak LEDs. FIG. 2 is a block diagram showing an example of a connection state between an LED port, an LED, and a solenoid in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of a data load process executed as one of various initialization processes by the host control circuit in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of a random number initialization process executed as one of various initialization processes by the host control circuit in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of random number periodic update processing in the pachinko gaming machine according to the first embodiment of the present invention. (a) A flowchart showing an example of the random number 1 acquisition process, (b) A flowchart showing an example of the random number 2 acquisition process, and (c) an example of the random number 3 acquisition process in the pachinko game machine according to the first embodiment of the present invention. (d) is a flowchart showing an example of random number 4 acquisition processing. It is a flowchart showing an example of a random number acquisition process executed when a random number is used in the pachinko gaming machine according to the first embodiment of the present invention. This is a sub-control main process (overall flow) executed by the host control circuit for explaining a modification of the sub-random number process in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of reception interrupt processing executed by the host control circuit in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of accessory initial operation processing executed by the host control circuit as one of various initialization processing in the pachinko gaming machine according to the first embodiment of the present invention. It is a flowchart showing an example of accessory control processing for accessory objects executed by the host control circuit in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart which shows an example of the process at the time of receiving a performance-related command. It is a flowchart showing an example of a process executed by the host control circuit when receiving a fluctuation start command regarding an accessory in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of an initial position restoration operation process for an accessory executed by a host control circuit in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of a process executed by the host control circuit when receiving a demo command regarding an accessory in the pachinko game machine according to the first embodiment of the present invention. 2 is a flowchart illustrating an example of a process executed by the host control circuit when receiving a change confirmation command regarding an accessory in the pachinko game machine according to the first embodiment of the present invention. It is a flowchart showing an example of a process executed by the host control circuit when receiving a winning command regarding an accessory in the pachinko game machine according to the first embodiment of the present invention. 3 is a flowchart illustrating an example of a hole menu task executed by a sub CPU. FIG. 6 is a diagram showing an example of a hall menu screen displayed in a display area of a liquid crystal display device. It is an example of a hall menu screen displayed in the display area of a liquid crystal display device when hall menu display processing is executed. It is an example of a hall menu screen displayed in the display area of a liquid crystal display device when hall menu display processing is executed. FIG. 6 is a diagram showing an example of a hall menu screen displayed in the display area of the liquid crystal display device when hall menu redisplay processing is executed. This is an example of a screen in which error details are displayed in the display area of the liquid crystal display device, (a) a screen indicating that backup clear processing without setting change processing has been executed, and (b) a starting port abnormal winning error has occurred. (c) A screen showing that the backup clear process that did not involve the setting change process was executed, and (c) that both the backup clear process that did not involve the setting change process and the abnormal start error occurred. This is the screen after the notification period indicating that backup clear processing has been executed has elapsed. 12 is a flowchart illustrating another example of the hall menu task executed by the host control circuit, in which the host control circuit executes a setting determination process for determining the suitability of setting value information. 3 is a flowchart illustrating an example of hall menu processing executed by a sub CPU. It is an example of an error information history screen displayed in the display area of a liquid crystal display device. 3 is a flowchart illustrating an example of a setting change/confirmation history process executed by a sub CPU. 118 is an example of a setting change/confirmation history process executed by the sub CPU, and is a flowchart continued from FIG. 117. FIG. FIG. 6 is a diagram illustrating an example of an initial screen of a setting change/confirmation history screen displayed in a display area of a liquid crystal display device. It is a figure which shows an example when "Page" is selected on a setting change/confirmation history screen. FIG. 6 is a diagram illustrating an example of a page update screen on which a page can be updated on a setting change/confirmation history screen. FIG. 7 is a diagram illustrating an example when "clear" is selected on the setting change/confirmation history screen. FIG. 7 is a diagram illustrating an example of a data clear screen where each history data is cleared on the setting change/confirmation history screen. FIG. 7 is another example of a setting change/confirmation history screen displayed in the display area of the liquid crystal display device, and is a diagram showing an example of an initial screen. FIG. 7 is another example of a setting change/confirmation history screen displayed in the display area of the liquid crystal display device, and is a diagram illustrating an example when "setting display" is selected. FIG. 7 is another example of the setting change/confirmation history screen displayed in the display area of the liquid crystal display device, and is a diagram illustrating an example when newly added setting values are displayed. FIG. 7 is another example of a setting change/confirmation history screen displayed in the display area of the liquid crystal display device, and is a diagram illustrating an example when "Page" is selected. FIG. 7 is a diagram illustrating an example of a page update screen that is another example of a setting change/confirmation history screen displayed in the display area of the liquid crystal display device and allows page updates. FIG. 7 is a flowchart illustrating an example of an operation procedure until a setting change/confirmation history screen on which setting values can be checked is displayed on a hall menu screen displayed in a display area of a liquid crystal display device. 3 is a flowchart illustrating an example of maintenance processing executed by a sub CPU. FIG. 6 is a diagram illustrating an example of a maintenance screen displayed in a display area of a liquid crystal display device. It is an example of the maintenance screen displayed on the display area of a liquid crystal display device. FIG. 6 is a diagram illustrating an example when a guide initial image is displayed in a display area of a liquid crystal display device. FIG. 6 is a diagram illustrating an example of a UniMemo initial image displayed in the display area of the liquid crystal display device. FIG. 6 is a diagram showing an example when a password request screen is displayed in the display area of the liquid crystal display device. It is a flowchart which shows the modification 1 of the setting change/confirmation history process performed by sub CPU. 12 is a flowchart illustrating an example of authentication processing in modification example 1 of setting change/confirmation history processing executed by the sub CPU. 2 is a diagram illustrating an example in which a password request screen is displayed in the display area of the liquid crystal display device when the setting change/confirmation history process is executed in modification example 1 of the setting change/confirmation history process executed by the sub CPU. be. This is an example of a password request screen displayed in the display area of the liquid crystal display device in modification example 1 of the setting change/confirmation history process executed by the sub CPU. FIG. 7 is a diagram showing an example of a screen displayed in the display area of the liquid crystal display device when the input password is inappropriate in modification example 1 of the setting change/confirmation history process executed by the sub CPU. In the hall menu screen displayed in the display area of the display device 16 in modification example 1 of the setting change/confirmation history process executed by the sub CPU, a setting change/confirmation history screen that allows the setting values to be confirmed is displayed. FIG. 3 is a flow diagram showing an example of the operating procedure until FIG. 7 is a diagram showing an example of the configuration of a volume switch that generates a volume password applied to authentication processing in a second modification of setting change/confirmation history processing executed by a sub CPU. 12 is a flowchart illustrating an example of authentication processing in modification example 2 of setting change/confirmation history processing executed by the sub CPU. 2 is a diagram illustrating an example in which a password request screen is displayed in the display area of the liquid crystal display device when the setting change/confirmation history process is executed in modification example 2 of the setting change/confirmation history process executed by the sub CPU. be. This is an example of a volume password request display screen displayed in the display area of the liquid crystal display device in modification example 2 of the setting change/confirmation history process executed by the sub CPU. FIG. 12 is a flow diagram illustrating an example of a setting value confirmation procedure for setting change/confirmation history information in a second modification of the setting change/confirmation history process executed by the sub CPU. It is a figure showing the example of composition of the game system concerning modification 3 of the setting change/confirmation history processing performed by sub CPU. 12 is a flowchart showing an example of a setting change/confirmation history process in a pachinko gaming machine that constitutes a gaming system according to modification 3. 12 is a flowchart illustrating an example of a setting change/confirmation history process in a portable wireless communication terminal and a server device of a gaming system according to modification 3. 12 is a diagram showing an example of a setting change/confirmation history screen including a two-dimensional code in a pachinko game machine of a gaming system according to modification 3. FIG. 12 is a flow diagram showing an example of a setting value confirmation procedure for setting change/confirmation history information in a gaming system according to modification example 3. FIG. FIG. 12 is a diagram showing an example of a two-dimensional code display screen on a mobile wireless communication terminal of a gaming system according to modification example 3. FIG. 7 is a diagram showing an example of a password input screen on a portable wireless communication terminal of a gaming system according to Modification 3. FIG. 12 is a diagram showing an example of a setting change/confirmation history screen in a portable wireless communication terminal of a gaming system according to modification 3. It is a diagram showing a functional flow of a pachinko gaming machine according to a second embodiment of the present invention. FIG. 7 is a diagram showing an example of a variation pattern table that can be used in the second embodiment. It is an external perspective view seen from the front side of the pachinko game machine concerning the 2nd embodiment of the present invention. FIG. 2 is an exploded perspective view of a pachinko game machine according to a second embodiment of the present invention. FIG. 3 is an external perspective view of a pachinko game machine according to a second embodiment of the present invention, seen from the back side. FIG. 3 is a front view showing the configuration of a game board of a pachinko game machine according to a second embodiment of the present invention. It is a block diagram showing a circuit configuration of a pachinko gaming machine according to a second embodiment of the present invention. FIG. 2 is a block diagram showing the internal configuration of a sub-control circuit of a pachinko gaming machine according to a second embodiment of the present invention. It is a block diagram of the various registers which the main CPU of the pachinko game machine based on the 2nd Embodiment of this invention has. It is a figure showing the memory map of the main control circuit of the pachinko game machine concerning the 2nd embodiment of the present invention. In the pachinko game machine according to the second embodiment of the present invention, it is a diagram showing an example of the operation of variable display of each special symbol when the simultaneous variation function is activated. It is a figure which shows an example of the 1st special symbol work area table in the 2nd Embodiment of this invention. It is a figure which shows an example of the 1st special symbol related definition data table in the 2nd Embodiment of this invention. It is a figure which shows an example of the 2nd special symbol work area table in the 2nd Embodiment of this invention. It is a figure which shows an example of the 2nd special symbol related definition data table in the 2nd Embodiment of this invention. It is a figure which shows the modification of the 1st special symbol work area table in the 2nd Embodiment of this invention. It is a flowchart showing an example of external maskable interrupt processing executed by the main CPU in the pachinko gaming machine according to the second embodiment of the present invention. It is a flowchart showing an example of system timer interrupt processing executed by the main CPU in the pachinko gaming machine according to the second embodiment of the present invention. It is a flow chart which shows an example of setting control processing in a 2nd embodiment of the present invention. It is a flow chart which shows an example of setting change processing in a 2nd embodiment of the present invention. It is a flow chart which shows an example of setting confirmation processing in a 2nd embodiment of the present invention. It is a flowchart showing an example of the first normal game pre-processing in the second embodiment of the present invention. It is a flowchart showing an example of the second normal game pre-processing in the second embodiment of the present invention. It is a flow chart which shows an example of switch input detection processing in a 2nd embodiment of the present invention. It is a flow chart which shows an example of abnormal state monitoring processing in a 2nd embodiment of the present invention. It is a flow chart which shows an example of abnormal state monitoring pre-processing in a 2nd embodiment of the present invention. It is a flow chart which shows an example of general-purpose abnormality detection judgment processing in a 2nd embodiment of the present invention. It is a flowchart (part 1) showing an example of main control main processing executed by the main CPU in the pachinko gaming machine according to the second embodiment of the present invention. It is a flowchart (part 2) showing an example of main control main processing executed by the main CPU in the pachinko gaming machine according to the second embodiment of the present invention. It is a flowchart (part 3) showing an example of main control main processing executed by the main CPU in the pachinko gaming machine according to the second embodiment of the present invention. It is a flowchart (part 4) showing an example of main control main processing executed by the main CPU in the pachinko gaming machine according to the second embodiment of the present invention. It is a flow chart which shows an example of wait processing in a 2nd embodiment of the present invention. It is a flowchart which shows an example of the initialization process at the time of startup in the 2nd Embodiment of this invention. It is a flow chart which shows an example of setting operation pre-processing in a 2nd embodiment of the present invention. It is a flow chart which shows an example of power interruption processing in a 2nd embodiment of the present invention. It is a flowchart (Part 1) showing an example of special symbol control processing in the second embodiment of the present invention. It is a flowchart (Part 2) showing an example of special symbol control processing in the second embodiment of the present invention. It is a flowchart which shows an example of the special symbol related timer update process in the 2nd Embodiment of this invention. It is a flowchart showing an example of special symbol management processing in the second embodiment of the present invention. It is a flowchart showing an example of special symbol variation start processing in the second embodiment of the present invention. It is a flowchart showing an example of special symbol game standby processing in the second embodiment of the present invention. It is a flowchart (Part 1) showing an example of the special symbol variation end process in the second embodiment of the present invention. It is a flowchart (part 2) showing an example of the special symbol variation end process in the second embodiment of the present invention. It is a flowchart (Part 1) showing an example of special symbol game determination processing in the second embodiment of the present invention. It is a flowchart (Part 2) showing an example of special symbol game determination processing in the second embodiment of the present invention. It is a flowchart showing an example of special symbol game end processing in the second embodiment of the present invention. It is a flowchart which shows an example of big prize opening preparation processing in the 2nd embodiment of the present invention. It is a flowchart showing an example of the big prize opening control process in the second embodiment of the present invention. It is a flowchart which shows an example of the end process per special symbol in the 2nd Embodiment of this invention. It is a flowchart showing an example of normal symbol control processing in the second embodiment of the present invention. It is a flowchart which shows an example of special symbol management processing in the 3rd embodiment of the present invention. It is a flowchart which shows an example of special symbol fluctuation start processing in a 3rd embodiment of the present invention. It is a flowchart showing an example of special symbol game standby processing in the third embodiment of the present invention. It is a flowchart which shows an example of special symbol falling judgment processing in a 3rd embodiment of the present invention. It is a flowchart which shows an example of special symbol production mode management processing in the 3rd embodiment of the present invention. It is a diagram showing the configuration of a special symbol variation pattern selection table selection data table, a special symbol variation pattern selection table group, and a special symbol variation pattern selection offset table used in another example of the production variation table selection method. It is a flowchart showing an example of special symbol game state setting processing in the third embodiment of the present invention. It is a flowchart which shows an example of special symbol fluctuation end processing in a 3rd embodiment of the present invention. It is a flowchart (Part 1) showing an example of special symbol game determination processing in the third embodiment of the present invention. It is a flowchart (part 2) showing an example of special symbol game determination processing in the third embodiment of the present invention. It is a flowchart showing an example of gaming state management processing in the third embodiment of the present invention. It is a flowchart showing an example of special symbol game end processing in the third embodiment of the present invention. It is a flowchart which shows an example of the end process per special symbol in the 3rd embodiment of this invention.

A. First Embodiment Hereinafter, the configuration and various operations of a pachinko gaming machine (gaming machine) according to a first embodiment of the present invention will be explained with reference to the drawings.

[1. Configuration of gaming machine]
[1-1. Exterior configuration]
First, the appearance of the pachinko gaming machine 1 will be explained using FIGS. 1 to 8. FIG. 1 is an example of a perspective view showing the appearance of a pachinko gaming machine according to a first embodiment of the present invention. FIG. 2 is an example of an exploded perspective view showing the external appearance of the pachinko gaming machine according to the first embodiment of the present invention. FIG. 3 is a diagram schematically showing an example of a group of operation buttons. FIG. 4 is an example of a perspective view showing the pachinko game machine according to the first embodiment of the present invention from the back side. FIG. 5 is an example of a front view showing the appearance of the game board unit in the pachinko game machine according to the first embodiment of the present invention. FIG. 6 is an example showing an external perspective view of the game board unit in the pachinko game machine according to the first embodiment of the present invention. FIG. 7 is an example showing an exploded perspective view of the game board unit in the pachinko game machine according to the first embodiment of the present invention, viewed diagonally from above and to the front right. FIG. 8 is an example of a front view showing an LED unit including the first and second special symbol display sections. Further, the directions shown in the drawings are the directions when viewed from the front. Therefore, for example, the reason why "left" is written in the right direction in the drawing is because the drawing is a rear view, and "right" on the drawing corresponds to "left" when viewed from the front. Similarly, when "right" is written toward the left in the drawing, "left" in the drawing becomes "right" when viewed from the front for the same reason.

In the following description, unless otherwise specified, the front and rear directions of the pachinko game machine 1 will be defined with the front side as the front side and the back side as the rear side when viewed from the player. Further, when the pachinko game machine 1 is viewed from the player, the left-hand side is defined as the left side, and the right-hand side is defined as the right side, and the left-right direction is defined. Further, the front side is the side that is visible when viewed from the player's side, and the back side is the side that is visible when viewed from the side opposite to the player.

As shown in FIGS. 1, 2, and 4 to 7, the pachinko game machine 1 includes a wooden frame 11, a base door 12, a glass door 13, a tray unit 14, a firing device 15, a display device 16, and a game board unit 17. , a payout unit 18, and a board unit 19.

The wooden frame 11 is a generally rectangular frame when viewed from the front. The wooden frame 11 is provided with an opening 21 that penetrates in the front-rear direction. The base door 12 is fitted into the opening 21 of the wooden frame 11. The base door 12 supports various members. Specifically, the base door 12 supports a payout unit 18 and a board unit 19 on the back side, and supports a glass door 13, a tray unit 14, a firing device 15, a display device 16, and a game board unit 17 on the front side. To support.

The glass door 13 is pivoted to the base door 12 so as to be freely openable and closable. The glass door 13 is provided with an opening 22 and a group of operation buttons 66. A transparent protective glass 23 is disposed in the opening 22 of the glass door 13 . The protective glass 23 is arranged so as to face a game board unit 17, which will be described later, in the front-rear direction with the glass door 13 closed with respect to the base door 12. Furthermore, a speaker 24 and an LED 25 are arranged at the top of the glass door 13. The speaker 24 is used to make, for example, audio announcements, presentations, error notifications, and the like. The LED 25 is, for example, a light-emitting means for making a light announcement or a performance, and is not limited to an LED, but may be a lamp, etc., as long as it can perform a light-emission performance.

As shown in FIG. 3, the operation button group 66 includes a main button 662 and a select button 664. The select buttons 664 include an upper select button 664a, a lower select button 664b, a left select button 664c, and a right select button 664d. In the following, when the select button 664 is referred to, it is a general term for the upper, lower, left, and right select buttons 664a to 664d.

The pachinko gaming machine 1 of this embodiment can be operated on a guide menu screen, a hall menu screen, etc., which will be described later, by using at least one or both of the main button 662 and the select button 664. Note that the position where the operation button group 66 is provided is not limited to the glass door 13, and may be provided on the pan unit 14, for example, on the upper tray 26.

The plate unit 14 is a unit body in which an upper plate 26 and a lower plate 27 are integrated. The pan unit 14 is arranged at the front lower part of the base door 12 and below the glass door 13.

The upper tray 26 stores game balls, and the game balls stored in the upper tray 26 are fired from the firing device 15 toward a game area 20, which will be described later. The upper tray 26 is provided with a payout opening 61 and a production button 62. Game balls to be lent out and game balls to be paid out as prize balls are paid out from the payout opening 61 onto the upper tray 26. The effect button 62 is a so-called "CHANCE button", a "push button", or the like. The performance button 62 may have a predetermined performance function in addition to the operation function operated by the player. The predetermined performance function corresponds to, for example, a function of projecting upward based on the result of a jackpot determination of a special symbol, which will be described later.

The lower tray 27 is mainly for storing game balls overflowing from the upper tray 26. A dispensing port 63 is provided in the lower tray 27. The game balls overflowing from the upper tray 26 are paid out from the payout opening 63 to the lower tray 27.

The firing device 15 is for firing game balls stored in the upper tray 26 toward the game area 20. The firing device 15 is disposed at the front lower right of the base door 12 and at the lower right of the dish unit 14. The firing device 15 includes a panel body 31, a drive device (not shown), and a firing handle 32.

The panel body 31 is integrated with the lower right portion of the dish unit 14 in the firing device 15. The firing handle 32 is arranged on the front side of the panel body 31. The drive device is arranged on the back side of the panel body 31, and is constituted by, for example, a firing solenoid (not shown). In this way, in the firing device 15, when the firing handle 32 is operated by the player, the game ball is fired by the operation of the driving device according to the operation.

The display device 16 displays the results of special symbol jackpot determination (hereinafter, the special symbol jackpot determination may simply be referred to as "jackpot determination") and various performance images related to the game, such as a liquid crystal display. A device is used. The various performance images displayed in the display area of the display device 16 include, for example, a performance identification pattern (decorative pattern), a performance image according to the result of jackpot determination, a performance image during a jackpot, a demonstration performance image, and a special performance image. Includes the number of pending symbols, etc. for variable display (variable display). The display device 16 (for example, a display area of a liquid crystal display device) is arranged approximately at the center of the game board unit 17 (on the inner circumferential side of a center rail 1742, which will be described later).

Note that in this embodiment, one display device 16 is provided for displaying the various effect images described above, but two liquid crystal display devices are provided and the effect images are displayed using the two liquid crystal display devices. You may also do so.

Further, as shown in FIG. 4, the pachinko gaming machine 1 of the present embodiment includes a main control board 30 having a main control circuit 100 (see FIG. 9, which will be described later), and a sub-control circuit 200 (see FIG. 9, which will be described later). a payout/launch control board 50 that has a payout/launch control circuit 300 (see FIG. 9 described below) that controls the payout/launch of game balls, and a power supply circuit 338 that supplies power (described later). A power supply unit 60 having a power source (see FIG. 9), a power switch 35, and a backup clear switch 330 (see FIG. 9, which will be described later) are provided.

In this embodiment, the sub-control board 40 is configured as a one-board board (a board in which one control LSI or a plurality of LSIs is provided on one board); however, the sub-control board 40 is not limited to this; (For example, the host control circuit 2100, the audio/LED control circuit 2200, the display control circuit 2300, etc.) may be configured.

The pachinko game machine 1 of this embodiment is provided with a plurality of setting values (in this embodiment, six levels from "1" to "6") that differ in various data related to the pachinko game. The setting "6" is most advantageous to the player, and as the setting value becomes smaller, the degree of advantage to the player becomes progressively lower.

Inside the main board case that houses the main control board 30, there is a setting switch 332 that is operated when changing setting values, a setting key 328 that is operated when changing or confirming setting values, and a performance display monitor. 334 and an error notification monitor 336 (both of which will be described later in FIG. 9) are housed therein. The performance display monitor 334 displays, for example, performance display data and setting values, which will be described later. For example, an error code, which will be described later, is displayed on the error notification monitor 336. Note that the setting switch 332 and the setting key 328 are housed in the main control board case by the person in charge of managing the pachinko game machine 1 (hereinafter referred to as "the person in charge of managing the game machine") in consideration of security. ) This is to prevent a third party (for example, a player) other than the player from easily accessing the setting switch 332 and the setting key 328. Note that inside the main board case means that the setting switch 332 and/or setting key 328 cannot be accessed unless the main board case is opened, and also that there is a switch in the corresponding location of the setting switch 332 and setting key 328 on the main board case. If there is a chip and the pachinko machine 1 is rotated from the island equipment where the pachinko machine 1 is installed using a key managed by the machine manager to expose the back side, the machine manager It also includes those in which the responsible person has access to the setting switch 332 and/or the setting key 328.

Note that the RAM clear switch (RAM clear switch 6121 in FIG. 161 described later), which is the backup switch 330 (see FIG. 9 described later), is the setting switch (setting switch 332 in FIG. 9 described later, settings in FIG. 161 described later). switch 6081), but at this time, if the gaming machine is not installed on an island facility, there is no influence from the island facility, so a person other than the gaming machine manager can easily control the gaming machine. It is assumed that a situation would be possible in which the setting switch exposed on the back of the device could be accessed and then installed on the island equipment. On the other hand, even if a gaming machine is installed on an island facility, depending on the type of island facility, it may be possible for someone other than the person in charge of managing the gaming machine to be able to move to the back side of the installed gaming machine. . Therefore, under each situation, it is considered possible to easily access the setting switch of the pachinko game machine without using the key managed by the person in charge of managing the game machine. Therefore, in such cases, the pachinko machine cannot be rotated until it is rotated (for example, by rotating the front door or main body of the machine) using a key managed by the machine manager. The system is controlled so that settings can be changed and confirmed using the setting switch exposed on the back of the gaming machine before it is started, allowing the gaming machine manager to accurately manage setting changes and confirmation. It may be done as follows. Note that the setting key (setting key 328 in FIG. 9 described later, setting key 6080 in FIG. 161 described later) and the key for rotating the pachinko game machine (door key, etc.) may be different keys. Desirably, it is possible to control so that settings cannot be changed or confirmed only by using one key.

The game board unit 17 is arranged in front of the base door 12 so as to be located behind the protective glass 23. A game area 20 is formed on the front side of the game board unit 17, in which the fired game balls can roll and flow down.

As shown in FIGS. 5 to 7, the game board unit 17 is arranged approximately at the center of the game area 20 and a transparent panel 172 in which a game area 20 in which the fired game balls can roll and flow down is formed. It includes a center unit 174, a normal electric accessory unit 400, an attacker unit 500, a passage gate 49, and a back unit 176. The center unit 174, the normal electric accessory unit 400, the attacker unit 500, and the passage gate 49 are provided on the front side of the transparent panel 172. The back unit 176 decorates the game board unit 17 and is provided on the rear side of the transparent panel 172. This back unit 176 includes a group of accessories 1000 such as an upper accessory (see FIG. 7) arranged above the display area of the display device 16. At least one or more of these accessory objects 1000 or the actuating members that constitute the accessory functions as a performance accessory that can be operated based on the result of the special lottery, and therefore will be referred to as a performance accessory hereinafter. There is also.

An opening 1722 is formed in the transparent panel 172 at a portion where a display area of a display device 16, which will be described later, is arranged. As shown in FIGS. 5 and 7, a guide rail 26 is provided on the front surface of the transparent panel 172, and game nails and the like are planted therein. The game ball fired from the firing device 15 flies out from the guide rail 26 toward the game area 20, collides with a game nail, etc., and flows down the game area 20 while changing its traveling direction.

The guide rail 26 is composed of two rail-shaped members (hereinafter referred to as "outer rail 26a" and "inner rail 26b"). The game area 20 is divided (defined) by guide rails 26. The inner rail 26b, together with the outer rail 26a, is for guiding the launched game ball to the upper part of the gaming area 20. The inner rail 26b is arranged on the left side of the transparent panel 172 and inside the outer rail 26a.

The center unit 174 includes a center rail 1742 above the opening 1722 of the transparent panel 172 (above the display area of the display device 16), and is formed in an arc shape when viewed from the front. The center rail 1742 is arranged at the upper part of the game area 20, and divides the downstream area of the game ball in the game area 20 into left and right sides of the center rail 1742.

The game balls fired by the firing device 15 are divided into left and right sides of the center rail 1742 and flow down the game area 20, and the game balls flowing down the game area 20 are planted on the game board unit 17 (more specifically, the transparent panel 172). Due to the collision with the installed game nails, etc., it flows downward while changing its direction of travel. The shot game ball is distributed into a falling area according to the amount of operation of the shooting handle 32. Specifically, when the amount of operation of the firing handle 32 is small, the fired game ball flows down the left side area of the center rail 1742. On the other hand, when the amount of operation of the firing handle 52 is large, the fired game ball flows down the right side area of the center rail 1742. Note that the hitting method in which the game ball flows down to the left side area of the center rail 1742 is called "left hitting", and the hitting method in which the game ball flows down in the right side area of the center rail 1742 is called "right hitting". It is possible to make different bets depending on the player.

The attacker unit 500 is a unit body that integrates the first starting opening 420, the big winning opening 540, and the special electric accessory 600. The attacker unit 500 is located approximately at the lower right portion of the gaming area 20 and below the passage gate 49.

The jackpot opening 540 is a portion that can be opened in a jackpot gaming state, which is an advantageous gaming state for the player. A count switch 541 is arranged in the big prize opening 540 (see FIG. 9). When a game ball enters the big prize opening 540, the winning game ball is detected by the count switch 541. When game balls are detected by the count switch 541, a preset number of game balls are paid out from the payout port 61 to the upper tray 26 (or from the payout port 63 to the lower tray 27).

The special electric accessory 600 includes a shutter 610 that can move back and forth in the front-back direction and a big prize opening solenoid 620 (see FIG. 9) that drives the shutter 610. The special electric accessory 600 is arranged above the big prize opening 540. The special electric accessory 600 has an open state in which it is possible (or easy) to enter the game ball into the big winning hole 540 by driving the shutter 610 by the big winning hole solenoid 620, and an open state in which it is possible (or easy) to enter the game ball into the big winning hole 540. It is configured to be able to shift (drive) to a closed state that makes it impossible (or difficult) to win a game ball. The opening drive by the special electric accessory 600 (shutter 610) shifts to a jackpot game state based on the result of jackpot determination performed when a game ball enters the first starting port 420 or the second starting port 440 (described later). will be carried out if Note that the result of the jackpot determination performed when a game ball enters the first starting port 420 or the second starting port 440 (described later) is displayed as a special symbol in the first special symbol display section 73 or second special symbol display section 74. This is indicated by the stop display mode.

In addition, in this specification, when it is simply referred to as a "special symbol", it means both the first special symbol and the second special symbol. However, in this embodiment, the number of special symbols is two (first special symbol, second special symbol), but the number of special symbols may be one.

The first starting port 420 provides an opportunity to determine a jackpot on the condition that the game ball wins (passes), and also provides an opportunity to display the result of the jackpot determination on the display device 16 or a first special symbol display section 73 to be described later. It is something to give. A first starting port switch 421 is provided in the first starting port 420 (see FIG. 9). When a game ball enters the first starting port 420, the winning game ball is detected by the first starting port switch 421. When a game ball is detected by the first starting port switch 421, a jackpot determination is performed inside the pachinko game machine 1 (main CPU 101 shown in FIG. 9), and a preset number of game balls are released from the payout port 61. It is dispensed (discharged) to the upper tray 26 or from the dispensing port 63 to the lower tray 27 . Note that the winning of the game ball into the first starting hole 420 is performed by hitting the ball to the left.

The normal electric accessory unit 400 is a unit body that integrates a second starting port 440, an outlet 450, and a normal electric accessory 460. The normal electric accessory unit 400 is arranged approximately at the lower left of the gaming area 20. The second starting port 440 and the out port 450 are disposed adjacent to each other, with the second starting port 440 being disposed on the right side when viewed from the front, and the out port 450 being disposed on the left side when viewed from the front. Conventionally, the electric accessory unit 400 was often disposed below the first starting port 420, for example. However, in recent years, there has been a demand for the display device 16 to be larger, and it has become difficult to arrange it below the first starting port 420. Therefore, in the pachinko game machine 1 of this embodiment, the normal electric accessory unit 400 is arranged approximately at the lower left of the game area 20.

The second starting port 440 provides an opportunity to determine a jackpot on the condition that the game ball wins (passes), and also provides an opportunity to display the result of the jackpot determination on the display device 16 or a second special symbol display section 74 to be described later. It is something to give. A second starting port switch 441 is provided in the second starting port 440 (see FIG. 9). When a game ball enters the second starting port 440, the winning game ball is detected by the second starting port switch 441. When a game ball is detected by the second starting port switch 441, a jackpot determination is performed inside the pachinko game machine 1 (main CPU 101 shown in FIG. 9), and a preset number of game balls are transferred to the payout port 61. The liquid is dispensed (discharged) from the outlet to the upper tray or from the outlet 63 to the lower tray 27 . The difficulty of winning the second starting port 440 is determined by the normal electric accessory 460. Note that the winning of the game ball into the second starting port 440 is, in principle, performed by hitting the ball to the right.

The normal electric accessory 460 includes a wing member 4620 that can rotate in the right direction, a starting port solenoid 4630 (for example, see FIG. 9), and a power transmission mechanism (not shown) that transmits the power of the starting port solenoid 4630 to the wing member 4620. ). The normal electric accessory 460 can be shifted (driven) between an open state in which a game ball can easily pass through and a closed state in which a game ball cannot pass through by driving the blade member 4620 by the starting port solenoid 4630. It is composed of When a game ball passes above the blade member 4620 while the blade member 4620 is being driven, the game ball enters the second starting port 440 or is discharged to the outside of the pachinko game machine 1 from the out port 450. be done. The opening/closing drive by the normal electric accessory 460 (blade member 4620) is performed for a predetermined period and a predetermined number of times when the normal symbol is in a specific stop display mode in the normal symbol display section 71.

The passage gate 49 provides an opportunity for normal symbol determination on the condition that the game ball wins (passes). The passage gate 49 is arranged on the lower right side of the center unit 174 and on the upper right side of the attacker unit 500. The passage gate 49 is provided with a passage gate switch 49a (see FIG. 9). When a game ball passes through the passage gate 49, the passing game ball is detected by the passage gate switch 49a. When a game ball is detected by the passage gate switch 49a, a normal symbol determination is performed inside the pachinko game machine 1 (main CPU 101 shown in FIG. 2). Note that the game ball passes through the passage gate 49 by hitting the ball to the right.

The attacker unit 500 is a unit body that integrates the first starting opening 420, the big winning opening 540, and the special electric accessory 600. Attacker unit 500 is arranged approximately at the lower right portion of gaming area 20. The reason why the attacker unit 500 is arranged approximately at the lower right corner of the game area 20 is because in recent years, there has been a demand for larger display devices 16, and when various components such as the attacker unit 500 are arranged in the game area 20. This is because it is necessary to avoid such an enlarged display device 16.

The jackpot opening 540 is a portion that can be opened in a jackpot gaming state, which is an advantageous gaming state for the player. A count switch 541 is arranged in the big prize opening 540 (see FIG. 9). When a game ball enters the big prize opening 540, the winning game ball is detected by the count switch 541. When game balls are detected by the count switch 541, a preset number of game balls are paid out (discharged) from the payout port 61 to the upper tray 26 (or from the payout port 63 to the lower tray 27).

The special electric accessory 600 includes a shutter 610 that can move back and forth in the front-back direction and a big prize opening solenoid 620 (see FIG. 9) that drives the shutter 610. The special electric accessory 600 is arranged above the big prize opening 540. The special electric accessory 600 has an open state in which it is possible (or easy) to enter the game ball into the big winning hole 540 by driving the shutter 610 by the big winning hole solenoid 620, and an open state in which it is possible (or easy) to enter the game ball into the big winning hole 540. It is configured to be able to shift (drive) to a closed state that makes it impossible (or difficult) to win a game ball. The opening drive by the special electric accessory 600 (shutter 610) is performed when the special symbol becomes a specific stop display mode in the first special symbol display section 73 or the second special symbol display section 74 and shifts to the jackpot game state. It will be held on.

The general winning holes 53, 54, and 55 are arranged at the lower left of the game board unit 17, and the general winning hole 56 is arranged at the lower right of the game board unit 17. Further, general winning ports 53, 54, 55, and 56 are provided with general winning ports switches 53a, 54a, 55a, and 56a (see FIG. 9). When a game ball wins in the general winning hole 53, 54, 55, 56, the winning game ball is detected by the general winning hole switch 53a, 54a, 55a, 56a. When game balls are detected by the general winning port switches 53a, 54a, 55a, and 56a, a preset number of game balls are paid out from the payout port 61 to the upper tray 26 (or from the payout port 63 to the lower tray 27). (excreted).

In addition, in this embodiment, the number of prize balls for the first starting hole 420 and the second starting hole 440 is three, the number of prize balls for the general winning holes 53, 54, 55, and 56 is 10, and the number of winning balls for the big winning hole 540 is 10. The number of prize balls is set at 15 each. This value (number of prize balls) can be arbitrarily changed in design.

The out port 57 is arranged at the lowest center of the game area 20 (the most downstream position in the downstream direction of the game ball). When the fired game ball does not enter any starting hole or winning hole, it finally flows into the out hole 57.

The LED unit 70 is arranged at the lower right part of the game board unit 17 and outside the guide rail 26 (see FIGS. 5 and 6). The LED unit 70 is a unit body that integrates various display sections. Specifically, the LED unit 70 includes a normal symbol display section 71, a normal symbol reservation display section 72, a first special symbol display section 73, a second special symbol display section 74, and a first special symbol display section 74 as the various display sections. A symbol reservation display section 75 and a second special symbol reservation display section 76 are provided.

The normal symbol display section 71 is for displaying the result of determination for the regular symbol game (normal symbol determination). Here, the normal symbol game refers to a game in which it is determined whether or not to drive the normal electric accessory 460 to an open state based on the result of determination (normal symbol determination). The normal symbol display section 71 includes display LEDs 71a and 71b. The display LEDs 71a and 71b start a variable display in which they alternately turn on and off when a start condition for the variable display (variable display) is satisfied. A combination (display pattern) of lighting and turning off the display LEDs 71a and 71b is displayed as a normal symbol. The display LEDs 71a and 71b start a variable display and then perform a stop display after a predetermined period has elapsed.

If the result of the determination (normal symbol determination) is a hit (hereinafter referred to as "normal win"), the combination of lighting and extinguishing of the display LEDs 71a and 71b (normal symbol) becomes a specific stop display mode. In this way, when the normal symbol is stopped and displayed in a specific stop display mode, it is decided to open the normal electric accessory 460, the normal electric accessory 460 is driven to open and close in a predetermined pattern, and the second starting port is opened and closed. The difficulty of winning the game ball to 440 is changed.

The normal symbol pending display section 72 displays the number of times the normal symbol variable display is executed (hereinafter referred to as "the pending number of normal symbol variable displays"). The normal symbol reservation display section 72 includes display LEDs 72a and 72b. The normal symbol reservation display section 72 displays the number of pending changes in the normal symbol by a combination of lighting and extinguishing of the display LEDs 72a and 72b. For example, when the execution of the fluctuating display of the normal symbol is suspended for one time, the display LED 72a is turned on and the display LED 72b is turned off. Further, when the execution of the variable display of the normal symbols is suspended twice, the display LED 72a lights up and the display LED 72b lights up. Further, when the execution of the variable display of the normal symbols is suspended for three times, the display LED 72a blinks and the display LED 72b lights up. Further, when the execution of the variable display of the normal symbols is suspended for four times, the display LED 72a blinks and the display LED 72b blinks.

The first special symbol display section 73 and the second special symbol display section 74 are for displaying the results of the determination (jackpot determination) for the special symbol game. Here, the special symbol game refers to a game in which the transition or maintenance of the gaming state is determined based on the result of determination (jackpot determination).

The first special symbol display section 73 includes a display LED group 73a consisting of eight LEDs. The display LED group 73a performs a variable display triggered by the winning of a game ball into the first starting hole 420 (starting winning), and also displays the result of jackpot determination based on the winning of the game ball. The display LED group 73a starts a variable display in which each of the eight LEDs repeatedly turns on and off when the start condition for the variable display is satisfied. In the display LED group 73a, a combination (display pattern) of eight LEDs turned on and off is displayed as a special symbol. The display LED group 73a starts a variable display and then performs a stop display after a predetermined period has elapsed.

If the result of the jackpot determination based on the winning of the game ball into the first starting port 420 is a jackpot, the combination of lighting and turning off the eight LEDs of the display LED group 73a (special symbol) becomes a specific stop display mode. . In this way, when the special symbols are stopped and displayed in a specific stop display mode, a transition to the gaming state is determined, the shutter 610 is driven to open and close in a predetermined pattern, and the game state is changed to a gaming state in which a game ball can enter the big prize opening 540. Become. In addition, in the following explanation, the special symbol that is variably displayed on the first special symbol display section 73 based on the winning of the game ball to the first starting hole 420 will be referred to as a first special symbol.

The second special symbol display section 74 includes a display LED group 74a consisting of eight LEDs. The display LED group 74a performs a variable display triggered by the winning of a game ball into the second starting hole 440 (starting winning), and also displays the result of jackpot determination based on the winning of the game ball. The display LED group 74a starts a variable display in which each of the eight LEDs repeatedly turns on and off when the start condition for the variable display is satisfied. In the display LED group 74a, a combination (display pattern) of eight LEDs turned on and off is displayed as a special symbol. The display LED group 74a starts a variable display and then performs a stop display after a predetermined period has elapsed.

If the result of the jackpot determination based on the winning of the game ball into the second starting port 440 is a jackpot, the combination of lighting and turning off the eight LEDs of the display LED group 74a (special symbol) becomes a specific stop display mode. . In this way, when the special symbols are stopped and displayed in a specific stop display mode, a transition to the gaming state is determined, the shutter 610 is driven to open and close in a predetermined pattern, and the game state is changed to a gaming state in which a game ball can enter the big prize opening 540. Become. In addition, in the following explanation, the special symbol that is variably displayed on the second special symbol display section 74 based on the winning of the game ball to the second starting hole 440 will be referred to as a second special symbol.

In this way, in the display LED groups 73a and 74a of the first special symbol display section 73 and the second special symbol display section 74, when the first or second special symbol is stopped and displayed in a specific stop display mode, the normal A transition from the gaming state (normal gaming state) to the jackpot gaming state, which is advantageous to the player, is determined. In this embodiment, the jackpot determination includes a jackpot determination based on the winning of the game ball into the first starting port 420 and a jackpot determination based on the winning of the game ball into the second starting port 440. That is, when the result of the jackpot determination is a jackpot, the game is shifted to a jackpot game state in which a round game in which the jackpot 540 is opened is executed for a predetermined number of rounds.

The first special symbol reservation display section 75 and the second special symbol reservation display section 76 display the number of executions of the variable display of the reserved special symbol (hereinafter referred to as "the number of pending special symbol variable displays"). It is to be displayed. The first special symbol reservation display section 75 includes display LEDs 75a and 75b. The second special symbol reservation display section 76 includes display LEDs 76a and 76b. The first special symbol reservation display section 75 and the second special symbol reservation display section 76 display the number of reservations in the variable display of special symbols by turning on and off the display LEDs 75a, 75b and 76a, 76b. The display mode of lighting and extinguishing of the display LEDs 75a, 75b and 76a, 76b is the same as that of the display LEDs 72a, 72b of the normal symbol reservation display section 72.

[1-2. Electrical configuration]
Next, the control circuit of the pachinko gaming machine 1 will be explained using FIGS. 9 to 19.

As shown in FIG. 9, the pachinko gaming machine 1 mainly includes a main control circuit 100 that controls the game, a sub-control circuit 200 that controls effects according to the progress of the game, and a payout/fire control circuit 300. and a power supply circuit 338. For convenience, each of these configurations will be described below in the order of main control circuit 100, payout/emission control circuit 300, power supply circuit 338, and sub control circuit 200.

[1-2-1. Main control circuit]
The main control circuit 100 includes a main CPU 101, a main ROM 102 (read-only memory), a main RAM 103 (read/write memory), and is housed in a main board case.

A main ROM 102, a main RAM 103, etc. are connected to the main CPU 101. The main CPU 101 has a function of executing various processes according to programs stored in the main ROM 102.

The main ROM 102 stores programs for controlling the operation of the pachinko gaming machine 1 by the main CPU 101, various tables, and the like.

The main RAM 103 has a function of storing various flags and variable values as a temporary storage area of the main CPU 101, and can store and retain written information even in a power-off state. Note that in this embodiment, the main RAM 103 is used as a temporary storage area of the main CPU 101, but the storage medium is not limited to this, and any storage medium that can be read and written may be used.

The main RAM 103 is provided with a storage area in which information about the special symbol game is stored as a starting memory. Specifically, the main RAM 103 includes a first special symbol starting storage area (0) in which information of the special symbol game corresponding to the first special symbol that is changing is stored as a starting memory, and a first special symbol game information for an upper limit of four times. A first special symbol starting storage area (1) to a first special symbol starting storage area (4) are provided in which information of a special symbol game corresponding to a special symbol is stored as a starting memory. Similarly, the main RAM 103 includes a second special symbol starting storage area (0) in which information about the special symbol game corresponding to the second special symbol that is changing is stored as a starting memory, and a second special symbol game for up to four times. A second special symbol starting storage area (1) to a second special symbol starting storage area (4) are provided in which information of a special symbol game corresponding to a symbol is stored as starting memory.

The main control circuit 100 also includes an initial reset circuit 104 that generates a reset signal when the power is turned on, an I/O port 105, a command output port 106, a backup capacitor 107, and the like. Initial reset circuit 104 is connected to main CPU 101 . The I/O port 105 transmits input signals from various devices to the main CPU 101 and output signals from the main CPU 101 to various devices. The command output port 106 is for transmitting commands from the main CPU 101 to the sub control circuit 200. The backup capacitor 107 holds various data stored in the main RAM 103 by quickly supplying power to the main RAM 103, for example, when the power is cut off (power OFF).

Further, various devices (members) are connected to the main control circuit 100.

For example, the main control circuit 100 includes a normal symbol display section 71, a normal symbol reserve display section 72, a first special symbol display section 73, a second special symbol display section 74, a first special symbol reserve display section 75, A second special symbol reservation display section 76, a starting opening solenoid 4630 that drives the blade member 4620 of the normal electric accessory 460, a big winning opening solenoid 620 that drives the shutter 610, etc. are connected. The main control circuit 100 can control the operations of these devices (members) by transmitting signals. The main control circuit 100 also includes a calling device (not shown) that has functions such as calling a hall attendant and displaying the number of jackpots, and a system for transmitting data to a hall computer 700 that manages pachinko machines in the entire hall. An external terminal board 323 to be used is connected.

In addition, the main control circuit 100 includes a first starting port switch 421, a second starting port switch 441, a passing gate switch 49a, a count switch 541, general winning port switches 53a, 54a, 55a, 56a, a performance display monitor 334, etc. is connected. When a game ball is detected by these members, a predetermined detection signal is supplied to the main control circuit 100 from the members. Also connected to the main control circuit 100 is a backup clear switch 330, etc., which clears backup data in the event of a power outage in response to an operation by a manager of the gaming hall.

Further, a setting key 328 and a setting switch 332 are also connected to the main control circuit 100. The setting key 328 is a key or a key-like key that triggers the execution of setting change processing and setting confirmation processing, which will be described later. The setting switch 332 can be pressed and is used to change the set value during a setting change process, which will be described later. As described above, the setting key 328 and the setting switch 332 are housed in the main board case so that a third party (for example, a player) other than the person in charge of managing the gaming machine cannot easily access them.

Further, a payout/emission control circuit 300 is connected to the main control circuit 100. The payout/launch control circuit 300 is connected to a payout device 350 that pays out game balls, a launch device 15 that shoots game balls, a card unit 360, and the like. The dispensing device 350 is provided in the dispensing unit 18. A ball lending operation panel 370 is connected to the card unit 360, and a signal is supplied to the ball lending operation panel 370 according to the player's operation.

[1-2-2. Payout/fire control circuit]
When the payout/launch control circuit 300 receives the prize ball control command supplied from the main control circuit 100 or the rental ball control signal supplied from the card unit 360, it transmits a predetermined signal to the payout device 350, Control is performed to cause the payout device 350 to pay out game balls. Further, when the firing handle 32 is grasped by the player and rotated clockwise, the payout/launch control circuit 300 controls a firing solenoid (not shown) according to the rotation angle (rotation amount). The controller supplies power to the controller and controls the firing of game balls.

Further, a sub-control circuit 200 (relay board 2010) is connected to the command output port 106. The sub-control circuit 200 performs display control on the display device 16, control regarding the sound generated from the speaker 24, control regarding the light of the LED 25, etc. in accordance with various commands supplied from the main control circuit 100.

In this embodiment, the main control circuit 100 supplies commands to the sub-control circuit 200, but the sub-control circuit 200 is configured to be unable to supply signals to the main control circuit 100. However, the present invention is not limited to this. The configuration may be such that signals can be transmitted from the control circuit 200 to the main control circuit 100.

The payout/launch control circuit 300 controls the payout of prize balls and rental balls from the pachinko game machine 1, and the payout/launch control circuit 300 includes a payout device 350 for paying out game balls, a game A firing device 15 for firing a ball, a backup clear switch 330 for clearing backup data in the event of a power outage according to an operation by an administrator of the game hall, and the like are connected.

[1-2-3. Power supply circuit]
The power supply circuit 338 is a power supply circuit created to supply the power supply voltage necessary for playing games with the pachinko gaming machine 1 to the main control circuit 100, the sub-control circuit 200, the payout/launch control circuit 300, etc. .

The power supply circuit 338 is connected to the power switch 35 and the like. The power switch 35 is turned on when supplying the necessary power to the pachinko game machine 1.

Although the setting key 328 and the setting switch 332 are connected to the main control circuit 100 as described above, they may be connected to the power supply circuit 338 instead. Even in this case, it is preferable that the setting switch 332 and the setting key 328 be housed in a predetermined case so that a third party (for example, a player) other than the person in charge of managing the gaming machine cannot easily access the setting switch 332 and the setting key 328. . Even in such a case, being inside a predetermined case means that the setting switch 332 and setting key 328 cannot be accessed without opening the case, as well as the correspondence of the setting switch 332 and setting key 328 of the case. There is a notch only in one place, and when the pachinko game machine 1 is rotated from the island equipment where the pachinko game machine 1 is installed using a key managed by the game machine management manager to expose the back side. , including those in which a gaming machine manager can access the setting switch 332 and/or the setting key 328.

Here, the display contents displayed on the performance display monitor 334 will be explained. Performance display data is displayed on the performance display monitor 334 under the control of the main CPU 101. The performance display data is, for example, data indicating the ratio of game balls paid out in a state other than a jackpot game state with respect to the firing of a predetermined number of game balls (for example, 60,000 shots), and is also called a base value.

The payout/fire control circuit 300 totals the base value based on past game history, and stores the total result in a specific work area of the work area of the main RAM 103, which will be described later. This specific work area will be described later, but it is an area where data will not be cleared even if the backup clear process described below is performed. Note that the base value may be aggregated based on a predetermined operation being performed, or the base value may be always aggregated so that the base value is always displayed on the performance display monitor 334. .

The payout/launch control circuit 300 includes a total history aggregation means for aggregating all base values based on the entire game history from the initial power-on (the first power-on after the pachinko game machine 1 was manufactured) to the present; and a setting value-by-setting history aggregation means that executes a setting-value-by-setting base value aggregation based on past game history for each setting value.

For example, when a gaming machine manager or the like performs an operation to display all base values, the all history totaling means executes the above-mentioned totaling of all base values. The total base value totaled by the total history totaling means is displayed on the performance display monitor 334 by the main CPU 101. Further, when the display operation of the base value by setting value is performed, the history aggregation unit by setting value executes the aggregation of the base value by setting value. The setting value-specific base values compiled by the setting value-specific history aggregating means are displayed on the performance display monitor 334 by the main CPU 101.

The setting value-by-setting history aggregation means can also aggregate only base values for arbitrary setting values in response to a request (operation). In this case, it is possible to aggregate not only the base value of the set setting value but also the base value of other setting values other than the set setting value. Therefore, the main CPU 101 can display base values for other setting values on the performance display monitor 334 without executing the setting change process described later.

In addition, the main CPU 101 calculates both the total base value totaled by the total history totaling means and the base value by setting value totaled by the setting value-specific history totaling means, in response to an operation by, for example, a gaming machine management manager. can be displayed on the performance display monitor 334, or only one of them can be selectively displayed on the performance display monitor 334.

Further, the main CPU 101 may display only the base value of a specific setting value on the performance display monitor 334, or may display a list of the base values of all setting values. Further, both the total base value and the base value by setting value may be displayed in a list. When displaying the base values of all setting values in a list, or when displaying both all base values and base values by setting value in a list, use both the performance display monitor 334 and other display means. It may also be displayed.

In addition, the main CPU 101 includes a total history aggregation means and a history aggregation means for each setting value, but in addition to these or in place of the history aggregation means for each setting value, the main CPU 101 has a total history aggregation means for each setting value. A post-setting-change history aggregation means may be provided for aggregating the post-setting-change base value based on the game history. In this case, the main CPU 101 can display the base value by set value after the setting change on the performance display monitor 334 based on the display operation of the base value after the setting change.

In this way, by displaying all or part of the total base value, the base value by setting value and/or the base value by setting value after setting change on the performance display monitor 334, pachinko games can be improved. It becomes possible to easily confirm information based on the past gaming history of machine 1.

In addition, in this embodiment, the base value is displayed on the performance display monitor 334, but the total number of game balls paid out is paid by the ball entering the special electric accessory (big prize opening) and the normal electric accessory. The ratio of the number of game balls put out (payout by accessory) may be displayed. Further, it may be displayed in relation to the total number of balls fired, or it may be displayed as a percentage of the number of game balls paid out by the special electric accessory (big winning hole). Also, they may be displayed by setting.

Further, an error code, which will be described later, is displayed on the error notification monitor 336. In addition to the error code, the error notification monitor 336 may also display a setting change code indicating that the setting change process is in progress, a setting confirmation code indicating that the setting confirmation process is in progress, etc., which will be described later. can. Note that during the setting change, a symbol (setting change symbol) that is not normally displayed may be displayed on the special symbol display device.

[1-2-4. Sub control circuit]
Next, the internal configuration of sub-control circuit 200 will be described in more detail with reference to FIG. Note that FIG. 10 is a block diagram showing the circuit configuration inside the sub-control circuit 200 and the connection relationship between the sub-control circuit 200 and its various peripheral devices.

The sub-control circuit 200 executes effects, etc. according to the progress of the game in response to commands from the main control circuit 100, and as shown in FIG. ), a control ROM board 2030, and a CGROM (Character Generator ROM) board 2040 (second board). The sub board 2020 is connected to the relay board 2010, the control ROM board 2030, and the CGROM board 2040. Note that in the sub-control circuit 200, the sub-board 2020 and various ROM boards (control ROM board 2030 and CGROM board 2040) are connected via a board-to-board connector (not shown).

As shown in FIG. 9, the sub control circuit 200 includes a production button switch 621 that is turned ON/OFF by operating the production button 62, a main button switch 6621 that is turned ON/OFF by operating the main button 662, and various select buttons. Select button switches 6641a to 6641d, which are turned on and off by operating buttons 664a to 664d, and a group of accessory detection sensors 1002 that detect that the accessory group 1000 is in the initial position are connected, but in FIG. These illustrations are omitted. Furthermore, in reality, select button switches 6641a to 6641d corresponding to the respective select buttons 664a to 664d are provided, but in FIG. 9, for convenience, these are collectively shown as select button switches 6641. Further, the accessory detection sensor group 1002 is provided in the same number as the number of motors provided corresponding to the movable accessory.

Relay board 2010 is a relay board for receiving commands transmitted from main control circuit 100 and transmitting the received commands to sub-board 2020.

Note that when the sub-control board is the one-board board mentioned above, the sub-control board itself may have the function of receiving the commands transmitted from the main control circuit 100. However, the command may be eventually received via a relay board or the like.

Furthermore, if the sub-control board is composed of multiple boards, any of the boards may be equipped with the receiving means, and even in this case, it is interpreted that the sub-control board has the receiving means. can do. Also, in this case, even if a sub-control board made up of multiple boards receives a command via a relay board, etc., one of the boards that make up the sub-control board will receive information related to the command. If the command is recognized, it is possible to express that the sub-control board has received the command.

The sub board 2020 is provided with a host control circuit 2100, an audio/LED control circuit 2200, a display control circuit 2300, an SDRAM (Synchronous Dynamic RAM) 250, and a built-in relay board 2600. Of these, at least the host control circuit 2100, the audio/LED control circuit 2200, and the display control circuit 2300 are configured as a single board.

The host control circuit 2100 is a circuit that controls the operation of the entire sub-control circuit 200 based on various commands sent from the main control circuit 100, and includes a CPU processor, sub-work RAM 2100a, SRAM 2100b, RTC (real-time clock), Consists of a watchdog timer. The host control circuit 2100 is connected to the audio/LED control circuit 2200, the display control circuit 2300, and the built-in relay board 2600 within the sub-board 2020. Further, host control circuit 2100 is connected to control ROM board 2030.

Further, the host control circuit 2100 includes a sub-work RAM 2100a and an SRAM (Static RAM) 210b. The sub-work RAM 2100a is a storage device that acts as a temporary storage area for work when the host control circuit 2100 executes various processes, and stores various flags and variables necessary when the host control circuit 2100 executes various processes. Memorize the value etc. The RAM 2100b is a storage device that backs up predetermined data in the subwork RAM 2100a. Note that in this embodiment, a RAM is used as the temporary storage area of the host control circuit 2100, but the present invention is not limited to this, and any storage medium that can be read and written may be used as the temporary storage area. .

The audio/LED control circuit 2200 is connected to the speaker 24 and the lamp group 25 via the built-in relay board 2600, and controls the speaker 24 based on control signals (sound request and LED request described later) input from the host control circuit 2100. This circuit controls the audio playback operation by the lamp group 25 and the light emission operation by the lamp group 25. Therefore, functionally, the audio and LED control circuit 2200 includes an audio controller 2200a and a lamp controller 2200b. The audio controller 2200a and the lamp controller 2200b are substantially included in a sound/lamp control module 2260, which will be described below. The internal configuration of the audio/LED control circuit 2200 will be described in detail later with reference to the drawings.

Note that in this embodiment, when the control signal and data (for example, LED data described below) output from the audio/LED control circuit 2200 are transmitted to the lamp group 25 via the built-in relay board 2600, the audio/LED control circuit 2200 Communication between the control circuit 2200 and the lamp group 25 is performed using an SPI (Serial Peripheral Interface) communication method (a type of serial communication method). Further, in this embodiment, the lamp group 25 includes one or more LEDs and one or more LED drivers for controlling each LED.

The display control circuit 2300 is connected to the display device 16 and displays images related to presentation (decorative pattern images, background images, presentation images, etc.) on the display device 16 based on a control signal (drawing request) input from the host control circuit 2100. This is a circuit for controlling various processing operations when displaying images. Note that the display control circuit 2300 includes a display controller (a first display controller 2380 and a second display controller 2390 described later) and a built-in VRAM (Video RAM) 237.

Further, the display control circuit 2300 is connected to the SDRAM 2500 within the sub-board 2020. Furthermore, display control circuit 2300 is connected to CGROM board 2040. Further, the display controller in the display control circuit 2300 is directly connected to the display device 16 without using a relay board. Note that the internal configuration of the display control circuit 2300 will be described in detail later with reference to the drawings.

The SDRAM 2500 is configured with a DDR2 (Double-Date Rate 2) SDRAM. Furthermore, the SDRAM 2500 is provided with various buffers that temporarily store various image data during drawing control processing of images (moving images and still images) displayed by the display device 16. Specifically, for example, the SDRAM 2500 is provided with a texture buffer, a movie buffer, a blend buffer, two frame buffers (a first frame buffer and a second frame buffer), a motion buffer, and the like.

The built-in relay board 2600 receives various signals and various data output from the host control circuit 2100 and the audio/LED control circuit 2200, and transmits the received various signals and data to the speaker 24, the lamp group 25, and the accessory group 1000. This is a relay board that sends data to

Further, the built-in relay board 2600 includes an I2C (Inter-Integrated Circuit) controller 2610 and a digital audio power amplifier 2620 (amplification means). Although this embodiment shows an example in which the I2C controller 2610 and the digital audio power amplifier 2620 are mounted on the same relay board, the present invention is not limited to this. It may be provided separately from the relay board on which the power amplifier 2620 is mounted.

The I2C controller 2610 is connected to the host control circuit 2100 and the motor controller 2700 of the accessory group 1000. That is, the host control circuit 2100 is connected to the accessory group 1000 via the I2C controller 2610 and the motor controller 2700. Control signals and data (for example, excitation data described below) output from the host control circuit 2100 are input to the accessory group 1000 via the I2C controller 2610 and the motor controller 2700.

Note that in this embodiment, communication between the I2C controller 2610 and the motor controller 2700 is performed using an I2C communication method (a type of serial communication method). Furthermore, in this embodiment, the accessory group 1000 includes one or more motors, and the motor controller 2700 includes one or more motor drivers for driving each motor. Although FIG. 10 shows an example in which only one accessory group 1000 is provided, the present invention is not limited to this, and a plurality of accessory groups 1000 may be provided.

In addition, in the configuration of this embodiment, the host control circuit 2100 directly controls the motors of the operating objects of the objects forming the object group 1000 and the operating members forming the objects, without using the motor controller 2700. It may be configured to drive, or a control circuit for controlling the motor may be provided separately. Furthermore, in this embodiment, a plurality of motor drivers (motors) are controlled by one control circuit, but the present invention is not limited to this. In this embodiment, one or more (one or more) control circuits may control one or more (one or more) motors (motor drivers), or one or more (one or more) control circuits may control one or more (one or more) motors (motor drivers). The configuration may be such that one motor (motor driver) is controlled, or the configuration may be configured such that one control circuit controls one motor (motor driver).

Further, the digital audio power amplifier 2620 is connected to the audio/LED control circuit 2200 and the speaker 24. That is, the audio/LED control circuit 2200 is connected to the speaker 24 via the digital audio power amplifier 2620. Therefore, the audio signal etc. output from the audio/LED control circuit 2200 is input to the speaker 24 via the digital audio power amplifier 2620.

The control ROM board 2030 is provided with a sub-main ROM 2050. The sub-main ROM 2050 stores various programs and various data tables (for example, see FIGS. 21 to 28 described later) for controlling the performance operations of the pachinko gaming machine 1 by the host control circuit 2100. The host control circuit 2100 (more specifically, the CPU processor included in the host control circuit 2100) executes various processes according to the programs stored in the sub-main ROM 2050.

Note that in this embodiment, the sub-main ROM 2050 is used as a storage means for storing programs, various tables, etc. used in the host control circuit 2100, but the present invention is not limited thereto. As such storage means, other types of storage media may be used as long as they are readable by a computer equipped with a control means, such as hard disk drives, CD-ROMs, DVD-ROMs, ROM cartridges, etc. storage media may be applied. Furthermore, each of the programs may be recorded on separate storage media. Furthermore, the program may be recorded in advance on a recording medium, or may be downloaded from an external source after the power is turned on and recorded in the sub-main ROM 2050.

A CGROM 2060 is provided on the CGROM board 2040. The CGROM 2060 is configured with a NOR type or NAND type flash memory. The CGROM 2060 also stores, for example, image data displayed on the display device 16, audio data played back by the speaker 24 (sometimes referred to as sound data in this specification), and the like. Note that, at this time, various data are compressed (encoded) and stored in the CGROM 2060, but the present invention is not limited to this, and the various data may be stored in the CGROM 2060 without being compressed.

In this embodiment, a configuration in which various ROM boards (control ROM board 2030 and CGROM board 2040) and sub-board 2020 are connected by a board-to-board connector in the sub-control circuit 200 has been described. The invention is not limited to this. For example, various ROMs may be inserted directly into ports such as sockets provided on the sub-board 2020, and the sub-board 2020 may be configured with a single board having a ROM function or the ROM itself. That is, the sub-board 2020 and various ROMs may be integrally configured. Further, when the sub-board 2020 is configured by a single board equipped with a ROM function or a ROM itself, the sub-control circuit 200 controls the sub-board used according to the type of memory used as a CGROM. It may also include switching means for physically or electrically switching the circuits on the substrate, or switching means for switching the information of the circuits on the sub-boards to be used depending on the type of memory.

Furthermore, in this embodiment, the relationship in data communication speed between each of the various storage means (sub-main ROM 2050, CGROM 2060, built-in VRAM 2370, SDRAM 2500) and the corresponding control circuit is as follows: Built-in VRAM 2370>SDRAM 2500>Sub-main ROM2050≒CGROM2060. That is, in this embodiment, the communication speed between the built-in VRAM 2370 and various circuits in the display control circuit 2300 is the fastest, and the communication speed between the SDRAM 2500 and the display control circuit 2300 is the second fastest. The communication speed between the sub-main ROM 2050 and the host control circuit 2100 and the communication speed between the CGROM 2060 and the display control circuit 2300 are the slowest. However, the present invention is not limited thereto, and the relationship in communication speed between each of the various storage means and the corresponding control circuit can be set arbitrarily. For example, the magnitude relationship of the communication speed between each of the various storage means and the corresponding control circuit may be different from this embodiment, or the communication speed between each storage means and the corresponding control circuit may be different from this embodiment. may all be the same.

Here, possible configurations of the various storage means described above will be explained. In this embodiment, the storage means for information regarding image data (compressed (encoded) image data) stores information regarding transparency data (alpha table described below) that can be used when setting transparency for image data. A configuration example in which the storage means is the same (CGROM 2060) has been described. That is, a configuration example in which the "first information storage means" is physically the same as the "second information storage means" has been described. However, the present invention is not limited thereto. For example, the "first information storage means" may be configured with a physically different storage means (storage medium) from the "second information storage means".

Furthermore, the term "information storage means" as used herein refers not only to storage means such as the CGROM 2060, but also to tables stored in the storage means, data storage areas within the storage means, etc. good. Therefore, for example, the "first information storage means" and the "second information storage means" may be mutually different data storage areas within the same storage means, or may be mutually different tables, Alternatively, the information may be stored in mutually different register addresses. In other words, "information storage means" used in this specification are different not only when they are physically different storage means (storage media), but also when they are physically the same storage means (for example, ROM, RAM, etc.) However, the meaning also includes cases where data areas (storage areas distinguished by addresses, registers, tables, structures, etc.) are different within the storage means.

Note that the above-mentioned meaning of "information storage means" in this specification is also applicable to the above-mentioned "third information storage means" (SDRAM 2500) and "fourth information storage means" (built-in VRAM 2370). Therefore, for example, the "first information storage means" to "fourth information storage means" may be composed of physically different storage means (storage media), and the "first information storage means" to The "fourth information storage means" may be composed of mutually different data areas (storage areas distinguished by addresses, registers, tables, structures, etc.) within one storage means.

Furthermore, in this embodiment, the "first information storage means" and the "second information storage means" are configured in different data areas in one storage means (CGROM 2060), and the "third information storage means" is configured as different data areas. , a storage means (CGROM 2060) including a "first information storage means" and a "second information storage means", and a physically different storage means (SDRAM 2500); An example will be explained in which the storage means (CGROM 2060) includes a "1 information storage means" and a "second information storage means", and a storage means (built-in VRAM 2370) physically different from the "third information storage means" (SDRAM 2500). However, the present invention is not limited thereto. Whether the "information storage means" should consist of a data area or a storage means, and how the "information storage means" defined as a data area should be combined with the "information storage means" defined as a storage means. The mode can be set as appropriate depending on, for example, the configuration (number, type, etc.) of the storage means provided in the gaming machine. For example, in the present embodiment, the "first information storage means" to "third information storage means" are configured from mutually different data areas within one storage means, and the "fourth information storage means" is configured from the "third information storage means". The third information storage means may be physically different from the storage means including the first information storage means to the third information storage means.

[1-2-5. Audio/LED control circuit]
Next, the internal configuration of the audio/LED control circuit 2200 will be described with reference to FIG. 11. FIG. 11 is a block diagram showing the internal circuit configuration of the audio/LED control circuit 2200 and the connection relationship between the audio/LED control circuit 2200 and its various peripheral devices and peripheral circuit sections. Note that in FIG. 11, in order to simplify the explanation, illustrations of relay boards and the like provided between the audio/LED control circuit 2200 and various peripheral devices and circuit units are omitted.

As shown in FIG. 11, the audio/LED control circuit 2200 includes an LSI (Large-Scale Integration) interface 2210, a memory interface 2220, a digital audio interface 2230, a peripheral interface 2240, a command register 2250, and a sound lamp. It includes a control module 2260, a main generator 2270, and a multi-effector 2280. The connection relationship of each part in the audio/LED control circuit 2200 is as follows.

Within the audio/LED control circuit 2200, a sound/lamp control module 2260 is connected to a memory interface 2220, a peripheral interface 2240, a command register 2250, a main generator 2270, and a multi-effector 2280. Further, the command register 2250 is connected to the LSI interface 2210 in addition to the sound lamp control module 2260. In addition to the sound/lamp control module 2260, the main generator 2270 is connected to a memory interface 2220 and a multi-effector 2280. Furthermore, the multi-effector 2280 is connected to a memory interface 2220 and a digital audio interface 2230 in addition to the sound lamp control module 2260 and the main generator 2270.

Next, the configuration of each part in the audio/LED control circuit 2200 will be explained.

The LSI interface 2210 is an interface circuit used when inputting/outputting control signals (for example, sound requests, LED requests, etc.) between the host control circuit 2100 and the command register 2250. That is, command register 2250 is connected to host control circuit 2100 via LSI interface 2210.

The memory interface 2220 is an interface circuit used to input/output audio data and the like between the sub-main ROM 2050 and each of the sound/lamp control module 2260, main generator 2270, and multi-effector 2280.

The digital audio interface 2230 is an interface circuit used when outputting audio signals and the like from the multi-effector 2280 to the speaker 24. Further, digital audio interface 2230 outputs an audio input signal to multi-effector 2280.

The peripheral interface 2240 is an interface circuit used when inputting/outputting lamp signals (such as LED data to be described later) between the lamp group 25 and the sound/lamp control module 2260. Additionally, the peripheral interface 2240 is provided with three physical systems (SPI channels) for outputting data to the LED drivers included in the lamp group 25. Note that in this embodiment, as described later, two physical systems (physical system 0 (SPI channel 0) and physical system 1 (SPI channel 1)) are used.

Command register 2250 is comprised of a number of register groups (eg, a number of audio control registers) that are accessed by host control circuit 2100. Command register 2250 performs settings for controlling the functions of sound/lamp control module 2260, main generator 2270, and multi-effector 2280. The command register 2250 also sets operating conditions for each interface (LSI interface 2210, memory interface 2220, digital audio interface 2230, peripheral interface 2240).

Note that each register constituting the command register 2250 is equipped with an IC (Integrated Circuit), and each register is configured by a memory chip whose operation is stabilized by memory access control. When registers with this configuration are used, the load on the signal bus to which each register is connected is reduced, so by increasing the number of memory chips (registers), the capacity per memory module ( (capacity of command register 2250) can be increased.

The sound/lamp control module 2260 centrally controls audio playback operations, etc., and controls the operation of each component (each block) in the audio/LED control circuit 2200 according to the settings of the command register 2250. . As shown in FIG. 11, the sound/lamp control module 2260 includes a simple access controller 2260a, a sequencer 2260b, a lamp control section 2260c, and a peripheral control section 2260d.

The simple access controller 2260a is a circuit unit that processes commands in batches. The sequencer 2260b includes various sequencers (automatic reproduction function units) for controlling automatic reproduction operations such as lamp lighting and audio. Each sequencer controls various operations according to a timer and step conditions (for example, conditions set for each step processing during sequence playback of LED animation, audio, etc., which will be described later).

The lamp control unit 2260c calculates the brightness values to be set in all channels (eight channels) for which LED data, which will be described later, can be set, and transmits the calculation results to the outside (LED driver). Further, the peripheral control unit 2260d performs physical transmission control when transmitting the calculation result data output from the lamp control unit 2260c to the LED driver.

Main generator 2270 is a circuit unit that generates an audio signal. Specifically, the main generator 2270 acquires predetermined audio data stored in the CGROM 2060 based on the control signal input from the sound/lamp control module 2260, and converts the acquired audio data into a predetermined audio signal. Convert to The main generator 2270 includes a decoder 2270a that is divided into playback channels CH1 to CH32 and plays compressed data, a channel volume 2270b (V1 to V4) that adjusts the volume, and a channel mixer 2270c that mixes the playback sound of the decoder 2270a. and a remix section 2270d that performs the final mixing operation.

Multi-effector 2280 includes a mixer that synthesizes the audio signal input from main generator 2270 and an audio input signal input from digital audio interface 2230, and various effectors for applying various sound effects to audio. The multi-effector 2280 outputs the audio signal synthesized by the mixer, the output signal from the effector, etc. to the speaker 24 via the digital audio interface 2230.

FIG. 12 is a diagram illustrating output signals of the audio/LED control circuit. The CGROM 2060 stores up to 8192 types of sequence code groups and up to 8192 types of SAC data groups. The sequence code and SAC data are each specified by a 13-bit sequence code number and SAC number, and have a relationship of 8192=213.

In the case of this embodiment, 16 series (SQ0 to SQ15) that operate in parallel are provided as the sequencer 2260b, and 4 series (SAC0 to SAC3) that operate in parallel are provided as the simple accelerator controller 2260a. There is. Corresponding to this configuration, the command register 2250 is provided with an audio control register RGj2 for controlling the sequencers (SQ0 to SQ15) and an audio control register RGj1 for controlling the SACs (SAC0 to SAC3).

Then, when the host control circuit 2100 constituted by the CPU processor writes the SAC number and its attached information to a predetermined voice control register RGj1 for SAC control based on the voice command transmission operation, the corresponding simple Access controller 2260a begins functioning, and simple access controller 2260a will write a set of configuration data identified by the SAC number to a set of voice control registers pointed to by the SAC data. In this embodiment, complicated setting operations can be completed by transmitting one SAC number and its attached information.

On the other hand, the host control circuit 2100 constituted by a CPU processor sends a sequence code number and its attached information to a predetermined voice control register RGj2 for controlling the sequencer 2260b (SQ0 to SQ7) based on the voice command transmission operation. When written, the corresponding sequencer SQi starts functioning and writes the set of configuration data specified by the sequence code to the set of audio control registers pointed to by the sequence code.

Here, a predetermined audio control register RGj2 for controlling the sequencers (SQ0 to SQ7) contains multiple (up to 8) sequence code numbers and loop information for the performance of each sequence code number for any sequencer SQi. It is now possible to enter. Therefore, for example, when n+1 sequence code numbers (X0, X1, ..., Xn) are specified for sequencer SQi, the setting operation of sequence code number →...The setting operations of the sequence code number Xn will be executed in order, and the audio effects corresponding to the setting operations will be executed.

In addition, loop information such as the number of repetitions can be specified for each sequence code number, so after repeating the audio performance specified by the sequence code number a predetermined number of times, the audio performance specified by the next sequence code number can be changed. can be migrated.

As described above, there is a wide variety of data to be set in the sequencer SQi, and it is necessary to appropriately set these sequence code numbers and accompanying data in the audio control register RGj2 for sequencer control. Therefore, in this embodiment, the entire sequence code number and accompanying data is divided into 1-byte units, and the divided 1-byte data and the register address of the sequencer control register RGj2 to which this 1-byte data is to be set are divided. A set of SAC data is secured in the CGROM 2060 (hereinafter referred to as sequencer startup SAC data).

Then, the host control circuit 2100 activates the simple access controller 2260a by specifying a predetermined SAC number in the voice control register RGj1 for SAC control. Here, the SAC number of course specifies the SAC data for starting the sequencer. Then, necessary data is developed in the sequencer control register RGj2 based on the operation of the SAC (Simple Access Controller). Therefore, the operation of setting start-up data for sequencers SQ0 to SQ15 is easy.

By the way, as explained above with reference to FIG. 12, a group of sequence codes identified by one sequence code number includes multiple operation units (sequence steps) separated by step end codes (FFFEH). In the end, after all the sequence steps specified by one sequence code number are executed, the sequence steps specified by the next sequence code number are executed.

Since a standby time can be set for each sequencer, the first sequence step (writing a group of setting data) is started after the standby time specified by the host control circuit 2100 constituted by the CPU processor. , and when the step end code (FFFEH) is executed, the next set of setting data is written to the set of voice control registers after a waiting time. Note that the standby time can be set as a single piece of time information for each sequencer (SQ0 to SQ7), but for example, in a preceding sequence step, the standby time that is applied to the subsequent sequence step is set. By doing so, the waiting time for each sequence step can be set arbitrarily.

Furthermore, to continue the explanation of the internal configuration of the audio/LED control circuit 2200, as shown in FIG. The mixed SUB1) is subjected to digital filter processing in the multi-effector 2280 based on the operating parameters specified in a predetermined audio control register of the command register 2250, and is then supplied to the total volume 2290 (TV0 to TV3) to set the total volume value. Amplified based on TV.

The total volume value TV is defined by the operating parameters written in the corresponding audio control register, but as explained earlier, in this embodiment, in principle, these operating parameters are determined by the setting switch (hardware) operated by the staff. (ware switch). However, if the player operates the volume switch (operates the screen) during the game operation (while waiting for audio production), the total volume TV is defined (changed) based on the set value. Furthermore, when the player operates the volume switch, instead of or in addition to the total volume TV being defined based on the setting value, the channel volume 2270b (V1 to V4) is defined (changed). You can also do it.

[1-2-5-1. Speaker volume control]
Next, the volume control of each speaker 24 executed by the host control circuit 2100 will be described with reference to FIG. 13. FIG. 13 is a control block diagram for explaining an example of volume control by the host control circuit.

Sounds such as game sounds output from each speaker 24 (L0/R0/L1/R1, SUB0, SUB1) are audio signals of total volume TV0 to TV3 output to all channels, and audio signals of each individual volume among all channels. The volume is controlled by a volume transition operation that changes the volume value of the audio signal in stages by multiplying the audio signal of each playback channel output to the channel.

Note that the "audio signal" has volume information (for example, information such as wattage), and can also be simply referred to as "volume." For example, in this specification, "audio signal for each reproduction channel" may be referred to as "volume for each reproduction channel."

Total volume The audio signals of TV0 to TV3 are the total value of the audio signal output by the volume control 2810 using the hardware switch, the audio signal output by the user volume control 2820 using the volume setting screen, and the debug volume control 2830 during debugging. It is defined by multiplying the audio signal by The host control circuit 2100 that executes volume control 2810 using a hardware switch, user volume control 2820 using a volume setting screen, and debug volume control 2830 during debugging corresponds to the "first volume control means" of the present invention.

Further, the volume of each reproduction channel is determined by multiplying the audio signal of the primary volume and the audio signal of the secondary volume. The audio signal of the primary volume is the audio signal output by the first playback channel primary control 2840 that is affected by the volume adjustment and the audio signal output by the second playback channel primary control 2850 that is not affected by the volume adjustment. Defined by total value. In the first playback channel primary control 2840, control is performed to change the volume of the normal game sound (i.e., the audio signal (the same applies hereinafter)) based on, for example, a player or the like performing an operation to change the volume. be exposed. The second playback channel primary control 2850 is a control that outputs a specific game sound (for example, an error sound or a warning sound for illegal activity) at a constant volume regardless of whether or not an operation to change the volume has been performed. will be held. This constant volume may always be the maximum volume. In this way, the second playback channel primary control 2850, which is not affected by volume adjustment, controls a specific game sound to be output at a constant volume, so that a specific game sound can be output only in a specific playback channel rather than in the entire volume. It becomes possible to perform control to keep the volume of the game sound constant. Further, the secondary volume audio signal is the volume incorporated in the audio data specified by the SAC number, and is output by the volume controls 2860, 2870, and 2880. The host control circuit 2100 that executes the first playback channel primary control 2840, the second playback channel primary control 2850, and the volume controls 2860, 2870, and 2880 incorporated in the audio data is the “second volume control circuit 2100” of the present invention. This corresponds to "control means".

In this way, the sound output from each speaker 24 (L0/R0/L1/R1, SUB0, SUB1) is determined by the volume of the total volume TV0 to TV3, the volume of the primary volume that is the volume of each playback channel, and the volume of the secondary volume. Since it is defined by multiplying the volume by the volume, it is possible to provide diversity in the volume of the game sound. In particular, since the volumes of the total volumes TV0 to TV3 are also determined by the volume output by the debug volume control 2830 during debugging, the game sound data used in the game can be used as is when debugging. This makes it possible to improve work efficiency.

In addition, the volume of normal game sounds can be changed based on the operation performed by the player to change the volume, but specific sounds such as error sounds and warning sounds for illegal activities, etc. Regarding game sounds, the second playback channel primary control 2850 outputs a constant volume regardless of whether or not an operation to change the volume has been performed. Therefore, it is not possible to hide the occurrence of an error or illegal act, making it possible to improve security.

In the pachinko game machine 1 of this embodiment, the volume control 2810 by the hardware switch has three levels, for example, large, medium, and small. Further, there are seven levels of user volume control 2820 using the volume setting screen, and these are set in conjunction with the hardware switch: [Small] = [1], [Medium] = "4", and [Large] = "7".

As explained above, in the pachinko game machine 1 of the present embodiment, the volume of a specific sound such as an error sound can be maintained only by the control by the second playback channel primary control 2850. It becomes possible to easily control the volume of other normal sounds by changing the volume according to the volume adjustment while maintaining the volume of the other normal sounds. Note that processing by the host control circuit 2100 when volume adjustment is performed will be described later with reference to FIGS. 86 to 90.

[1-2-5-2. Connection configuration between digital audio power amplifier and speakers]
Next, with reference to FIG. 14, a connection configuration between the digital audio power amplifier 2620 and its peripheral circuits provided in the built-in relay board 2600 and the speaker 24 will be described. FIG. 14 is a connection configuration diagram between the built-in relay board 2600 and the speaker 24. As shown in FIG. Note that FIG. 14 shows a state in which the speaker 24 is not connected to the built-in relay board 2600 in order to make the configuration of the connection part clearer.

In the pachinko game machine 1 of this embodiment, as shown in FIG. 14, a speaker box 24a provided with a speaker 24 is connected to a built-in relay board 2600 via a harness 3000.

The built-in relay board 2600 includes a digital audio power amplifier 2620, an LC circuit 2630, a connection terminal group 2640 including four connection terminals (first to fourth connection terminals), two resistors 2650 and 2660, and a capacitor. 2670 and a NOT circuit (logic circuit) 2680.

The digital audio power amplifier 2620 amplifies the input audio signal (audio data), outputs the amplified audio signal to the speaker 24, and drives the speaker 24. LC circuit 2630 is composed of a resonant circuit including a coil and a capacitor. Further, the NOT circuit 2680 is a logic circuit that inverts the level of an input signal and outputs the inverted signal.

A clock input terminal (MCK) and a data input terminal (SDATA) of the digital audio power amplifier 2620 are connected to the audio/LED control circuit 2200. The clock signal (master clock signal) output from the audio/LED control circuit 2200 is input to the clock input terminal (MCK) of the digital audio power amplifier 2620, and the audio/LED control circuit is input to the data input terminal (SDATA). The audio signal (audio data) output from the control circuit 2200 is input.

Further, the first output terminal (OUTM1) and the second output terminal (OUTM2) of the digital audio power amplifier 2620 are connected to the first connection terminal and the second connection terminal in the connection terminal group 2640 of the built-in relay board 2600, respectively, via the LC circuit 2630. Connected to the second connection terminal. Note that although this embodiment shows an example in which two output terminals of the digital audio power amplifier 2620 are provided, the present invention is not limited to this, and may be modified as appropriate depending on, for example, the functions and specifications of the speaker 24. Can be done.

Furthermore, the digital audio power amplifier 2620 has a mute terminal (MUTE: audio output control terminal). When the level (amplitude value) of the voltage signal applied to the mute terminal is LOW level, the digital audio power amplifier 2620 outputs the audio signal from the first output terminal (OUTM1) and the second output terminal (OUTM2). It has a function of stopping output or grounding these output terminals via a high resistance (hereinafter referred to as a mute function). That is, when the level of the voltage signal applied to the mute terminal is LOW level, the digital audio power amplifier 2620 outputs the signal from the first output terminal (OUTM1) and the second output terminal (OUTM2) to the first output terminal of the built-in relay board 2600. It has a function of generating a state in which the output of the audio signal to the connection terminal and the second connection terminal is stopped.

On the other hand, when the level (amplitude value) of the voltage signal applied to the mute terminal (MUTE) is HIGH level, the digital audio power amplifier 2620 outputs the first output terminal (OUTM1) and the second output terminal (OUTM2). Outputs audio signals from.

A third connection terminal in the connection terminal group 2640 of the built-in relay board 2600 is connected to an input terminal of a NOT circuit 2680 via a resistor 2660. Further, an output terminal of the NOT circuit 2680 is connected to a mute terminal (MUTE) of the digital audio power amplifier 2620. Note that the signal wiring between the third connection terminal of the built-in relay board 2600 and the resistor 2660 is connected to a power supply voltage (+5V) terminal provided inside the built-in relay board 2600 via the resistor 2650. Further, the signal wiring between the input terminal of the NOT circuit 2680 and the resistor 2660 is connected (grounded) to a ground (GND) terminal provided in the built-in relay board 2600 via a capacitor 2670. Further, the fourth connection terminal of the built-in relay board 2600 is connected to a ground (GND) terminal.

As shown in FIG. 14, the speaker 24 is attached to a speaker box 24a made of a wooden frame. Further, the speaker box 24a is provided with a connection terminal group 24b including four connection terminals (first to fourth connection terminals). The first connection terminal and second connection terminal of the speaker box 24a are connected to the speaker 24 via signal wiring. Further, the third connection terminal (specific connection terminal) of the speaker box 24a is electrically connected to the fourth connection terminal by the signal wiring W1.

As shown in FIG. 14, the harness 3000 is configured by bundling four signal wires. The four connection terminals (first to fourth connection terminals) on one side of the four signal wires are connected to the first to fourth connection terminals of the built-in relay board 2600, respectively. On the other hand, the other four connection terminals (fifth connection terminal to eighth connection terminal) of the four signal wires are connected to the first connection terminal to fourth connection terminal of the speaker box 24a, respectively. That is, the first connection terminal of the built-in relay board 2600 and the first connection terminal of the speaker box 24a are connected by the signal wiring between the first connection terminal and the fifth connection terminal in the harness 3000, and the built-in relay board 2600 The second connection terminal of the speaker box 24a is connected to the second connection terminal of the speaker box 24a by a signal wiring between the second connection terminal and the sixth connection terminal in the harness 3000. Further, the third connection terminal of the built-in relay board 2600 and the third connection terminal of the speaker box 24a are connected by signal wiring between the third connection terminal and the seventh connection terminal in the harness 3000. The fourth connection terminal of the speaker box 24a is connected to the fourth connection terminal of the speaker box 24a by a signal wiring between the fourth connection terminal and the eighth connection terminal in the harness 3000. Thereby, the speaker 24 is connected to the built-in relay board 2600 via the harness 3000.

Note that the number of signal wires included in the harness 3000 is not limited to four, and may be changed as appropriate, for example, depending on the specifications of the digital audio power amplifier 2620 and the speaker 24, the connection configuration between them, and the like. The harness 3000 includes at least signal wiring for connecting the output terminal of the digital audio power amplifier 2620 and the speaker 24, and signal wiring for grounding the mute terminal of the digital audio power amplifier 2620 via the speaker box 24a. should be included.

When the built-in relay board 2600 and the speaker 24 are connected via the harness 3000 as described above, the first output terminal (OUTM1) and the second output terminal (OUTM2) of the digital audio power amplifier 2620 are connected via the harness 3000. and is connected to the speaker 24. Further, the mute terminal (MUTE) of the digital audio power amplifier 2620 is grounded via the NOT circuit 2680, the harness 3000, and the signal wiring W1 between the third connection terminal and the fourth connection terminal of the speaker box 24a.

As a result, when the speaker 24 is connected to the built-in relay board 2600 (digital audio power amplifier 2620) via the harness 3000, a LOW level voltage signal is input to the NOT circuit 2680, so the digital audio power amplifier 2620 The level (amplitude value) of the voltage signal input to the mute terminal (MUTE) of is HIGH level. In this case, audio signals are output from the first output terminal (OUTM1) and the second output terminal (OUTM2) of the digital audio power amplifier 2620 to the speaker 24.

On the other hand, when the speaker 24 is not connected to the built-in relay board 2600 (digital audio power amplifier 2620), the third connection terminal of the built-in relay board 2600 is in an open state. In this case, since the power supply voltage (+5V) is input to the NOT circuit 2680, the level (amplitude value) of the voltage signal input to the mute terminal (MUTE) of the digital audio power amplifier 2620 becomes a LOW level, and the digital audio power amplifier The above-described mute function of 2620 is activated.

That is, when the speaker 24 is disconnected from the built-in relay board 2600 (digital audio power amplifier 2620), the built-in relay board 2600 is connected to the first output terminal (OUTM1) and the second output terminal (OUTM2) of the digital audio power amplifier 2620. A state is generated in which the output of the audio signal to the first connection terminal and the second connection terminal of is stopped. As a result, the occurrence of a resonance phenomenon between the digital audio power amplifier 2620 (output terminal) and the first and second connection terminals of the built-in relay board 2600 is suppressed, and the occurrence of problems such as failure of the digital audio power amplifier 2620 is suppressed. It can be prevented.

As described above, in this embodiment, the mute function of the digital audio power amplifier 2620 can be activated regardless of software control by the host control circuit 2100 and the audio/LED control circuit 2200. Therefore, for example, in a situation where the speaker 24 is disconnected from the built-in relay board 2600, even if the host control circuit 2100 and the audio/LED control circuit 2200 recognize that they are controlling the output of audio signals, the program In cases where an audio signal is being output erroneously due to a bug (malfunction), or in a pachinko gaming machine 1 that is structured so that the game board cannot be replaced without removing the speaker 24 from the harness 3000, after the game board has been replaced. Even if a situation occurs such as when the door is closed and audio output is started without connecting the speaker 24 and the harness 3000 by mistake, the mute function of the digital audio power amplifier 2620 described above operates in terms of hardware. In this case, the digital audio power amplifier 2620 can be reliably protected, and the safety of the pachinko game machine 1 can be improved.

Furthermore, in this embodiment, as described above, the third connection terminal of the built-in relay board 2600 is connected to the signal wiring W1 between the harness 3000 and the third connection terminal and the fourth connection terminal of the speaker box 24a. It is connected to a ground (GND) terminal provided inside the built-in relay board 2600. In such a configuration, when the signal level of the third connection terminal of the built-in relay board 2600 is LOW, it is difficult to determine whether this is due to the fourth connection terminal of the built-in relay board 2600 being grounded. Since this can be determined by measuring the signal level of the fourth connection terminal of the built-in relay board 2600, the digital output operation from the digital audio power amplifier 2620 can be managed more accurately.

[1-2-6. Display control circuit]
Next, the internal configuration of display control circuit 2300 will be described with reference to FIG. 15. FIG. 15 is a block diagram showing the circuit configuration inside the display control circuit 2300 and the connection relationship between the display control circuit 2300 and its various peripheral devices and peripheral circuit sections.

As shown in FIG. 15, the display control circuit 2300 includes a memory controller 2310, a command memory 2320, a command parser 2330, a video decoder 2340, a still image decoder 2350, an SDRAM controller 2360, a built-in VRAM 2370, and a first It includes a display controller 2380, a second display controller 2390, a 3D (Dimension) geometry engine 2400, and a rendering engine 2410. The connection relationships among the various parts in the display control circuit 2300 and the connection relationships between the display control circuit 2300 and its various peripheral devices and peripheral circuits are as follows.

Within the display control circuit 2300, a memory controller 2310 is connected to a command parser 2330, a video decoder 2340, and a still image decoder 2350. In addition to the memory controller 2310, the command parser 2330 is connected to a command memory 2320, a video decoder 2340, a still image decoder 2350, and a 3D geometry engine 2400. Video decoder 2340 is connected to SDRAM controller 2360 in addition to memory controller 2310 and command parser 2330. Still image decoder 2350 is connected to built-in VRAM 2370 in addition to memory controller 2310 and command parser 2330.

Furthermore, in the display control circuit 2300, the SDRAM controller 2360 is connected to a built-in VRAM 2370, a first display controller 2380, and a second display controller 2390 in addition to the video decoder 2340. The built-in VRAM 2370 is connected to a first display controller 2380, a second display controller 2390, and a rendering engine 2410 in addition to the still image decoder 2350 and the SDRAM controller 2360. Additionally, 3D geometry engine 2400 is connected to rendering engine 2410 in addition to command parser 2330.

Note that the SDRAM 2500 is connected to a memory controller 2310 and an SDRAM controller 2360 within the display control circuit 2300. Further, the CGROM board 2040 is connected to a memory controller 2310 within the display control circuit 2300. Further, the host control circuit 2100 is connected to a memory controller 2310 and a command memory 2320 within the display control circuit 2300. Further, the display device 16 is connected to a first display controller 2380 and a second display controller 2390 within the display control circuit 2300.

Next, the configuration of each part in display control circuit 2300 will be explained.

The memory controller 2310 mainly controls communication between various external memories (CGROM board 2040 and SDRAM 2500) and the display control circuit 2300. For example, the memory controller 2310 performs processing such as sending and receiving address designation signals for external memories to be controlled, memory ready and busy management, and stores data (acting data) stored at specified addresses in various memories. , command data, etc.).

Command memory 2320 is a built-in memory that stores a command list. Note that the command list can also be stored in the SDRAM 2500 and the CGROM board 2040 (CGROM 2060) in addition to the command memory 2320.

The command parser 2330 obtains a command list from a specified memory (command memory 2320, SDRAM 2500, or CGROM 2060). Specifically, in this embodiment, the host control circuit 2100 stores the type of memory (command memory 2320, SDRAM 2500, or CGROM 2060) in which the command list is placed in a system control register (not shown) in the display control circuit 2300; The start address is set. The command parser 2330 then accesses the start address in the memory specified by the system control register (not shown) and obtains the command list.

Additionally, the command parser 2330 analyzes the acquired command list to generate a specific control code, and outputs the control code to the video decoder 2340, still image decoder 2350, and 3D geometry engine 2400. In this embodiment, each image processing module in the display control circuit 2300 operates based on the control code output by the command parser 2330.

The video decoder 2340 decodes the video compressed data acquired from the CGROM board 2040 or the SDRAM 2500. The video decoder 2340 then outputs the decoded video data to the SDRAM 2500 (external RAM). Note that the video data (decoding result) output from the video decoder 2340 is stored in a movie buffer provided in the SDRAM 2500.

Still image decoder 2350 decodes still image compressed data acquired from CGROM board 2040 or SDRAM 2500. Still image decoder 2350 then outputs the decoded still image data to built-in VRAM 2370. Note that the still image data (decoding result) output from the still image decoder 2350 is temporarily stored in a sprite buffer, which will be described later, provided in the built-in VRAM 2370.

The SDRAM controller 2360 is a controller that controls operations such as storing decoded video data and still image data in the RAM, and transferring image data between the built-in VRAM 2370 and the CGROM board 2040 or the SDRAM 2500.

The built-in VRAM 2370 operates as a work RAM when various processes such as decoding processing and rendering processing are executed in the drawing control processing by the display control circuit 2300. Further, various image data are temporarily stored in the built-in VRAM 2370 in image data transfer processing between the built-in VRAM 2370 and the CGROM board 2040 or the SDRAM 2500, which is performed in each process in the drawing control processing described later.

Each of the first display controller 2380 and the second display controller 2390 obtains the rendering result (drawing result) generated by the rendering engine 2410 and outputs the rendering result to the display device 16. As a result, a predetermined image is displayed on the display screen of the display device 16. Note that when two display controllers are provided as in the pachinko game machine 1 of this embodiment, two screens are provided on the display device 16 and each screen is controlled by one display control circuit 2300 (one chip). Can be controlled independently.

The 3D geometry engine 2400 performs processing for converting three-dimensional information into two-dimensional information (projection transformation processing) and affine transformation such as enlargement, reduction, rotation, and movement of figures based on the control code input from the command parser 2330. (shape conversion) processing. The 3D geometry engine 2400 then outputs the results of the conversion process to the rendering engine 2410.

The rendering engine 2410 refers to a texture source (SDRAM 2500 in this embodiment) in which decompressed still image data and moving image data are stored, and performs rendering (drawing) processing on the image data. The rendering engine 2410 then writes the rendering result to a rendering target (in this embodiment, the built-in VRAM 2370 or SDRAM 2500).

Note that "rendering (drawing)" as used herein means editing decoded data according to specified information such as scaling and rotation of a video (in this embodiment, information output from the 3D geometry engine 2400). It is to be. Furthermore, the "rendering engine" here includes, for example, a "rasterizer" and a "pixel shader". Therefore, similarly to the pixel shader, the rendering engine 2410 uses ARGB values (A: alpha value indicating transparency (opacity), R: brightness value of red component, G: green component) for each pixel of image data. A calculation process is also performed on the brightness value of B: the brightness value of the blue component).

[1-2-6-1. Connection configuration between display control circuit and CGROM]
The pachinko game machine 1 of this embodiment has a configuration that can handle different types of CGROMs (NOR type or NAND type) connected to the display control circuit 2300. Here, the connection configuration between the display control circuit 2300 and its peripheral circuits provided in the sub-board 2020 and the CGROM mounted on the CGROM board will be described with reference to FIGS. 16 and 17.

FIG. 16 is a connection configuration diagram between the sub-board 2020 and the CGROM board 2040a when the CGROM is a NOR-type CGROM 2060a (NOR-type flash memory). Further, FIG. 17 is a connection configuration diagram between the sub-board 2020 and the CGROM board 2040b when the CGROM is a NAND-type CGROM 2060b (NAND-type flash memory). In addition, in FIGS. 16 and 17, the CGROM board is shown detached from the sub-board 2020 in order to make the configuration of the connection part clearer, but in reality, both boards are connected via a board-to-board connector. Connected.

(1) Configuration of sub-board First, the internal configuration of sub-board 2020 will be described. As is clear from the comparison between FIG. 16 and FIG. 17, the configuration of the sub-board 2020 when the NOR-type CGROM 2060a is mounted on the CGROM board 2040a is the same as that when the NAND-type CGROM 2060b is mounted on the CGROM board 2040b. The same is true.

As shown in FIGS. 16 and 17, the sub-board 2020 is provided with a display control circuit 2300, and is provided with a bidirectional balance transceiver 3010 and an AND circuit 302 (AND gate) as its peripheral circuits. Further, the sub-board 2020 is provided with various signal wirings (buses) and a terminal group 3030 including a plurality of connection terminals connected directly or indirectly to the display control circuit 2300 via various buses.

The bidirectional balanced transceiver 3010 has four input/output terminals (terminals A0 to A3 in FIG. 16) on one side, and four input/output terminals on the other side connected to the four input/output terminals (terminals A0 to A3) on the other side. It has two input/output terminals (terminals B0 to B3 in FIG. 16). The bidirectional balanced transceiver 3010 also has two control terminals (terminals in FIG. OE and terminal DIR).

The bidirectional balanced transceiver 3010 operates between input/output terminals A0 to A3 and input/output terminals B0 to B3 depending on the combination of signal levels of voltage signals applied to control terminals OE and DIR, respectively. Switch the communication direction of the signal. Thereby, even if a mismatch occurs in the communication direction (communication operation) for some reason, the safety of the communication operation between the display control circuit 2300 and the CGROM can be ensured. Note that the communication direction switching control operation in the bidirectional balanced transceiver 3010 will be described in detail later. Furthermore, the bidirectional balanced transceiver 3010 used in this embodiment is also compatible with a system having two power supplies of 3.3V and 5V.

The display control circuit 2300 is provided with four input/output terminals (terminal GMA31/GRB3 to terminal GMA28/GRB0 in FIG. 16). These input/output terminals GMA31/GRB3 to input/output terminals GMA28/GRB0 act as address bus output terminals when the CGROM is a NOR type CGROM2060a, and are ready when the CGROM is a NAND type CGROM2060b. /Acts as a busy signal input terminal. The display control circuit 2300 is also provided with 26 output terminals (terminal GMA27 to terminal GMA2 in FIG. 16) that act as output terminals for data related to the address of the data storage area in the CGROM (address designation data, etc.). It will be done.

Furthermore, the display control circuit 2300 is provided with two CG memory chip enable output terminals (terminal GCE_0 and terminal GCE_1 in FIG. 16). Note that in this embodiment, the display control circuit 2300 has two memory spaces corresponding to two CG memory chip enable output terminals (GCE_0, GCE_1: specific output terminals), and each memory space includes a memory Information such as type, bus width, access timing, etc. is set. However, in this embodiment, the display control circuit 2300 has a configuration that cannot support (use) a case where a synchronous mode ROM and an asynchronous mode ROM are mixed.

Furthermore, the display control circuit 2300 is provided with a plurality of data bus input terminals for acquiring image data (compressed data of moving images/still images) from the CGROM via a data bus.

Note that the electrical connection relationship of the above-mentioned components provided on the sub-board 2020 is as follows.

The input/output terminals GMA31/GRB3 to input/output terminals GMA28/GRB0 of the display control circuit 2300 are connected to the input/output terminals B0 to B3 of the bidirectional balanced transceiver 3010, respectively, as shown in FIGS. 16 and 17. be done. The input/output terminals A0 to A3 of the bidirectional balanced transceiver 3010 are connected to the first to fourth connection terminals of the terminal group 3030, respectively. That is, the input/output terminals GMA31/GRB3 to input/output terminals GMA28/GRB0 of the display control circuit 2300 are connected to the first to fourth connection terminals of the terminal group 3030 via the bidirectional balanced transceiver 3010, respectively. Ru.

Furthermore, the output terminals GMA27 to GMA2 of the display control circuit 2300 are connected to the 9th to 34th connection terminals of the terminal group 3030, respectively, and the CG memory chip enable output terminal GCE_0 and the CG memory chip enable output terminal GCE_1 are , are connected to the 35th connection terminal and the 36th connection terminal of the terminal group 3030, respectively. Further, the plurality of data bus input terminals of the display control circuit 2300 are respectively connected to corresponding connection terminals after the 37th connection terminal of the terminal group 3030.

The control terminal DIR of the bidirectional balanced transceiver 3010 is connected to the fifth connection terminal of the terminal group 3030, and the control terminal OE is connected to the output terminal of the AND circuit 302. One input terminal of the AND circuit 302 is connected to the CG memory chip enable output terminal GCE_0, and the other input terminal of the AND circuit 302 is connected to the CG memory chip enable output terminal GCE_1. Further, the sixth connection terminal and the seventh connection terminal of the terminal group 3030 of the sub-board 2020 are connected to the power supply voltage (+3.3V) terminal provided on the sub-board 2020, and the eighth connection terminal is connected to the sub-board 2020. It is connected to the provided ground (GND) terminal.

(2) Configuration of CGROM board (NOR type) Next, the internal configuration of the CGROM board 2040a on which the NOR type CGROM 2060a is mounted will be described with reference to FIG.

When a NOR-type CGROM 2060a is mounted on the CGROM board 2040a, the CGROM board 2040a includes terminals including various signal wirings (buses) and a plurality of connection terminals connected to the CGROM 2060a via the various buses, as well as the NOR-type CGROM 2060a. A group 3110 is provided.

The first to fourth connection terminals and the connection terminals after the ninth connection terminal in the terminal group 3110 provided on the CGROM board 2040a are connected to the CGROM 2060a.

In the example shown in FIG. 16, the CGROM 2060a is a NOR flash memory (random access flash memory), so the first to fourth connection terminals and the ninth to 34th connection terminals in the terminal group 3110 The connection terminal is connected to an input terminal (not shown) of the address bus of the CGROM 2060a. Further, the 35th connection terminal and the 36th connection terminal in the terminal group 3110 are connected to a CG memory chip enable input terminal (not shown) of the CGROM 2060a, and the connection terminals after the 37th connection terminal are connected to the CGROM 2060a by the display control circuit 2300. It is connected to the data output terminal of the CGROM 2060a used when acquiring image data (compressed data of moving images/still images) from the CGROM 2060a.

Further, the fifth connection terminal (predetermined connection terminal) in the terminal group 3110 provided on the CGROM board 2040a is connected to the eighth connection terminal via the signal wiring W2, and the eighth connection terminal is connected to the CGROM board 2040a. It is connected to the provided ground (GND) terminal. That is, when the CGROM 2060a is a NOR flash memory, the fifth connection terminal is grounded via the signal wiring W2. Further, the sixth connection terminal and the seventh connection terminal in the terminal group 3110 are connected to a power supply voltage (+3.3V) terminal provided on the CGROM board 2040a.

The number of connection terminals included in the terminal group 3110 is the same as the number of connection terminals in the CGROM board connection terminal group 3030 provided on the sub-board 2020. When the CGROM board 2040a is connected (attached) to the sub-board 2020, both boards are connected so that the connection terminal of the CGROM board 2040a is connected to the connection terminal of the sub-board 2020 having the same terminal number. That is, as shown in FIG. 16, the first connection terminal, second connection terminal, ..., 37th connection terminal, ... of the CGROM board 2040a are the same as the first connection terminal, second connection terminal, ..., 37th connection terminal, ... of the sub-board 2020. 37 connection terminals, respectively.

(3) Configuration of CGROM board (NAND type) Next, the internal configuration of the CGROM board 2040b on which the NAND type CGROM 2060b is mounted will be described with reference to FIG. In the configuration of the CGROM board 2040b shown in FIG. 17, the same components as the CGROM board 2040a mounted with the NOR type CGROM 2060a shown in FIG. 16 are denoted by the same reference numerals.

When a NAND type CGROM 2060b is mounted on the CGROM board 2040b, a transistor circuit 312 is provided on the CGROM board 2040b together with the NAND type CGROM 2060b as a peripheral circuit thereof. Further, the CGROM board 2040b is provided with various signal wirings (buses) and a terminal group 3110 including a plurality of connection terminals directly or indirectly connected to the CGROM 2060b via the various buses.

The first to fourth connection terminals in the terminal group 3110 of the CGROM board 2040b are connected to the drain terminal of the transistor circuit 312. Note that the gate terminal of the transistor circuit 312 is connected to the CGROM 2060b, and the source terminal is connected to a ground (GND) terminal provided on the CGROM substrate 2040b. That is, the first to fourth connection terminals are connected to the CGROM 2060b via the transistor circuit 312.

In the example shown in FIG. 17, the CGROM 2060b is a NAND flash memory (sequential access flash memory), so the gate terminal of the transistor circuit 312, that is, the first to fourth connections in the terminal group 3110 The terminal is connected to a ready/busy output terminal (not shown) provided in the CGROM 2060b.

Further, the fifth connection terminal (predetermined connection terminal) in the terminal group 3110 of the CGROM board 2040b is connected to the sixth connection terminal and the seventh connection terminal via the signal wiring W3, and the sixth connection terminal and the seventh connection terminal are connected to the sixth connection terminal and the seventh connection terminal. The terminal is connected to a power supply voltage (+3.3V) terminal provided on the CGROM board 2040b. That is, when the CGROM 2060b is a NAND flash memory, the fifth connection terminal is connected to the power supply voltage (+3.3V) terminal via the signal wiring W3.

Further, the eighth connection terminal in the terminal group 3110 of the CGROM board 2040b is connected to a ground (GND) terminal provided on the CGROM board 2040b.

Furthermore, the connection terminals after the ninth connection terminal in the terminal group 3110 of the CGROM board 2040b are connected to the CGROM 2060b. At this time, the 9th connection terminal to the 34th connection terminal are connected to an input terminal (not shown) related to address data provided in the CGROM 2060b, and the 35th connection terminal and the 36th connection terminal are connected to the CGROM 2060b provided in the CGROM 2060b. Connected to the memory chip enable input terminal. Further, the connection terminals after the 37th connection terminal are connected to data output terminals (not shown) of the CGROM 2060b, which are used when the display control circuit 2300 acquires image data (compressed data of moving images/still images) from the CGROM 2060b. Ru.

Note that even when the NAND type CGROM 2060b is mounted on the CGROM board 2040b, the number of connection terminals included in the terminal group 3110 of the CGROM board 2040b is equal to the number of connection terminals included in the terminal group 3030 for CGROM board connection provided on the sub-board 2020. It is the same as the number of connection terminals. When the CGROM board 2040b is connected (attached) to the sub-board 2020, both boards are connected so that the connection terminal of the CGROM board 2040b is connected to the connection terminal of the sub-board 2020 having the same terminal number. That is, as shown in FIG. 17, the first connection terminal, second connection terminal, ..., 37th connection terminal, ... of the CGROM board 2040b are the same as the first connection terminal, second connection terminal, ..., 37th connection terminal, ... of the sub-board 2020. 37 connection terminals, respectively.

[1-2-6-2. Communication operation between display control circuit and CGROM]
Next, the operation when the display control circuit 2300 acquires image data (compressed data of moving images/still images) from the CGROM will be described with reference to FIGS. 16 to 19. Note that FIG. 18 is a truth table showing the correspondence between input signals and output signals in the AND circuit 302 provided on the sub-board 2020, and FIG. 3 is a truth table showing the correspondence between the signal levels applied to the control terminal OE and the control terminal DIR and the communication direction in FIG.

(1) Operation of AND circuit and bidirectional balanced transceiver As shown in FIG. 18, the AND circuit 302 operates when the bidirectional balanced transceiver 3010 A HIGH level signal is output to the control terminal OE, and under other input conditions, a LOW level signal is output to the control terminal OE.

As shown in FIG. 19, the bidirectional balanced transceiver 3010 becomes a bidirectional balanced transceiver when a LOW level signal (voltage signal) is input to the control terminal OE and a LOW level signal is input to the control terminal DIR. The input/output terminals A0 to A3 of 3010 are made to act as output terminals, and the input/output terminals B0 to B3 are made to act as input terminals. In this case, the direction of communication between the display control circuit 2300 and the CGROM is from the display control circuit 2300 to the CGROM.

Furthermore, when a LOW level signal is input to the control terminal OE and a HIGH level signal is input to the control terminal DIR, the bidirectional balanced transceiver 3010 inputs and outputs the input/output terminals A0 to I/O of the bidirectional balanced transceiver 3010. The terminal A3 acts as an input terminal, and the input/output terminals B0 to B3 act as output terminals. In this case, the direction of communication between the display control circuit 2300 and the CGROM is from the CGROM to the display control circuit 2300.

Note that if the combination of the signal level input to the control terminal OE of the bidirectional balanced transceiver 3010 and the signal level input to the control terminal DIR is a combination other than the above (HIGH is input to the control terminal OE of the bidirectional balanced transceiver 3010) level signal is input), the input/output terminals A0 to A3 and the input/output terminals B0 to B3 of the bidirectional balanced transceiver 3010 are in the HIGH impedance state (“Z” in FIG. 19). ), that is, the state is equivalent to an open state, and no communication is performed between the display control circuit 2300 and the CGROM.

(2) Communication operation between display control circuit and CGROM (NOR type) First, consider a case where a CGROM board 2040a on which a NOR type CGROM 2060a is mounted is connected (mounted) to the sub-board 2020.

In this case, in this embodiment, since a LOW level signal is output from at least one of the two CG memory chip enable output terminals GCE_0 and GCE_1 of the display control circuit 2300, a LOW level signal is output to the control terminal OE of the bidirectional balanced transceiver 3010. A level signal is input. Note that the signal levels of the CG memory chip enable output terminals GCE_0 and GCE_1 are set in the hardware initialization process (see FIG. 63, which will be described later).

In this embodiment, since the amplitude values of the output signals from the CG memory chip enable output terminals GCE_0 and GCE_1 (specific terminals), which are set in advance by the sub-control circuit 200, differ depending on the type of CGROM, the display control circuit The amplitude value of the signal output from the CG memory chip enable output terminals GCE_0 and GCE_1 provided in 2300 changes depending on the type of storage means. However, the mode in which "the amplitude value of the output signal changes depending on the type of CGROM" is not limited to this mode. As explained in Modification 7 below, the display control circuit 2300 detects the type of connected storage means, and based on the detection result, outputs signals from the CG memory chip enable output terminals GCE_0 and GCE_1 (specific terminals). The amplitude value of the output signal may also be set.

Further, the fifth connection terminal of the sub-board 2020 to which the control terminal DIR of the bidirectional balance transceiver 3010 is connected is grounded via the fifth connection terminal of the CGROM board 2040a and the signal wiring W2, as shown in FIG. Therefore, a LOW level signal is input to the control terminal DIR.

Therefore, when the CGROM board 2040a equipped with the NOR type CGROM 2060a is connected to the sub-board 2020, the input/output terminals A0 to A3 of the bidirectional balanced transceiver 3010 are used as output terminals, as shown in FIG. The input/output terminals B0 to B3 act as input terminals. That is, the direction of communication between the display control circuit 2300 and the CGROM 2060a in the bidirectional balanced transceiver 3010 is from the display control circuit 2300 to the CGROM 2060a.

In this case, the signal wiring connected via the first to fourth connection terminals of the sub-board 2020 and the first to fourth connection terminals of the CGROM board 2040a can be used as an address bus, and the display control The circuit 2300 can normally perform a memory addressing operation for the NOR type CGROM 2060a. As a result, the display control circuit 2300 can directly specify an address via the address bus and perform a data read operation.

(3) Communication operation between display control circuit and CGROM (NAND type) Next, consider a case where a CGROM board 2040b on which a NAND type CGROM 2060b is mounted is connected (mounted) to the sub-board 2020.

Even in this case, in this embodiment, a LOW level signal is output from at least one of the two CG memory chip enable output terminals CGE_0 and CGE_1 of the display control circuit 2300, so that the signal is output from the control terminal OE of the bidirectional balanced transceiver 3010. A LOW level signal is input. That is, in this embodiment, a LOW level signal is input to the control terminal OE of the bidirectional balanced transceiver 3010 regardless of whether the type of CGROM is a NOR type or a NAND type. Further, as shown in FIG. 17, the fifth connection terminal of the sub-board 2020 to which the control terminal DIR of the bidirectional balanced transceiver 3010 is connected is connected to the power supply voltage ( +3.3V) terminal, a HIGH level signal is input to the control terminal DIR.

Therefore, when the CGROM board 2040b equipped with the NAND type CGROM 2060b is connected to the sub-board 2020, the input/output terminals A0 to A3 of the bidirectional balanced transceiver 3010 are used as input terminals, as shown in FIG. The input/output terminals B0 to B3 act as output terminals. That is, the communication direction between the display control circuit 2300 and the CGROM 2060b in the bidirectional balanced transceiver 3010 is from the CGROM 2060b to the display control circuit 2300.

In this case, the signal wires connected via the first to fourth connection terminals of the sub board 2020 and the first to fourth connection terminals of the CGROM board 2040b are used as communication wires for ready/busy signals. Can be done. That is, in this case, it becomes possible to execute the process of transmitting the ready/busy signal from the CGROM 2060 to the display control circuit 2300, which the display control circuit 2300 refers to when reading data from the NAND-type CGROM 2060b in a sequential access method. As a result, the display control circuit 2300 can normally perform the operation of acquiring the memory state (ready/busy state) for the NAND type CGROM 2060b.

As described above, in this embodiment, even if the type of CGROM changes, the communication operation between the display control circuit 2300 and the CGROM can be performed normally without changing the configuration of the sub-board 2020. Therefore, in this embodiment, an optimal CGROM can be selected in consideration of data capacity, communication speed, price, etc., for example. For example, when manufacturing a new pachinko game machine 1, the sub-board 2020 used in a pachinko game machine created in the past may be used due to conditions such as data capacity and communication speed, and only the type of CGROM may be changed. Even in such cases, it can be easily dealt with. That is, in the pachinko game machine 1 of this embodiment, it is possible to select a CGROM according to the embodiment, and the expandability of the pachinko game machine 1 can be ensured.

Furthermore, in this embodiment, by using the bidirectional balanced transceiver 3010, the first to fourth connection terminals in the terminal group 3030 of the sub-board 2020 and the first connection terminal in the terminal group 3110 of the CGROM board 2040 are connected. The terminals to the fourth connection terminals can be used as data input/output terminals. In this case, there is no need to separately provide data input terminals and output terminals corresponding to the first to fourth connection terminals of the sub-board 2020 and the CGROM board 2040, which saves space on the sub-board 2020 and the CGROM board 2040. It is possible to aim for

Note that, as described above, in this embodiment, the bidirectional balanced transceiver 3010 can switch the "communication form" between the display control circuit 2300 and the CGROM depending on the type of CGROM. However, the "communication mode" between the display control circuit 2300 and the CGROM in this specification refers to the overall mode of transmitting and receiving various information between the display control circuit 2300 and the CGROM.

For example, the "communication form" between the display control circuit 2300 and the CGROM in this specification includes data (image data (compressed data of moving images/still images) necessary when displaying information regarding performance operations on the display device 16. )) Not only the mode of transmission and reception between the display control circuit 2300 and the CGROM, but also the mode of transmission and reception when communicating information specifying the address of the data stored in the CGROM between the display control circuit 2300 and the CGROM, and the display. The meaning also includes the transmission/reception mode when the control circuit 2300 receives a ready/busy signal from the CGROM. Note that the present invention is not limited to this, and the term "communication form" in this specification may mean only a communication form in which the information transmission/reception mode changes depending on the type of CGROM.

[2. Functional flow]
Next, the functional flow of the pachinko gaming machine according to the first embodiment of the present invention will be explained using FIG. 20. FIG. 20 is a diagram showing a functional flow of the pachinko gaming machine according to the first embodiment of the present invention.

As shown in FIG. 20, the pachinko game is a game in which a game ball is fired by a user's operation, and when the game ball wins various prizes, a game ball payout control process is performed. Further, pachinko games include special symbol games using special symbols and normal symbol games using normal symbols.

When a "big hit" occurs in a special symbol game or a "normal win" occurs in a regular symbol game, the probability that the game ball will win increases relatively, and the game ball payout control process is performed. It becomes easier.

In addition, various winnings include special symbol start winning, which is one of the conditions for the fluctuating display of special symbols in the special symbol game, and one condition for the fluctuating display of the normal symbols in the regular symbol game. It also includes a certain normal symbol starting prize.

Hereinafter, an outline of the processing flow of the special symbol game and the normal symbol game will be explained. The special symbol game and the normal symbol game are executed by the main CPU 101 as control processing.

(1) When there is a special symbol starting prize in the special symbol game, various random numbers (for example, random numbers for jackpot determination and random numbers for symbol determination) are input from various counters (for example, jackpot determination counter and symbol determination counter). ) are extracted (obtained), and each extracted random number value is stored (see the flow of the special symbol start winning process during the special symbol game shown in FIG. 20).

Further, as shown in FIG. 20, in the special symbol control process during the special symbol game, it is first determined whether a condition for starting variable display of the special symbol is satisfied. In this determination process, it is checked whether various data such as random numbers are stored due to the special symbol starting winning, and one condition is that the various data such as random numbers are stored, and the fluctuation display of the special symbol is It is determined that the conditions for starting the process have been met.

Next, when starting the variable display of the special symbols, the random number value for jackpot determination extracted from the jackpot determination counter is referred to, and a jackpot determination is made as to whether or not it is a "jackpot". After that, a stop symbol determination process is performed. In this process, the random number value for symbol determination extracted from the symbol determination counter and the result of the above-mentioned jackpot determination are referred to, and a special symbol to be stopped and displayed is determined.

Next, a variation pattern determination process is performed. In this process, a random number value is extracted from the counter for determining the variation pattern, and the random number value, the result of the above-mentioned jackpot determination, and the above-mentioned special symbol to be stopped and displayed are referred to, and the variation pattern of the special symbol (variable display pattern ) to determine.

Next, performance pattern determination processing is performed. In this process, a random value is extracted from the production pattern determining counter, and the random value, the result of the jackpot determination described above, the special symbol to be stopped and displayed, and the variation pattern of the special symbol described above are referred to, A performance pattern to be executed in conjunction with the variable display of special symbols is determined.

Next, as a result of the determined jackpot determination, the special symbol to be stopped and displayed, the variation pattern of the special symbol, and the production pattern accompanying the variable display of the special symbol are referred to, and a variation display control process is performed to control the variable display of the special symbol. , and performance control processing for performing a predetermined performance.

Then, when the fluctuation display control process and the performance display control process are completed, it is determined whether or not there is a "big hit". In this determination process, if it is determined that a "jackpot" has been achieved, a jackpot game state control process for performing a jackpot game state is executed. In addition, in the jackpot game state, the possibility of winning the various prizes described above increases. On the other hand, if it is determined that the "big hit" has not occurred, the jackpot game state control process is not executed.

If it is determined that a "big hit" has not been achieved, or if the jackpot game state control process is completed, a game state transition control process for shifting the game state is performed. In this gaming state transition control process, the normal gaming state, which is different from the jackpot gaming state, is managed.

The normal gaming state includes, for example, a gaming state in which a "jackpot" is determined with a predetermined probability (hereinafter referred to as "normal gaming state") in the jackpot determination described above, and a gaming state in which a "jackpot" is determined with a certain probability. A gaming state that increases more than the normal gaming state (hereinafter referred to as "high probability gaming state") and a gaming state in which it is easier to obtain a special symbol starting prize as a result of the normal hit determination described later (hereinafter referred to as "time-saving gaming state") ), etc. After that, the process of determining whether or not to start the variable display of the special symbols is performed again, and thereafter, the various processes of the special symbol control process described above are repeated.

In addition, in the pachinko game machine of this embodiment, when the game ball starts winning while the special symbol is being displayed in a variable manner, various data extracted at the time of the starting winning (random value for jackpot determination, random value for symbol determination, etc.) ) is stored until the condition for starting the variable display of the special symbol is met. In this way, storing various data (for example, random numbers for jackpot determination, etc.) until the conditions for starting the variable display of special symbols are satisfied is called "suspension", and the various data that is put on hold is called starting memory.

That is, if the game ball starts winning during the variable display of a special symbol, the execution of the variable display of the special symbol corresponding to the starting prize is suspended, and the execution of the variable display of the special symbol currently being executed is suspended. The changing display of the special symbols that are displayed starts in order. In the following, various data regarding the reserved special symbols are also referred to as "reserved balls."

In addition, in the pachinko game machine of this embodiment, as will be described later, two types of special symbol starting prizes (first starting hole winning and second starting hole winning) are provided, and a maximum of four prizes are given for each special symbol starting winning. It is possible to suspend execution of the variable display of special symbols until That is, in this embodiment, execution of the variable display of special symbols can be suspended for a total of up to eight special symbols, including four first special symbols and four second special symbols.

Although not shown in FIG. 20, the pachinko gaming machine 1 of the present embodiment determines whether the held ball is a hit or lost (whether or not there is a "jackpot" win) based on the above-mentioned information on the held balls, and It has a function of performing a predetermined performance based on the determination result, that is, a pre-reading performance function.

(2) When there is a normal symbol start win in the normal symbol game, a random value is extracted from the normal winning determination counter and the random value is stored (normal symbol start during the normal symbol game shown in Figure 20). (See prize winning processing flow).

Further, as shown in FIG. 20, in the normal symbol control process during the normal symbol game, it is first determined whether a condition for starting the variable display of the normal symbols is satisfied. In this determination process, it is referenced whether or not a random number value is stored by the normal symbol starting winning, and if the random number value is stored as one of the conditions, the condition for starting the fluctuating display of the normal symbol is satisfied. Discern.

Next, when starting the fluctuating display of normal symbols, the random value extracted from the normal hit determination counter is referred to, and a normal hit determination is performed to determine whether or not it is a "normal win." After that, a variation pattern determination process is performed. In this process, the result of the normal hit determination is referred to and the fluctuation pattern of the normal symbols is determined.

Next, the determined normal hit determination result and the variation pattern of the normal symbols are referred to, and a variation display control process that controls the variation display of the normal symbols and a production control process that performs a predetermined production are executed. .

When the fluctuation display control process and the effect display control process are completed, it is determined whether or not it is a "normal win". In this determination process, if it is determined that it is a "normal win", a normal win game control process for performing a normal win game is executed.

In the normal winning game control process, the possibility of winning the various prizes mentioned above increases, especially the possibility of winning by starting a special symbol of the game ball in the special symbol game. On the other hand, if it is determined that it is not a "normal win", the normal win game control process is not executed. After that, the process of determining whether or not to start the variable display of the normal symbols is performed again, and after that, the various processes of the normal symbol control process described above are repeated.

As mentioned above, in pachinko games, the payout of game balls depends on conditions such as whether or not there will be a "jackpot" in the special symbol game, the transition status of the gaming state, and whether or not it will be a "normal hit" in the normal symbol game. The ease with which control processing is performed changes.

In this embodiment, as a method for extracting various random numbers, a soft random number method is used in which random numbers are generated within a predetermined range (width) by executing a program by the main CPU 101. However, the present invention is not limited to this, and for example, if a pachinko game machine is equipped with a random number generator whose random numbers are updated at a predetermined period, a random number is obtained from a counter (so-called ring counter) in the random number generator. A hard random number method for extracting may be adopted as the method for extracting the various random numbers described above.

Note that when using the hard random number method, by determining the initial value of the random number value at a timing different from the predetermined cycle, it is possible to prevent the same random number value from being extracted at the predetermined cycle.

[3. Basic specifications of pachinko machines]
Next, the basic specifications of the pachinko gaming machine 1 will be explained using FIGS. 21 to 24. FIG. 21 is a diagram showing an example of a table showing the jackpot probability of the pachinko gaming machine 1, and FIG. 22 shows the hit type (hereinafter referred to as "main symbol") when the result of jackpot determination of the special symbol is a jackpot. FIG. 23 is a diagram showing an example of the selection rate, and FIG. 23 is a diagram showing an example of a special symbol variation time (variable display time) determination table stored in the main ROM 102. FIG. 24 is a diagram showing an example of a decorative symbol determination table stored in the sub-main ROM 2050 of the sub-control circuit 200. Note that in the following description, terms such as main CPU 101 and main RAM 103, which are not shown in FIGS. 21 to 24, are used, but these are shown in FIG.

In explaining the jackpot probability shown in FIG. 21, first, the jackpot in the pachinko gaming machine 1 will be briefly explained.

When the main CPU 101 detects the winning of a game ball into the first starting hole 420 (see FIG. 5, for example), the main CPU 101 extracts a random number for jackpot determination of the first special symbol from the jackpot determination counter, and extracts the random number for jackpot determination of the first special symbol from the jackpot determination counter. Referring to the first special symbol jackpot random number determination table (not shown), a jackpot determination (hereinafter referred to as "first special symbol jackpot determination") is performed for the extracted random numbers for jackpot determination. Note that extraction of the random number for jackpot determination of the first special symbol is performed even when the jackpot game state is controlled.

Similarly, when the main CPU 101 detects winning of a game ball into the second starting port 440 (see FIG. 5, for example), the main CPU 101 extracts a random number for jackpot determination of the second special symbol from the jackpot determination counter and stores it in the main RAM 103. Referring to the second special symbol jackpot random number determination table (not shown), a jackpot determination (hereinafter referred to as "second special symbol jackpot determination") is performed for the extracted random numbers for jackpot determination. Incidentally, the extraction of the random number for jackpot determination of the second special symbol is performed even when the jackpot game state is controlled.

When the jackpot determination of the first special symbol is performed, either a "jackpot" or a "loss" is determined. Moreover, when the jackpot determination for the second special symbol is performed, it is determined as either a "jackpot" or a "loss" similarly to the jackpot determination for the first special symbol. The jackpot random number determination table for the first special symbol and the jackpot random number determination table for the second special symbol stored in the main RAM 103 each contain values of probability variable flags (“0 (=off)” or “1 (=on)”). ), the relationship between the range (width) of random numbers for jackpot determination determined as “jackpot” or “loss” and the corresponding determination value data (“jackpot determination value data” and “loss determination value data”) is stipulated.

In this embodiment, the total random number is 65536 for both the first special symbol and the second special symbol. That is, the above-mentioned random numbers for jackpot determination are generated in the range (width) of 0 to 65535. This range is set as a fixed value. The jackpot probability is determined by the number of jackpot judgment value data for the range of jackpot judgment random numbers. Note that the range (width) of the random numbers for jackpot determination can be changed as appropriate.

Note that the probability change flag is one of the management flags stored in the main RAM 103, and is a flag for managing whether the gaming state is a "high probability gaming state" or not. When the gaming state is a "high probability gaming state", the probability variation flag is "1", and when it is a "low probability gaming state", the probability variation flag is "0".

Further, the time saving flag is one of the management flags stored in the main RAM 103, and is a flag for managing whether or not the gaming state is the "time saving gaming state". When the gaming state is a "time-saving gaming state", the time-saving flag is "1", and when it is a "non-time-saving gaming state", the time-saving flag is "0". In addition, in the time saving game state, the number of time saving times is also managed by the main CPU 101, and each time the special symbol changes once, the number of time saving times is subtracted by 1.

In addition, in the time-saving gaming state where the time-saving flag is set to ON, the probability of being determined as a normal win in the normal winning determination (normal winning probability) is increased compared to the non-time-saving gaming state. Therefore, in the time-saving game state, compared to the non-time-saving game state, the frequency at which the normal electric accessory 46 changes from the closed state to the open state, that is, the frequency at which the game ball enters the second starting port 440 is increased. However, in the time-saving gaming state, instead of increasing the normal winning probability compared to the non-time-saving gaming state, for example, by increasing the execution frequency of the normal winning lottery (shortening the fluctuation time of the normal symbols), The frequency with which the object 46 changes from the closed state to the open state may be increased, or the opening mode of the normal electric accessory 46 may be changed to make it easier to win a prize with the normal electric accessory 46. Furthermore, two or three of the above three aspects may be combined.

In the pachinko gaming machine 1 of the present embodiment, there is a normal gaming state in which both the variable probability flag and the time saving flag are OFF, a variable time saving game state in which the variable probability flag is ON and the time saving flag is ON, and a time saving game state in which the variable probability flag is OFF and the time saving flag is ON. It is configured to be controlled by the main CPU 101 into one of the gaming states.

When the main CPU 101 detects the winning of a game ball into the first starting hole 420 (for example, see FIG. 5) and extracts the random number for jackpot determination of the first special symbol, the main CPU 101 extracts the random number for jackpot determination of the extracted first special symbol. The numerical value is held as a starting memory until the variable display of the first special symbol is started. Then, when starting the variable display of the first special symbol, a jackpot determination of the first special symbol is performed to determine whether it is a jackpot or a loss.

When the main CPU 101 detects the winning of a game ball into the second starting port 440 (for example, see FIG. 5) and extracts the random number for jackpot determination of the second special symbol, the main CPU 101 extracts the random number for jackpot determination of the extracted second special symbol. The numerical value is held as a starting memory until the variable display of the second special symbol is started. Then, when starting the variable display of the second special symbol, a jackpot determination of the second special symbol is performed to determine whether it is a jackpot or a loss.

[3-1. Jackpot probability]
As shown in FIG. 21, in the jackpot determination of the first special symbol, the jackpot probability differs depending on the set value. When the jackpot probability is relatively low (probability variable flag OFF), the jackpot probability for each setting value is approximately 1/300 for setting 1, approximately 1/290 for setting 2, and approximately 1/290 for setting 3. Setting 4 is about 1/270, setting 5 is about 1/260, and setting 6 is about 1/250. In addition, when the jackpot probability is relatively high (probability change flag ON), the jackpot probability for each setting value is approximately 1/30 for setting 1, approximately 1/29 for setting 2, and approximately 1/29 for setting 3. setting is approximately 1/28, setting 4 is approximately 1/27, setting 5 is approximately 1/26, and setting 6 is approximately 1/25.

That is, as mentioned above, in this embodiment, the range (width) of random numbers for jackpot determination is set as a fixed value in the range of 0 to 65535, so the number of jackpot determination value data of the first special symbol is set to the set value. By changing it accordingly, the jackpot probability is varied depending on the set value. For example, in the low probability game state with the first special symbol, the number of jackpot judgment value data is set to 218 pieces in setting 1 and 226 pieces in setting 2 for the fixed value range of jackpot judgment random numbers (0 to 65535). By setting 234 pieces for setting 3, 243 pieces for setting 4, 252 pieces for setting 5, and 262 pieces for setting 6, the jackpot probability is varied depending on the setting value. In addition, the number of jackpot judgment value data in the high probability gaming state is 21 pieces in setting 1, 22 pieces in setting 2, 23 pieces in setting 3, 24 pieces in setting 4, 25 pieces in setting 5, and 26 pieces in setting 6. It becomes.

Also, in the jackpot determination of the second special symbol, the jackpot probability differs depending on the set value. When the jackpot probability is relatively low (probability variable flag OFF), the jackpot probability for each setting value is 1/300 for setting 1, 1/290 for setting 2, and 1/280 for setting 3. 1. Setting 4 is 1/270, setting 5 is 1/260, and setting 6 is 1/250. In addition, when the jackpot probability is relatively high (probability change flag ON), the jackpot probability for each setting value is 1/30 for setting 1, 1/29 for setting 2, and 28 for setting 3. Setting 4 is 1/27, setting 5 is 1/26, and setting 6 is 1/25.

That is, regarding the jackpot probability of the second special symbol, the jackpot probability is varied depending on the setting value by changing the number of jackpot judgment value data according to the setting value. For example, in the low probability game state with the second special symbol, the number of jackpot judgment value data is set to 218 pieces in setting 1 and 226 pieces in setting 2 for the fixed value range of jackpot judgment random numbers (0 to 65535). By setting 234 pieces for setting 3, 243 pieces for setting 4, 252 pieces for setting 5, and 262 pieces for setting 6, the jackpot probability is varied depending on the setting value. Also, regarding the number of jackpot judgment value data in the high probability gaming state, 21 pieces for setting 1, 22 pieces for setting 2, 23 pieces for setting 3, 24 pieces for setting 4, 25 pieces for setting 5, and 26 pieces for setting 6. It is individual.

Note that the jackpot probability determined according to the settings is the same for the jackpot determination of the first special symbol and the jackpot determination of the second special symbol. That is, if the set values are the same, the jackpot probability in the jackpot determination of the first special symbol and the jackpot probability in the jackpot determination of the second special symbol are the same. For example, in setting 3, the jackpot probability in jackpot determination for the first special symbol is 1/280 in the low probability gaming state (1/28 in the high probability gaming state), and this jackpot probability is This is the same as the jackpot probability in jackpot determination (1/280 in low probability gaming state, 1/28 in high probability gaming state).

In this embodiment, the setting values are set in six stages from setting 1 to setting 6, but they do not necessarily have to be six stages, and can be set arbitrarily as long as they are in multiple stages.

Further, in this embodiment, the jackpot probability is configured to be different depending on the set value, but the present invention is not limited to this, and a common jackpot probability may be set for a plurality of set values. For example, setting 1 and setting 2 have a common jackpot probability (first probability), setting 3 and setting 4 have a common jackpot probability (second probability higher than the first probability), and setting 5 and setting 4 have a common jackpot probability (second probability higher than the first probability). Setting 6 may have a common jackpot probability (a third probability higher than the second probability).

In addition, in this embodiment, the range (width) of random numbers for jackpot determination generated by the main CPU 101 is set as a fixed value in the range of 0 to 65535, and the range of random numbers for jackpot determination that is a fixed value is set as a fixed value. By changing the number of jackpot judgment value data according to the setting value, the jackpot probability is made different for each setting value, but the method of varying the jackpot probability for each setting value is not limited to this, and the jackpot judgment value By making the number of data common to all settings and changing the range (width) of random numbers for jackpot determination as the total random number according to the setting value, the jackpot probability may be varied depending on the setting value. For example, the number of jackpot judgment value data is set to 218, which is common to all settings, and the range (width) of random numbers for jackpot judgment is in the range of 0 to 65535 (jackpot probability is about 1/300) in setting 1, and in setting 2. Range of 0 to 63219 (probability of jackpot is 1/290), range of 0 to 61039 with setting 3 (probability of jackpot is 1/280), range of 0 to 58859 with setting 4 (probability of jackpot is 1/270) , setting 5 is a range of 0 to 56679 (jackpot probability is 1/260), setting 6 is a range of 0 to 54499 (jackpot probability is 1/250), and the main CPU 101 determines a jackpot within the range according to the set value. By generating random numbers, the jackpot probability can be changed depending on the set value. Moreover, according to this method, the jackpot probability is changed by changing the denominator (range of random numbers for jackpot judgment), which has more digits than the numerator (number of jackpot judgment value data). Compared to a method in which the range is set to a fixed value and the number of jackpot judgment value data is changed according to the set value, it becomes possible to set the jackpot probability for each set value in detail.

In addition, in the above, the number of jackpot judgment value data is common to all settings, and the range (width) of random numbers for jackpot judgment as a total random number is changed according to the setting value, but the number of jackpot judgment value data is the same for all settings. It is not necessarily necessary to make them common. For example, in setting 1, the number of jackpot judgment value data is 218, the range (width) of random numbers for jackpot judgment is in the range of 0 to 65535 (jackpot probability is about 1/300), and in setting 2, jackpot judgment value data The number of jackpot judgment value data is 219, and the range (width) of random numbers for jackpot judgment is 0 to 63509 (the probability of jackpot is about 1/290). The range (width) is from 0 to 61,599 (the jackpot probability is approximately 1/280), and in setting 4, the number of jackpot judgment value data is 221 pieces, and the range (width) of random numbers for jackpot judgment is from 0 to 59,669. (Jackpot probability is about 1/270), and in setting 5, the number of jackpot judgment value data is 222, and the range (width) of random numbers for jackpot judgment is in the range 0 to 57719 (Jackpot probability is about 1/260). In setting 6, the number of jackpot judgment value data and Even if both the range (width) of random numbers for jackpot judgment are changed according to the set value, the range of random numbers for jackpot judgment is fixed and the number of jackpot judgment value data is changed according to the set value. In comparison, it becomes possible to finely set the jackpot probability for each set value.

In addition, when the range (width) of the random numbers for jackpot determination as the above-mentioned total random numbers is changed according to the setting value, the main CPU 101 will In addition to or in place of determining whether the set value data is within the range of "0" to "5", for example, the range (width) of random numbers for jackpot determination as a total random number is determined as the set value. It may be checked whether the number of jackpot determination value data is within the corresponding range and/or whether the number of jackpot determination value data is the number specified in the set value. Then, if it is determined that the check is not normal (for example, the range (width) of random numbers for jackpot judgment as total random numbers and/or the number of jackpot judgment value data is outside the range according to the set value) (steps described below (corresponding to NO in S721), the main CPU 101 turns off the game permission flag (step S722, which will be described later), making it impossible to proceed with the game.

[3-2. Jackpot distribution]
Next, with reference to FIG. 22, a description will be given of the jackpot distribution when the result of the jackpot determination of the special symbol is a jackpot, that is, the selection rate of the stop symbol (main symbol) of the special symbol. In the example shown in FIG. 22, the distribution of the main symbols is common to all settings. Note that the contents of the table shown in FIG. 22 are stored in the main ROM 102.

As shown in FIG. 22, when the result of the jackpot determination for the first special symbol is a jackpot, the main CPU 101 selects the main symbol from special symbol 1-1 (distribution probability 25.0%), special drawing 1-2 (sorting probability 25.0%), special drawing 1-3 (sorting probability 25.0%), and special drawing 1-4 (sorting probability 25.0%) ). Special figure 1-1 is a jackpot with 4 rounds, probability variable flag OFF, and 100 time-savings. In special figure 1-2, the number of rounds is 4, the probability change flag is ON, and the time saving continues until the next jackpot gaming state is executed (the time saving flag is set to OFF when the next jackpot gaming state starts). It's a jackpot. Special figure 1-3 is a jackpot with 10 rounds, probability variable flag OFF, and 100 time-savings. Special figure 1-4 is a jackpot where the number of rounds is 10, the probability change flag is ON, and the time saving continues until the next jackpot game state is executed. When the result of the jackpot determination for the first special symbol is a jackpot, the main CPU 101 variably displays the first special symbol for a variable time determined with reference to FIG. 23, which will be described later, and then displays the determined main symbol Execute the control to stop it.

In addition, in this embodiment, when the result of the jackpot determination of the special symbol is a jackpot, if a predetermined condition is met (in this embodiment, the probability variable flag is turned ON like special symbol 1-2 and special symbol 1-4). After the jackpot gaming state ends, the high probability gaming state continues until the next jackpot gaming state starts. In such variable rate loop machines, when the result of jackpot determination of the special symbol in the high probability gaming state is a jackpot and a predetermined condition is met, the next jackpot gaming state starts again after the jackpot gaming state ends. The high probability gaming state continues until the game is played. Then, if the result of the jackpot determination of the special symbol in the high probability gaming state is a jackpot, and a predetermined condition is not met (in this embodiment, the probability variable flag is If it is a jackpot that does not turn ON), after the jackpot gaming state ends, it is not controlled to a high probability gaming state but to a low probability gaming state.

When the result of the jackpot determination for the second special symbol is a jackpot, the main CPU 101 selects either the special symbol 2-1 (allocation probability 50.0%) or the special symbol based on the extracted random number for determining the symbol. 2-2 (allocation probability 50.0%) is decided. Special figure 2-1 is a jackpot with 10 rounds, probability variable flag OFF, and 100 time-savings. Special figure 2-2 is a jackpot in which the number of rounds is 10, the probability change flag is ON, and the time saving continues until the next jackpot game state is executed. When the result of the jackpot determination of the second special symbol is a jackpot, the main CPU 101 variably displays the second special symbol for a variable time determined with reference to FIG. 23, which will be described later, and then displays the determined main symbol. Execute the control to stop it.

Note that when the result of the jackpot determination of the special symbol is a loss, the main CPU 101 determines the loss symbol and executes control to stop the special symbol at the determined loss symbol.

Further, the number of rounds is the number of rounds of the round game executed in the jackpot game state. In addition, if the variable probability flag is ON, the gaming state after the jackpot gaming state is controlled to be a high probability gaming state (a gaming state in which the variable probability flag is set to ON), and if the variable probability flag is OFF, the gaming state is controlled to be a jackpot gaming state. After the completion of the game, the gaming state is controlled to be a low probability gaming state (a gaming state in which the probability change flag is set to OFF). In the following, the number of rounds is 4, the probability variable flag is OFF, and the jackpot with the time saving number of 100 times (for example, the jackpot of special drawing 1-1) is referred to as "4R normal jackpot", and the number of rounds is 4, the probability variable flag is ON, and the next jackpot game is A jackpot that continues to save time until it is executed (for example, the jackpot of special figure 1-2) is called a "4R fixed variable jackpot", and a jackpot with 10 rounds, the fixed variable flag OFF, and 100 times of time saving (for example, the special figure 1-2 jackpot) 3. Special figure 2-1 jackpot) is called "10R normal jackpot", and the number of rounds is 10, the probability change flag is ON, and the time saving continues until the next jackpot game is executed (for example, special figure 1-4, The special figure 2-2 jackpot) is called the "10R surefire jackpot".

In addition, in this embodiment, when the result of jackpot determination is a jackpot, the time saving flag is always set to ON, but this is not necessarily the case. Depending on the main symbol displayed, it may be determined whether the time saving flag is set to ON or OFF.

[3-3. Special symbol variation time]
Next, with reference to FIG. 23, the flow until the special symbol variation time is determined will be explained. Since the special symbol variation time corresponds to the special symbol variation pattern, the main CPU 101 determines the special symbol variation time and the special symbol variation pattern at the same time. Further, the variation pattern of the special symbol also corresponds to the performance content (for example, the variation pattern of the decorative symbol) displayed on the display device 16 (see, for example, FIG. 5) by the sub-control circuit 200 (host control circuit 2100). The pachinko game machine 1 of this embodiment is configured so that the variation pattern of the special symbols to be determined (that is, the variation time and performance content) can vary depending on the set value. Note that the contents of the table shown in FIG. 23 are stored in the main ROM 102. In addition, the execution probability of the reach effect is changed depending on the number of reserved special symbols, and the variation time in the normal variation becomes shorter as the number of reserved special symbols increases, but these are omitted in Figure 23. .

As shown in FIG. 23, the main CPU 101 determines the fluctuation time of the first special symbol based on the result of the jackpot determination of the first special symbol, and determines the fluctuation time of the second special symbol based on the result of the jackpot determination of the second special symbol. Determine the variation time of the symbol.

As shown in FIG. 23, in this embodiment, the variation time of the special symbol is determined using a common table for the first special symbol and the second special symbol. However, instead of this, the variation time of the special symbol may be determined using different tables for the first special symbol and the second special symbol.

In addition, the special symbol fluctuation time determination table includes the result of the special symbol jackpot determination, the gaming state, the random number range for reach determination, the main symbol when the special symbol jackpot determination result is a jackpot, and the performance selection. The relationship among the random number range, variation pattern (variable display pattern), variation pattern designation command, variation time, and presentation content is defined. However, in determining the variation time of the special symbol, the variable time saving gaming state and the time saving gaming state are not distinguished. In addition, different random number ranges are set according to setting values for the random number range for reach determination and the random number range for production selection when determining the variation time of the special symbol.

The random number range for reach determination is a random number that is used to determine whether or not to execute the reach effect for each set value when the result of the jackpot determination of the special symbol is a loss. When a game ball enters the first starting port 420 or the second starting port 440 (for example, see FIG. 5), the main CPU 101 extracts a random number for reach determination from the reach determination counter, and executes the extracted reach determination. random numbers are stored in the main RAM 103. As described above, the main CPU 101 performs a jackpot judgment using the random number for jackpot judgment when starting the variable display of special symbols, but when the result of this jackpot judgment is a loss, the It is determined whether or not to execute the reach effect using the random number for reach determination. In this embodiment, the random number value for reach determination extracted from the reach determination counter is set in the range of 0 to 249, but this range can be changed as appropriate.

For example, if the result of the jackpot determination of the special symbol in the normal gaming state (the probability change flag is OFF and the time saving flag is OFF) is a loss, the random number range for reach determination in which it is determined to execute the reach effect is 0 in settings 1 and 2. -25, settings 3 and 4 are defined as 0 to 26, and settings 5 and 6 are defined as 0 to 27. In addition, if the result of the jackpot determination of the special symbol in the probability variable time-saving gaming state (the probability variable flag is ON and the time-saving flag is ON) is a loss, the random number range for reach determination in which it is determined to execute the reach effect is set to 1. In settings 3 and 4, it is specified as 0 to 11, and in settings 5 and 6, it is specified as 0 to 12.

In this way, when the result of the jackpot determination of the special symbol in the pachinko game machine 1 of this embodiment is a loss, the reach effect is more likely to be executed in settings 3 and 4 than in settings 1 and 2, and furthermore, in setting 3 - Settings 5 and 6 are easier to execute than 4. That is, the execution frequency of the ready-to-win effect differs depending on the setting value, and the higher the setting value, the higher the execution frequency of the ready-to-reach effect.

In addition, in this embodiment, when determining whether or not to perform a reach effect, the random number range for reach determination is common for setting 1 and setting 2, common for setting 3 and setting 4, and common for setting 5 and setting. 6, but is not limited to this, and may be different for all settings.

In addition, the above-mentioned decision on whether or not to execute the reach effect is explained in the case where the result of the jackpot determination of the special symbol is a loss, but if the result of the jackpot determination of the special symbol is a jackpot, the main CPU 101 determines to execute the reach effect regardless of the value of the reach determination random number extracted from the reach determination counter.

The random number range for performance selection is a random number used for determining the variation time of the special symbol for each set value. When a game ball enters the first starting port 420 or the second starting port 440 (for example, see FIG. 5), the main CPU 101 extracts a random number for performance selection from the performance selection counter, and selects the extracted performance selection. random numbers are stored in the main RAM 103. The main CPU 101 selects a random number for effect selection stored in the main RAM 103 according to the gaming state and the result of determining whether or not to execute the reach effect (only when the result of jackpot determination of the special symbol is a loss). Determine the fluctuation time of the special symbol using . In this embodiment, the random number value for effect selection extracted from the effect selection counter is set in the range of 0 to 99, but this range can be changed as appropriate. In addition, when the result of the jackpot determination of the special symbol is a jackpot, the main CPU 101 determines the variation time of the special symbol using the random number for performance selection stored in the main RAM 103 according to the game state.

Specifically, when the result of the jackpot determination of the special symbol in the normal gaming state (the probability change flag is OFF and the time saving flag is OFF) is a loss and it is decided to execute the reach effect, the variation time of the special symbol is as follows. It is determined as follows. In other words, the random number range for effect selection in which the variation time of the special symbol is determined to be 20,000 msec (normal reach) is defined as 0 to 57 in settings 1 and 2, and 0 to 58 in settings 3 and 4. In settings 5 and 6, it is specified as 0 to 59. In addition, the random number range for effect selection in which the variation time of the special symbol is determined to be 30,000 msec (normal medium super reach A) is defined as 58 to 89 in settings 1 and 2, and 59 to 89 in settings 3 and 4. For settings 5 and 6, it is specified as 60 to 89. Further, the random number range for performance selection in which the special symbol variation time is determined to be 40,000 msec (normal medium super reach B) is defined as 90 to 99 for settings 1 to 6.

In addition, when the result of the jackpot judgment of the special symbol in the normal gaming state (the probability change flag is OFF and the time saving flag is OFF) is a loss and it is decided not to execute the reach effect, the variation time of the special symbol is as follows. determined. That is, the random number range for effect selection in which the variation time of the special symbol is determined to be 10,000 msec (normal variation A) is defined as 0 to 51 in settings 1 and 2, and 0 to 50 in settings 3 and 4. In settings 5 and 6, it is specified as 0 to 49. In addition, the random number range for effect selection in which the variation time of the special symbol is determined to be 5000 msec (normal variation B) is defined as 52 to 99 in settings 1 and 2, and 51 to 99 in settings 3 and 4. In settings 5 and 6, it is specified as 50 to 99.

In addition, if the result of the jackpot determination of the special symbol in the probability variable time-saving gaming state (probability variable flag ON and time-saving flag ON) or the normal time-saving gaming state (probability variable flag OFF and time-saving flag ON) is a loss, and the reach effect is executed. When the special symbol is determined, the variation time of the special symbol is determined as follows. In other words, the random number range for effect selection in which the variation time of the special symbol is determined to be 25,000 msec (time saving medium normal reach) is defined as 0 to 57 in settings 1 and 2, and 0 to 58 in settings 3 and 4. In settings 5 and 6, it is specified as 0 to 59. In addition, the random number range for effect selection in which the variation time of the special symbol is determined to be 35,000 msec (time saving medium super reach A) is defined as 58 to 89 in settings 1 and 2, and 59 to 89 in settings 3 and 4. For settings 5 and 6, it is specified as 60 to 89. Further, the random number range for effect selection in which the special symbol variation time is determined to be 45,000 msec (time saving medium super reach B) is defined as 90 to 99 for settings 1 to 6.

In addition, the result of the jackpot determination of the special symbol in the probability variable time-saving gaming state (probability variable flag ON and time-saving flag ON) and the normal time-saving gaming state (probability variable flag OFF and time-saving flag ON) is a loss and the reach effect is not executed. When the special symbol is determined, the variation time of the special symbol is determined as follows. That is, the random number range for effect selection in which the special symbol variation time is determined to be 4000 msec (shortened variation A) is defined as 0 to 51 in settings 1 and 2, and 0 to 50 in settings 3 and 4. In settings 5 and 6, it is defined as 0 to 49. In addition, the random number range for effect selection in which the variation time of the special symbol is determined to be 2000 msec (shortened variation B) is defined as 52 to 99 in settings 1 and 2, and 51 to 99 in settings 3 and 4. In settings 5 and 6, it is specified as 50 to 99.

In addition, the main symbol is determined when the result of the jackpot determination of the special symbol is a jackpot, so if the result of the jackpot determination of the special symbol is a loss, the fluctuation time of the special symbol is determined. not involved.

The fluctuation time of the special symbol when the result of the jackpot determination of the special symbol in the normal game state (probability change flag OFF and time saving flag OFF) is a jackpot is common to all main symbols and is determined as follows. In other words, the random number range for effect selection in which the variation time of the special symbol is determined to be 20,000 msec (normal reach) is defined as 0 to 1 in settings 1 and 2, and 0 to 2 in settings 3 and 4. Settings 5 and 6 are defined as 0 to 3. In addition, the random number range for effect selection in which the variation time of the special symbol is determined to be 30,000 msec (normal medium super reach A) is defined as 2 to 49 in settings 1 and 2, and 3 to 49 in settings 3 and 4. For settings 5 and 6, it is specified as 4 to 49. Further, the random number range for performance selection in which the special symbol variation time is determined to be 40,000 msec (normal medium super reach B) is defined as 90 to 99 for settings 1 to 6.

In addition, the variation time of the special symbol when the result of jackpot determination of the special symbol in the probability variable time-saving gaming state (probability variable flag ON and time-saving flag ON) or normal time-saving gaming state (probability variable flag OFF and time-saving flag ON) is a jackpot, This is common to all main symbols and is determined as follows. In other words, the random number range for effect selection in which the variation time of the special symbol is determined to be 25,000 msec (time saving medium normal reach) is defined as 0 to 1 in settings 1 and 2, and 0 to 2 in settings 3 and 4. Settings 5 and 6 are defined as 0 to 3. In addition, the random number range for effect selection in which the variation time of the special symbol is determined to be 35,000 msec (time saving medium super reach A) is defined as 2 to 49 in settings 1 and 2, and 3 to 49 in settings 3 and 4. For settings 5 and 6, it is specified as 4 to 49. Further, the random number range for performance selection in which the special symbol variation time is determined to be 45,000 msec (time saving medium super reach B) is defined as 50 to 99 for settings 1 to 6.

In this way, in the pachinko gaming machine 1 of the present embodiment, as long as the gaming state, the result of the jackpot determination of the special symbol, and the result of the determination of whether or not to execute the reach effect are the same, the variation of the special symbol The time is more likely to be determined to be a short variable time for settings 3 and 4 than for settings 1 and 2, and furthermore, it is easier to be determined to be a shorter variable time for settings 5 and 6 than for settings 3 and 4. Therefore, the higher the setting value is, the shorter the average period of variation of the special symbol becomes, and the greater the number of variations of the special symbol (namely, the number of lottery draws) per unit time. As a result, the expectation level is high that the number of executions of the jackpot gaming state will increase when viewed per unit time, and the probability that the jackpot gaming state will be executed within the unit time also increases. It becomes possible to play an advantageous game.

In addition, in this embodiment, when determining the variation time of the special symbol, the random number range for effect selection is the same for settings 1 and 2, the same for settings 3 and 4, and the same for settings 5 and 6. Although these values are common, the present invention is not limited to this, and all setting values may be different.

In addition, the fluctuation time of the special symbol when the result of the jackpot determination of the special symbol is a jackpot is determined in common for all main symbols, but is not limited to this, and the variation time of the special symbol is determined according to the main symbol. It may be configured such that the fluctuation times of the values are different.

The fluctuation pattern is data representing the fluctuation time and the content of the performance. For example, the fluctuation pattern "02H" represents a normal medium super reach B with a fluctuation time of 40000 msec.

The fluctuation pattern designation command is transmitted from the main control circuit 100 to the sub-control circuit 200 as data representing the fluctuation time and the content of the performance. For example, if the variation pattern determined by the main CPU 101 is "05H", a variation pattern designation command of "83H05H" is transmitted from the main control circuit 100 to the sub control circuit 200. At this time, a symbol designation command for specifying the main symbol determined by the main control circuit 100 (main CPU 101) is also transmitted to the sub-control circuit 200.

[3-4. Decorative pattern stop pattern]
Next, with reference to FIG. 24, an example of the stop symbol of the decorative symbol will be described when the main symbol is determined with the selection rate shown in FIG. 22 when the result of the jackpot determination of the special symbol is a jackpot. . Note that the contents of the table shown in FIG. 24 are stored in the sub-main ROM 2050 of the sub-control circuit 200.

Upon receiving the symbol designation command sent from the main control circuit 100, the sub control circuit 200 (host control circuit 2100) stops the decorative design based on the main symbol specified by the symbol designation command, regardless of the setting value. Decide on the design. For example, when the main symbol specified by the symbol designation command sent from the main control circuit 100 is special symbol 1-2, the host control circuit 2100 controls the host control circuit 2100 so that all the decorative symbols are the same specific symbol (for example, the "7" symbol). ), the distribution probability is 0%, so all decorative patterns (three decorative patterns in this embodiment) are the same even number pattern (30.0% distribution probability), or all It is determined that the decorative symbols are the same odd numbered symbols (allocation probability 70.0%). In this embodiment, the specific symbol is the "7" symbol, but it is not limited to this, and if the player can recognize that it is a jackpot with a high degree of profit, other symbols (for example, the "V" symbol) may be used as the specific symbol. Also good.

As described above, the main symbol shown in FIG. 24 is determined when the result of the jackpot determination of the special symbol is a jackpot. Therefore, the host control circuit 2100 determines the stop symbol of the decorative symbol with reference to FIG. 24 when the result of the jackpot determination of the special symbol is a jackpot, and when the result of the jackpot determination of the special symbol is a loss, A pattern other than the pattern shown in FIG. 24 is determined as a stop pattern of the decorative patterns. The symbols other than those shown in FIG. 24 correspond to, for example, a symbol in which at least one of all the decorative symbols is different from the other decorative symbols.

In this way, according to FIG. 24, when the result of the jackpot determination of the special symbol is a jackpot, the state when all the decorative symbols have stopped is the jackpot determination of either the first special symbol or the second special symbol. , whether the gaming state after the jackpot gaming state ends is a jackpot controlled to a high probability gaming state, and whether the number of rounds of the round game executed in the jackpot gaming state is 10R. It can vary depending on whether

In other words, when the main symbol determined with reference to FIG. 22 is Special Figure 1-1, Special Figure 1-3, or Special Figure 2-1 (4R normal jackpot or 10R normal jackpot where the probability change flag is not set to ON), Regardless of the setting value, it always stops in a mode in which all the decorative patterns are the same even-numbered pattern (hereinafter referred to as the "first mode").

Also, when the main pattern is special pattern 1-2 (4R guaranteed strange jackpot), regardless of the setting value, the first mode or all the decorative patterns are the same odd-numbered pattern (other than the "7" pattern which is a specific pattern) (hereinafter referred to as the "second mode").

Also, when the main symbol is special pattern 1-4 (10R guaranteed strange jackpot), all decorative symbols are the same odd-numbered symbol, or all decorative symbols are the same specific symbol, regardless of the setting value. (hereinafter referred to as "specific mode").

Furthermore, when the main symbol is special figure 2-2 (10R probability variable jackpot), it stops in a specific manner regardless of the set value. Special figure 1-4 and special figure 2-2 are both 10R guaranteed variable jackpots, but since special figure 1-4 is a jackpot based on the winning of the game ball into the first starting hole 420, it is a jackpot in normal gaming conditions. It is highly likely that he was elected. In addition, since the special figure 2-2 is a jackpot based on the winning of a game ball into the second starting hole 440, there is a high possibility that the jackpot was won in a high probability game state or a time-saving game state.

In this way, if it stops in a specific manner, a 10R probability variable jackpot with the highest degree of profit for the player is determined, and if it stops in a manner in which all decorative symbols are the same odd-numbered symbol, a probability variation jackpot (4R probability variation jackpot or 10R probability variation jackpot) is determined. (Probable jackpot) is confirmed. On the other hand, when the game stops in the first mode, although it is determined that it is not the 10R probability variable jackpot that provides the highest degree of profit for the player, the possibility of a 4R probability variation jackpot remains.

In addition, when the result of the jackpot determination of the special symbol is a jackpot, the player may be informed as to which jackpot the jackpot is when all the decorative symbols have stopped, or the jackpot game The notification may be made while the state is being executed, or may be made when the jackpot gaming state ends. In addition, although this is not adopted in the pachinko gaming machine 1 of the present embodiment, even though the gaming state after the jackpot gaming state is a jackpot that is controlled to be a high probability gaming state, the high probability gaming state It may also be possible to control the game to a so-called "latent probability change state" in which it is not made clear to the player that the game will be controlled.

[4. Other examples of basic specifications of pachinko gaming machines]

Although the basic specifications of the pachinko gaming machine 1 in this embodiment are as described above, they are not limited to the above specifications and can be changed as appropriate. An example in which the basic specifications are changed as appropriate will be described below. However, it goes without saying that the following explanation is just an example, and is not limited thereto.
[4-1. Variation example of special symbol fluctuation time]
Next, with reference to FIG. 25, a modification of the special symbol variation time (that is, the special symbol variation pattern) will be described. FIG. 25 is a diagram showing another example of the special symbol variation time determination table stored in the main ROM 102. As mentioned above, there are cases in which the execution probability of the reach effect is changed depending on the number of reserved special symbols, and the fluctuation time in the normal fluctuation becomes shorter as the number of reserved special symbols increases, but these are also shown in FIG. 25. is omitted.

Further, the main CPU of the pachinko gaming machine according to the variation of the special symbol variation special symbol described with reference to FIG. Counting means (not shown) are provided. This lottery number counting means is reset, for example, at the start of the jackpot game state, and starts counting the number of changes in the special symbol starting from the end of the jackpot game state.

As shown in FIG. 25, in another example, if the result of the jackpot determination of the special symbol in the normal gaming state (the probability change flag is OFF and the time saving flag is OFF) is a loss, the decision as to whether or not to execute the reach effect is as follows: This is done in accordance with both the number of changes in the special symbol, which is counted starting from the point at which the jackpot game state ends, and the set value.

Specifically, if the number of fluctuations of the special symbol starting from a specific point in time (for example, the time when the jackpot game state ends) is 0 to 1000, it is determined that the reach effect is executed in the random number range for reach determination. is defined as 0 to 25 in settings 1 and 2, 0 to 26 in settings 3 and 4, and 0 to 27 in settings 5 and 6. These are the same as in FIG.

On the other hand, when the number of fluctuations of the special symbol starting from the end of the jackpot game state reaches 1001 times or more, the random number range for reach judgment is determined to execute the reach effect, and in settings 1 and 2, the random number range is 0 to 10. It is defined as 0 to 5 in settings 3 and 4, and 0 to 1 in settings 5 and 6. In other words, if the result of the jackpot judgment of the special symbol is a loss, the probability of executing the reach effect is twice as high in settings 1 and 2 compared to settings 3 and 4, and in settings 3 and 4 compared to settings 5 and 6. The probability of execution of a reach effect is 5 times higher (the probability of execution of a reach effect is 10 times higher in settings 1 and 2 than in settings 5 and 6).

In this way, if the number of changes in the special symbol starting from the point at which the jackpot gaming state ends is 1001 or more, if the number of changes in the special symbol starting from the point at which the jackpot gaming state ends is 0 to 1,000 times. Compared to this, the execution probability of reach effects differs markedly depending on the settings.

In addition, if the result of the jackpot determination of the special symbol in the normal gaming state (the probability change flag is OFF and the time saving flag is OFF) is a loss and it is decided to execute the reach effect, the fluctuation time of the special symbol will also be changed to the jackpot game. There is a noticeable difference in settings between when the number of variations of the special symbol starting from the point at which the state ends is 0 to 1000 times and when it is 1001 times or more.

Specifically, when the number of variations of the special symbol starting from the point when the jackpot game state ends is 0 to 1000, the random number range for performance selection is such that the variation time of the special symbol is determined to be 20,000 msec (normal reach during normal reach). is defined as 0 to 57 in settings 1 and 2, 0 to 58 in settings 3 and 4, and 0 to 59 in settings 5 and 6. In addition, the random number range for effect selection in which the variation time of the special symbol is determined to be 30,000 msec (normal medium super reach A) is defined as 58 to 89 in settings 1 and 2, and 59 to 89 in settings 3 and 4. For settings 5 and 6, it is specified as 60 to 89. Further, the random number range for performance selection in which the special symbol variation time is determined to be 40,000 msec (normal medium super reach B) is defined as 90 to 99 for settings 1 to 6. These are the same as in FIG.

On the other hand, when the number of variations of the special symbol starting from the end of the jackpot game state reaches 1001 times or more, the random number range for performance selection in which the variation time of the special symbol is determined to be 20,000 msec (normal reach during normal reach) is set to 1. -4 are not specified, and settings 5 and 6 are specified as 0-99. In addition, the random number range for effect selection in which the variation time of the special symbol is determined to be 30,000 msec (normal medium super reach A) is specified as 0 to 89 for settings 1 to 4, and is not specified for settings 5 and 6. . Furthermore, the random number range for effect selection in which the variation time of the special symbol is determined to be 40,000 msec (normal medium super reach B) is specified as 90 to 99 for settings 1 to 4, and is not specified for settings 5 and 6. do not have. Therefore, in a situation where the special symbol has changed more than 1001 times starting from the end of the jackpot game state, the set value is suggested to the player by the ready-to-reach effect that is executed. becomes possible.

In addition, if the result of the jackpot determination of the special symbol in the normal gaming state (the probability change flag is OFF and the time saving flag is OFF) is a loss and it is decided to execute the reach effect, the starting point is the point at which the jackpot gaming state ends. When the number of variations of the special symbol is 1001 times or more, the higher the setting value is, the lower the execution probability of the ready-to-reach effect is. Furthermore, even if a ready-to-win effect is executed, the higher the setting value is, the higher the probability of execution of the ready-to-reach effect is, where the variation time of the special symbol is short.

In this way, when the number of fluctuations of the special symbol starting from the end of the jackpot game state reaches 1001 times or more, the higher the setting value, the shorter the average time of fluctuation of the special symbol per time, and the unit The number of changes in special symbols per hour (ie, the number of drawings) becomes even greater. As a result, the expectation that the number of times a jackpot game will be executed in a unit time becomes even higher, and the probability that a jackpot game will be executed within a unit time becomes even higher.

In addition, if the number of changes in the special symbol starting from the end of the jackpot game state is less than 1000 times, it is extremely difficult to estimate the set value from the execution frequency of the reach effect, but the jackpot game state If the number of changes in the special symbol starting from the end of is 1001 or more, the execution frequency of the reach effect will differ markedly depending on the setting value, so when you get so-called a big hit, you can guess the set setting value. There may be room for this. As a result, when a so-called big hit occurs, the setting value set for the player can be changed without causing a direct loss to the hole (for example, without giving the game ball to the player). By providing opportunities for guessing, it is possible to give players fun. Moreover, although players would normally expect a reach effect, in this embodiment, the player expects that the setting value will be higher as the frequency of execution of the reach effect is lower when the player becomes addicted to the game. Since the player can hold the game, it is possible to reduce the decrease in the desire to continue playing the game even if the execution frequency of the reach effect is low.

In addition, in this embodiment, the starting point for counting the number of changes in the special symbol is the time when the jackpot game state ends, but it is not limited to this, and for example, a high probability game state may be started after a predetermined period has passed. The starting point can be any point in time, such as when a high-probability gaming state ends in a pachinko machine called an ST machine, or when a time-saving gaming state ends.

In addition, in this embodiment, when the number of fluctuations of the special symbol starting from a specific point in time becomes 1001 or more, the execution probability of the reach effect and the fluctuation time of the special symbol will differ significantly depending on the setting value, but it is not necessarily 1001. It doesn't have to be more than once. For example, the number of times is not limited to a specific number of times as long as the player feels addicted to it.

In addition, in this embodiment, when the number of fluctuations of the special symbol starting from a specific time exceeds the specified number of times, the execution probability of the reach effect and the fluctuation time of the special symbol will differ significantly depending on the set value, but the set value What differs markedly depending on is not necessarily limited to the execution probability of the reach effect or the variation time of the special symbol. For example, the main CPU 101 sets a predetermined waiting time (hereinafter referred to as "opening time") between when the result of the special symbol jackpot lottery is determined to be a jackpot and when the jackpot game state is actually controlled. ing. The main CPU 101 also provides a predetermined waiting time (hereinafter referred to as "ending time") between the end of the jackpot game state and the start of the variable display of special symbols. The host control circuit 2100 (display control circuit 2300) displays the opening effect on the display device 16 at the above-mentioned opening time, and displays the ending effect on the display device 16 at the above-mentioned ending time. In the opening performance, for example, a performance that shows that the result of the special lottery was a jackpot, a performance that congratulates the fact that the result of the special lottery was a jackpot, a performance that celebrates the fact that the result of the special lottery was a jackpot, and a game technique (such as right-handed hitting) in a jackpot game state. A teaching performance, etc. will be performed. In the ending performance, there is a performance that shows the amount of prize balls paid out in the jackpot game state, a performance that shows the number of times the jackpot game state has been continued (number of consecutive games), and a performance that shows the game state after the jackpot game state is a high probability game. A presentation that shows that the pachinko game machine 1 is controlled by the state, a presentation that teaches the gaming method (for example, returning to left-handed hitting) in the gaming state after the jackpot gaming state ends, and a presentation that displays the logo of the manufacturer of the pachinko gaming machine 1. etc. will be carried out.

Specifically, by decreasing all or at least one of the opening time, interval time, and ending time as the set value increases, the time required for the jackpot gaming state increases as the set value increases. Can be shortened. As a result, it becomes possible to increase the average number of changes in special symbols per unit time (namely, the number of drawings), and the higher the set value, the more advantageous the game can be executed for the player.

In addition, for example, in the pachinko game machine 1 where the higher the setting value is, the higher the expected ball payout value (for example, the higher the setting value is, the higher the jackpot probability), a larger amount of prize balls will be paid out in a shorter time compared to a lower setting value. Considering that there is a possibility that the opening time, the interval time, and the ending time, all or at least one of the opening time, the interval time, and the ending time may be configured to become longer as the setting value becomes higher. In this case, the higher the expected ball payout value, the longer all or at least one of the opening time, interval time, and ending time will be, ensuring the fun of the game with the higher setting value. At the same time, it becomes possible to suppress the prize balls paid out per unit time.

In addition, the main CPU 101 does not allow the game ball to enter the starting opening (first starting opening 420, second starting opening 440) even when the opening time, ending time and jackpot gaming state are controlled. When detected, various random numbers are extracted, and setting check processing (see FIG. 42) of step S74 and step S82, which will be described later, is executed. If it is determined in this setting check process that the setting value data is outside the range of "0" to "5" (NO in step S721, which will be described later), even if the control is in a jackpot gaming state, , the main CPU 101 turns off the game permission flag (step S722, which will be described later), making it impossible to proceed with the game.

[4-2. Variations of jackpot distribution and stop patterns of decorative patterns]
Next, with reference to FIGS. 26 to 28, the first and second modified examples of jackpot distribution (main symbol selection rate) when the result of jackpot determination of a special symbol is a jackpot, and these modified examples The stop symbols of the decorative symbols in the first modification and the second modification will be explained. In the first modification and the second modification, the selection rate of the main symbol is different depending on the set value. In addition, FIG. 26 is a diagram showing a first modification of the selection rate of the main symbol when the result of the jackpot determination of the special symbol is a jackpot, and FIG. 27 is a diagram showing a first modification example of the selection rate of the main symbol when the result of the jackpot determination of the special symbol is a jackpot. It is a figure which shows the 2nd modification regarding the selection rate of the main symbol. Moreover, FIG. 28 is a modification of the decorative symbol determination table stored in the sub-main ROM 2050 of the sub-control circuit 200, and is commonly used in the first modification and the second modification.

[4-2-1. 1st modification]
First, the first modification will be described with reference to FIGS. 26 and 28. Note that the contents of the table shown in FIG. 26 are stored in the main ROM 102, and the contents of the table shown in FIG. 28 are stored in the sub-main ROM 2050 of the sub-control circuit 200.

As shown in FIG. 26, in the first modification, when the result of the jackpot determination of the special symbol is a jackpot, the main CPU 101 changes the main symbol according to the set value based on the extracted random number for determining the symbol. The probability is that Tokuzu 1-1, Tokuzu 1-2, Tokuzu 1-3, Tokuzu 1-4, Tokuzu 1-5, Tokuzu 1-6, Tokuzu 1-7, and Tokuzu 1 Decide on one of -8. However, in this first modification, special map 1-1 and special map 1-3 are "4R normal jackpot", special map 1-2 and special map 1-4 are "4R definite strange jackpot", and special map 1 -5, Special Figure 1-7, Special Figure 2-1 and Special Figure 2-3 are "10R regular jackpot", Special Figure 1-6, Special Figure 1-8, Special Figure 2-2 and Special Figure 2- 4 is a "10R surefire jackpot".

Specifically, the main CPU 101 selects the main symbols as special symbols 1-1 (distribution probability 12.5%) and special symbol 1-2 (distribution probability 12.5%) with a common probability in settings 1 to 4. %), special map 1-3 (distribution probability 12.5%), special program 1-4 (distribution probability 12.5%), special program 1-5 (distribution probability 12.5%), special program 1-6 (sorting probability 12.5%), special drawing 1-7 (sorting probability 12.5%), and special drawing 1-8 (sorting probability 12.5%). decide. On the other hand, in setting 5, the main symbols are special figure 1-1 (distribution probability 10.0%), special figure 1-2 (distribution probability 10.0%), and special figure 1-3 (distribution probability 10.0%). (probability of distribution 15.0%), special figure 1-4 (probability of distribution 15.0%), special figure 1-5 (probability of distribution 10.0%), special figure 1-6 (probability of distribution 10.0%) %), special drawing 1-7 (allocation probability 15.0%), and special drawing 1-8 (allocation probability 15.0%). In addition, in setting 6, the main symbols are special figure 1-1 (distribution probability 5.0%), special figure 1-2 (distribution probability 5.0%), special figure 1-3 (distribution probability 20 .0%), special map 1-4 (distribution probability 20.0%), special diagram 1-5 (distribution probability 5.0%), special diagram 1-6 (distribution probability 5.0%), Decide on either special figure 1-7 (distribution probability 20.0%) or special figure 1-8 (distribution probability 20.0%).

In other words, for Tokuzu 1-2 and Tokuzu 1-4 (both 4R probability variable jackpot), which have the same jackpot type, the combined probability of both is 25.0% regardless of the setting, but the high setting value ( For example, with settings 5 and 6), the selection rate of special drawings 1-4 (15.0% with setting 5) is higher than the selection rate of special drawings 1-2 (10.0% with setting 5, 5.0% with setting 6). %, 20.0% at setting 6) is higher (common for settings 1 to 4).

Similarly, for Tokuzu 1-6 and Tokuzu 1-8 (both 10R probability variable jackpot), which have the same jackpot type, the combined probability of both is 25.0% regardless of the setting, but the high setting value (For example, with settings 5 and 6), the selection rate of special drawings 1-8 (15.0% with setting 5) is higher than the selection rate of special drawings 1-6 (10.0% with setting 5, 5.0% with setting 6). 0%, 20.0% at setting 6) is higher (common for settings 1 to 4).

Furthermore, for Tokuzu 2-2 and Tokuzu 2-4 (both 10R probability variable jackpot), which have the same jackpot type, the combined probability of both is 50.0% regardless of the setting, but the high setting value (For example, with settings 5 and 6), the selection rate of special map 2-4 (30.0% with setting 5) is higher than the selection rate of special map 2-2 (20.0% with setting 5, 10.0% with setting 6). 0%, setting 6: 40.0%) is higher.

By the way, when the result of the jackpot determination of the special symbol is a jackpot, the host control circuit 2100 controls the special symbols 1-1, 1-3, 1-5, and 1 as shown in FIG. -7, Special Figure 2-1, Special Figure 2-3 (4R normal jackpot or 10R normal jackpot where the probability variation flag is not set to ON), regardless of the setting value, the decoration displayed on the display device 16 is always displayed. The symbol is controlled to stop in the first mode.

On the other hand, when it is special drawing 1-2 (4R probability variable jackpot), the host control circuit 2100 selects the first mode (selection rate 50.0%) or the second mode (selection rate 50.0%) regardless of the setting value. control to stop at 0%). Furthermore, when the main symbol is special figure 1-4 (4R probability variable jackpot), the host control circuit 2100 selects the first mode (selection rate 25.0%) or the second mode (selection rate 25.0%) regardless of the setting value. control to stop at a rate of 75.0%). Here, at high setting values (for example, settings 5 and 6), the selection rate for special drawings 1-4 is higher than the selection rate for special drawings 1-2 (10.0% for setting 5, 5.0% for setting 6). (15.0% for setting 5 and 20.0% for setting 6) is higher. Therefore, even though the jackpot type of special drawings 1-2 and 1-4 is the same (both 4R probability variable jackpot), the high setting value is compared to the low setting value (for example, setting 1 to 4). Therefore, the probability that the decorative pattern stops in the second mode (a mode in which the player has a higher expectation level than the first mode) increases.

Similarly, when it is special drawing 1-6 (10R probability variable jackpot), the host control circuit 2100 always controls the game to stop in the second mode regardless of the set value. In addition, when the main symbol is special pattern 1-8 (10R probability variable jackpot), the host control circuit 2100 selects the second mode (selection rate 50.0%) or the specific mode (selection rate 50.0%). Here, as mentioned above, at high setting values (for example, settings 5 and 6), the selection rate of special drawings 1-6 is higher than that of special drawings 1-6 (10.0% for setting 5 and 5.0% for setting 6). The selection rate of 8 (15.0% for setting 5, 20.0% for setting 6) is higher. Therefore, even though the jackpot type of special drawings 1-6 and 1-8 is the same (both 10R probability variable jackpot), the high setting value is compared to the low setting value (for example, setting 1 to 4). Therefore, the probability that the decorative symbols will stop in a specific manner (the manner in which the player has the highest level of expectation) increases.

Furthermore, in the same way, when it is special drawing 2-2 (10R probability variable jackpot), the host control circuit 2100 controls the second mode (selection rate 50.0%) or the specific mode (selection rate 50.0%) regardless of the setting value. %). Further, when the main symbol is special symbol 2-4 (10R probability variable jackpot), the host control circuit 2100 always controls the game to stop in a specific manner regardless of the set value. Here, as mentioned above, at high setting values (for example, settings 5 and 6), the selection rate of special figure 2-2 is higher than the selection rate of special figure 2-2 (20.0% at setting 5, 10.0% at setting 6). The selection rate for setting 4 (30.0% for setting 5 and 40.0% for setting 6) is higher. Therefore, even though the jackpot type of special chart 2-2 and special chart 2-4 is the same (both 10R probability variable jackpot), the high setting value is compared to the low setting value (for example, settings 1 to 4). Therefore, the probability that the decorative pattern stops in a specific manner increases.

In this way, when the result of jackpot determination for a special symbol is a jackpot, it is possible to make it possible for the decorative symbol to stop in a different manner depending on the set value even if the jackpot type is the same. Become. Especially when the setting value is high (for example, setting 5 or 6), when the result of jackpot judgment of the special symbol is a jackpot, even if the composite probability determined for a specific jackpot type (for example, 10R probability variable jackpot) is the same. Also, it is possible to stop the decorative pattern in a mode (for example, a specific mode) that has a relatively high expectation level for the player with a high probability compared to when the setting value is low (for example, settings 1 to 4). Become.

[4-2-2. Second modification]
Next, the second modification will be described with reference to FIGS. 27 and 28. Note that the contents of the table shown in FIG. 27 are stored in the main ROM 102.

In the first modification, it is determined whether the probability change flag is set to ON or not, depending on the main symbol that is determined when the result of the jackpot determination of the special symbol is a jackpot. On the other hand, in the second modification, it is not immediately determined whether or not the probability variation flag is set to ON depending on the main symbol that is determined when the result of the jackpot determination of the special symbol is a jackpot. do not have. To explain in detail, in the second modification, unlike the first modification, a variable probability attacker (not shown) is provided inside the big prize opening 540 (for example, see FIG. 5). For example, when the jackpot game state is being controlled, if the entry of a game ball into the probability variable attacker is detected, the game state after the jackpot game state ends is controlled to a high probability game state, and the probability variation attacker is controlled. When the jackpot game state ends without the entry of a game ball being detected, the game state after the jackpot game state ends is controlled to a low probability game state. In this way, a pachinko game machine that is controlled to a high probability gaming state based on the entry of a game ball into a variable probability attacker is also a so-called "variable loop machine."

As shown in FIG. 27, in the second modification, the ease with which the game ball enters the probability-variable attacker differs depending on the main symbol that is determined when the result of the jackpot determination of the special symbol is a jackpot. ing. For example, in special figure 1-1, the game ball is controlled to enter the jackpot game state in a manner that makes it difficult for the game ball to enter the fixed-rate attacker, and in special figure 1-2, the jackpot game state is controlled in a manner that makes it easy for the game ball to enter the fixed-rate attacker. controlled by. In this embodiment, the number of time saving times when a jackpot is achieved in the "mode in which it is difficult for the game ball to enter the fixed-variable attacker" is 100, and the number of time-savings when the jackpot is achieved in the "mode in which it is easy for the game ball to enter the fixed-variable attacker" is 100. When it is a jackpot, the time saving continues until the next jackpot game is executed.

In this embodiment, the "mode in which it is difficult for the game ball to enter the probability-variable attacker" means that there is almost no possibility that the game ball will enter the probability-variable attacker while the jackpot game state is controlled (nearly 100%). This is a mode in which the game is controlled to a low-probability gaming state with a probability close to . In addition, "a mode in which it is easy for the game ball to enter the fixed-rate attacker" means that as long as the game ball is fired toward the placement site of the fixed-rate attacker (for example, the jackpot opening 540 (see FIG. 5, for example)), the jackpot game state will be achieved. This is a mode in which the game ball almost enters the probability-changing attacker while being controlled (it is controlled to a high-probability game state with a probability close to 100%). Therefore, in this second modified example, a jackpot in a manner in which it is difficult for the game ball to enter the fixed-variable attacker is referred to as a "normal jackpot," and a jackpot in a manner in which it is easy for the game ball to enter the fixed-variable attacker. A jackpot is called a "probable jackpot."

However, if it is "a mode in which it is easy for the game ball to enter the fixed-variable attacker", it will be controlled to a high probability gaming state with a probability close to 100%, and if it is "a mode in which it is difficult for the game ball to enter the fixed-variable attacker" Instead of being controlled to a low-probability game state with a probability close to 100%, when the game state is in a state where it is easy for the game ball to enter the fixed-variable attacker, It may be a mode in which the game is controlled to a high-probability gaming state with a relatively higher probability than the "mode".

As a method for creating modes in which it is difficult and easy for the game ball to enter the fixed-variable attacker, for example, in addition to the big prize opening 540 (for example, see FIG. 5) that includes the fixed-variable attacker inside, there is no fixed-variable attacker. It is conceivable to provide another big prize opening (not shown). Then, the mode in which the game ball can easily enter the fixed attacker (for example, special figure 1-2, special figure 1-4, special figure 1-6, special figure 1-8, special figure 2-2, special figure 2 -4), the jackpot game state is controlled in which the jackpot opening 540 is opened, and the state in which it is difficult for the game ball to enter the probability-changing attacker (for example, special drawing 1-1, special drawing 1-3, special drawing 1) is controlled. -5, Special Figure 1-7, Special Figure 2-1, Special Figure 2-3), by controlling to a jackpot game state in which other big winning openings are opened without opening the big winning opening 540, It is possible to create modes in which it is difficult for the game ball to enter the attacker and modes in which it is easy. It should be noted that the present invention is not limited to the above embodiments as long as it is possible to create a mode in which it is difficult for the game ball to enter the variable attacker and a mode in which it is easy to enter the game ball.

In addition, as described above, when the big winning hole 540 that is equipped with a fixed rate attacker inside and the other big winning hole (not shown) that is not equipped with a fixed variable attacker are provided, the big winning hole that is opened in the jackpot game state. The mouth may have different settings. For example, with a low setting value such as setting 1, a jackpot game state in which other big winning holes are opened is more likely to be selected than the big winning hole 540, and with a high setting value such as setting 6, the jackpot game state is more likely to be selected than the other big winning hole. The higher the set value is, the easier it is to select the jackpot game state in which the jackpot opening 540 is opened, such as the jackpot gaming state in which the jackpot opening 540 is opened is more likely to be selected.

As shown in FIG. 27, in such a second modification, when the result of the jackpot determination of the special symbol is a jackpot, the main CPU 101 changes the main symbol to the set value based on the extracted random number for determining the symbol. With a probability according to Decide on one of special drawings 1-8. However, in this second modification, special map 1-1 and special map 1-3 are "4R normal jackpot", special map 1-2 and special map 1-4 are "4R definite strange jackpot", and special map 1 -5, Special Figure 1-7, Special Figure 2-1 and Special Figure 2-3 are "10R regular jackpot", Special Figure 1-6, Special Figure 1-7, Special Figure 2-2 and Special Figure 2- 4 is a "10R surefire jackpot".

Specifically, the main CPU 101 selects the main symbols as special symbols 1-1 (distribution probability 12.5%) and special symbol 1-2 (distribution probability 12.5%) with a common probability in settings 1 to 4. %), special map 1-3 (distribution probability 12.5%), special program 1-4 (distribution probability 12.5%), special program 1-5 (distribution probability 12.5%), special program 1-6 (sorting probability 12.5%), special drawing 1-7 (sorting probability 12.5%), and special drawing 1-8 (sorting probability 12.5%). decide. On the other hand, in setting 5, the main symbols are special figure 1-1 (distribution probability 10.0%), special figure 1-2 (distribution probability 10.0%), and special figure 1-3 (distribution probability 10.0%). (probability of distribution 15.0%), special figure 1-4 (probability of distribution 15.0%), special figure 1-5 (probability of distribution 10.0%), special figure 1-6 (probability of distribution 10.0%) %), special drawing 1-7 (allocation probability 15.0%), and special drawing 1-8 (allocation probability 15.0%). In addition, in setting 6, the main symbols are special figure 1-1 (distribution probability 5.0%), special figure 1-2 (distribution probability 5.0%), special figure 1-3 (distribution probability 20 .0%), special map 1-4 (distribution probability 20.0%), special diagram 1-5 (distribution probability 5.0%), special diagram 1-6 (distribution probability 5.0%), Decide on either special figure 1-7 (distribution probability 20.0%) or special figure 1-8 (distribution probability 20.0%).

In other words, for Tokuzu 1-2 and Tokuzu 1-4 (both 4R probability variable jackpot), which have the same jackpot type, the combined probability of both is 25.0% regardless of the setting, but the high setting value ( For example, with settings 5 and 6), the selection rate of special drawings 1-4 (15.0% with setting 5) is higher than the selection rate of special drawings 1-2 (10.0% with setting 5, 5.0% with setting 6). %, 20.0% at setting 6) is higher (common for settings 1 to 4).

Similarly, for Tokuzu 1-6 and Tokuzu 1-8 (both 10R probability variable jackpot), which have the same jackpot type, the combined probability of both is 25.0% regardless of the setting, but the high setting value (For example, with settings 5 and 6), the selection rate of special drawings 1-8 (15.0% with setting 5) is higher than the selection rate of special drawings 1-6 (10.0% with setting 5, 5.0% with setting 6). 0%, 20.0% at setting 6) is higher (common for settings 1 to 4).

Furthermore, for Tokuzu 2-2 and Tokuzu 2-4 (both 10R probability variable jackpot), which have the same jackpot type, the combined probability of both is 50.0% regardless of the setting, but the high setting value (For example, with settings 5 and 6), the selection rate of special map 2-4 (30.0% with setting 5) is higher than the selection rate of special map 2-2 (20.0% with setting 5, 10.0% with setting 6). 0%, setting 6: 40.0%) is higher.

By the way, when the result of the jackpot determination of the special symbol is a jackpot, the host control circuit 2100 controls the special symbols 1-1, 1-3, 1-5, and 1 as shown in FIG. -7, Special Figure 2-1, Special Figure 2-3 (4R normal jackpot or 10R normal jackpot where the probability variation flag is not set to ON), regardless of the setting value, the decoration displayed on the display device 16 is always displayed. The symbol is controlled to stop in the first mode.

On the other hand, when it is special drawing 1-2 (4R probability variable jackpot), the host control circuit 2100 selects the first mode (selection rate 50.0%) or the second mode (selection rate 50.0%) regardless of the setting value. control to stop at 0%). Furthermore, when the main symbol is special figure 1-4 (4R probability variable jackpot), the host control circuit 2100 selects the first mode (selection rate 25.0%) or the second mode (selection rate 25.0%) regardless of the setting value. control to stop at a rate of 75.0%). Here, at high setting values (for example, settings 5 and 6), the selection rate for special drawings 1-4 is higher than the selection rate for special drawings 1-2 (10.0% for setting 5, 5.0% for setting 6). (15.0% for setting 5 and 20.0% for setting 6) is higher. Therefore, even though the jackpot type of special drawings 1-2 and 1-4 is the same (both 4R probability variable jackpot), the high setting value is compared to the low setting value (for example, setting 1 to 4). Therefore, the probability that the decorative pattern stops in the second mode (a mode in which the player has a higher expectation level than the first mode) increases.

Similarly, when it is special drawing 1-6 (10R probability variable jackpot), the host control circuit 2100 always controls the game to stop in the second mode regardless of the set value. In addition, when the main symbol is special pattern 1-8 (10R probability variable jackpot), the host control circuit 2100 selects the second mode (selection rate 50.0%) or the specific mode (selection rate 50.0%). Here, as mentioned above, at high setting values (for example, settings 5 and 6), the selection rate of special drawings 1-6 is higher than that of special drawings 1-6 (10.0% for setting 5 and 5.0% for setting 6). The selection rate of 8 (15.0% for setting 5, 20.0% for setting 6) is higher. Therefore, even though the jackpot type of special drawings 1-6 and 1-8 is the same (both 10R probability variable jackpot), the high setting value is compared to the low setting value (for example, setting 1 to 4). Therefore, the probability that the decorative symbols will stop in a specific manner (the manner in which the player has the highest level of expectation) increases.

Furthermore, in the same way, when it is special drawing 2-2 (10R probability variable jackpot), the host control circuit 2100 controls the second mode (selection rate 50.0%) or the specific mode (selection rate 50.0%) regardless of the setting value. %). Further, when the main symbol is special symbol 2-4 (10R probability variable jackpot), the host control circuit 2100 always controls the game to stop in a specific manner regardless of the set value. Here, as mentioned above, at high setting values (for example, settings 5 and 6), the selection rate of special figure 2-2 is higher than the selection rate of special figure 2-2 (20.0% at setting 5, 10.0% at setting 6). The selection rate for setting 4 (30.0% for setting 5 and 40.0% for setting 6) is higher. Therefore, even though the jackpot type of special chart 2-2 and special chart 2-4 is the same (both 10R probability variable jackpot), the high setting value is compared to the low setting value (for example, settings 1 to 4). Therefore, the probability that the decorative pattern stops in a specific manner increases.

In this way, in the second modification, as in the first modification, if the result of the jackpot determination of the special symbol is a jackpot, even if the jackpot type is the same, decorations are applied according to the set value. It becomes possible to make the patterns stop in different ways. Especially when the setting value is high (for example, setting 5 or 6), when the result of jackpot judgment of the special symbol is a jackpot, even if the composite probability determined for a specific jackpot type (for example, 10R probability variable jackpot) is the same. Also, it is possible to stop the decorative pattern in a mode (for example, a specific mode) that has a relatively high expectation level for the player with a high probability compared to when the setting value is low (for example, settings 1 to 4). Become.

In addition, in both the above-mentioned first modification and second modification, the selection rate of the main symbol is varied according to the setting value, so that the stop symbols of the decorative symbols can be different according to the setting value. are doing. That is, the host control circuit 2100 does not control the stop symbols of the decorative symbols according to the set value, but controls the stop symbols of the decorative symbols according to the main symbol, and as a result, the stop symbols of the decorative symbols are controlled according to the set value. The stop patterns of the decorative patterns can be different. However, the configuration is not limited to this, and the stop symbols of the decorative symbols may be configured to vary depending on the set value under control by the host control circuit 2100.

According to the first and second variations described above, it is possible to provide a difference in the selection rate of the special symbol according to the setting value, that is, to provide a setting difference in the number of rounds, the variable entry rate, and the time-saving entry rate. It becomes possible.

[5. Overview of drawing control method]
Here, an overview of the drawing control processing executed by the display control circuit 2300 when a drawing request control signal is output from the host control circuit 2100 to the display control circuit 2300 will be described with reference to FIG. Note that FIG. 29 is a diagram showing the flow of image data (video data and still image data) during drawing control processing.

In this embodiment, data (compressed data) of images (moving images and/or still images) to be displayed on the liquid crystal screen of the display device 16 is stored in the CGROM 2060 in the CGROM board 2040. Then, when the control signal of the drawing request is input to the display control circuit 2300, the display control circuit 2300 first reads compressed image data from the CGROM 2060 and decodes (expands) the image compressed data. At this time, if video compressed data is read out, the video compressed data is decoded by the video decoder 2340 in the display control circuit 2300, and if still image compressed data is read out, the video compressed data is decoded by the video decoder 2340 in the display control circuit 2300. The still image compressed data is decoded by the still image decoder 2350.

Next, the display control circuit 2300 writes the decoding result of the image data (image decompression data) to a predetermined buffer designated as the texture source. In this embodiment, the movie buffer and texture buffer provided in the SDRAM 2500 (external RAM) and the sprite buffer in the built-in VRAM 2370 are designated as texture sources. For example, when displaying one video, the decompressed video data (decoding result) is written to the movie buffer in the SDRAM 2500. Further, for example, when displaying one still image, the decompressed still image data is written to the sprite buffer in the built-in VRAM 2370.

Next, the display control circuit 2300 specifies a rendering target for writing the rendering (drawing) result of the image data. Note that as the rendering target, for example, a frame buffer provided in the SDRAM 2500 (external RAM), a frame buffer provided in the built-in VRAM 2370, etc. can be specified.

Next, the display control circuit 2300 operates the rendering engine 2410 to perform rendering processing on the decoded result of the image data written to the texture source, and writes the rendering result to the rendering target. Note that in this process, rendering processing is performed according to specified information (various information input from the 3D geometry engine 2400) such as scaling and rotation of the moving image.

Next, the display control circuit 2300 displays the rendering result (display output data) written to the rendering target on the display screen of the display device 16.

Note that in this embodiment, two frame buffers are prepared as rendering targets. When the rendering engine 2410 writes the rendering results to the frame buffer, the frame buffer to which the rendering results are written is switched for each frame. For example, if a rendering result is written to one frame buffer in a predetermined frame, the rendering result is written to the other frame buffer in the next frame, and the rendering result is written to one frame buffer in the next frame. That is, in this embodiment, the process of writing the rendering result to one frame buffer and the process of writing the rendering result to the other frame buffer are performed while being switched alternately for each frame.

In addition, in the above-described flow of the rendering result writing process and displaying process, the rendering result written to one frame buffer in a predetermined frame is displayed on the display screen of the display device 16 in the next frame (one side framebuffer function is switched from drawing function to display function). Furthermore, the rendering results written to the other frame buffer in the next frame are displayed on the display screen of the display device 16 one frame after another (the function of the other frame buffer is switched from the drawing function to the display function). That is, in this embodiment, display processing of rendering results in one frame buffer and display processing of rendering results in the other frame buffer are alternately switched and executed for each frame.

[6. Overview of audio playback control method]
Next, referring back to FIG. 12, an outline of the audio reproduction process executed by the audio/LED control circuit 2200 when a sound request is output from the host control circuit 2100 to the audio/LED control circuit 2200 will be described.

In this embodiment, audio data output to the speaker 24 is stored in the CGROM 2060. The audio data stored in the CGROM 2060 is compressed phrase data specified by a 13-bit phrase number NUM (000H to 1FFFH), and can be used to store a series of background music (BGM) or a group of songs. A maximum of 8192 types (=213) of production sounds (notice sounds) are stored, each corresponding to a phrase number NUM. This phrase number NUM is specified by the setting value (operation parameter) of the voice command transmitted from the host control circuit 2100 to the command register 2250 of the voice/LED control circuit 2200.

The voice command can be used for Individual Write, which transmits a 1-byte length set value to one of the many voice control registers built into the voice/LED control circuit 2200, or a series of N consecutive voice commands. It is used for block write purposes to transmit a group of N setting values to a group of voice control registers.

In any case, the audio control register to be accessed is specified by a 1-byte register address, and the storage capacity of each audio control register is 1 byte. In this embodiment, a large number of voice control registers are secured by dividing into seven register banks. That is, since the register bank is divided into seven sections, the total number of voice control registers is theoretically a maximum of 7×256.

In this embodiment, in all register banks, a specific register address is an audio control register for register bank setting. Therefore, in order to specify any one of the 7 x 256 voice control registers, first write the register bank to the voice control register for bank setting using the preceding voice command, and then write the voice control register belonging to that register bank. A register is specified by a 1-byte register address.

By the way, the operation of setting a setting value to the audio control register does not necessarily require directly specifying the register address of the audio control register to be set, but rather the SAC data (Simple Access Code Data) stored in the CGROM 2060, A sequence code can also be specified to complete a series of configuration operations for a group of audio control registers. In order to realize such an operation, the audio/LED control circuit 2200 includes four simple access controllers 2260a (simple access controllers) and 16 sequencers 2260b (sequencers) shown in FIG. .

To explain from the SAC (Simple Access Code) data for functioning the simple access controller 2260a, the SAC data contains the register address (1 byte) of the voice control register and the setting value (1 byte) for the voice control register. It means a data group of a maximum of 512 sets (=1024 bytes) that are associated and terminated with a SAC end code (FFFFH) (see FIG. 12).

In the case of this embodiment, a maximum of 8192 types (=213) of such SAC data can be provided, and the host control circuit 2100 stores the 13-bit SAC number in the audio control register for SAC control (see FIG. 12). ), the simple access controller 2260a can be made to function. The simple access controller 2260a that has started its function sequentially reads a group of SAC data specified by the SAC number from the CGROM 2060, and sets the setting value indicated by the SAC data in the audio control register indicated by the SAC data.

Therefore, the host control circuit 2100 only needs to write (register) the SAC number in the voice control register for SAC control, and can perform a series of setting operations without individually specifying the register address of the voice control register. can be given instructions. Note that a standby time (standby information as attached data) that defines the start timing of a series of setting operations can also be set in the voice control register for SAC control, and the SAC number in the voice control register for SAC control can also be set. It is also possible to delay the timing at which the simple access controller 2260a starts setting the audio control register from the write timing.

Next, a sequence code for operating the sequencer 2260b will be explained. Similarly to the SAC data, the sequence code is also a plurality of sets of data in which the register address (1 byte) of the audio control register corresponds to the setting value (1 byte) for the audio control register (see FIG. 12). However, unlike SAC data, a sequence code can define a plurality of operation steps (a plurality of sequence steps) that can be executed intermittently after a predetermined waiting time.

In addition, the audio control register for sequencer control contains, for each sequencer SQ0 to SQ15, the waiting time (standby information) that defines the start timing of the setting operation, the presence or absence of repeated operation, and the number of repetitions (loop information). ) can be included. Therefore, the sequence code specifies a series of audio effects that take a predetermined amount of time to be executed.

As shown in FIG. 12, the plurality of action steps are separated by a step end code (FFFEH), and the last of the plurality of action steps is terminated with a sequence end code (FFFFH). In the case of this embodiment, a maximum of 8192 types (=213) of sequence codes can be provided, and the host control circuit 2100 sends the 13-bit sequence code number and attached data that defines the operation of the sequencer to the sequencer (Sequencer). ) By writing to the voice control register for control, a series of setting operations can be instructed to the sequencer 2260b.

In this embodiment, necessary sets of such SAC data and sequence codes are stored in advance in the CGROM 2060, and a group of SAC data and a group of sequence codes are identified by an SAC number or a sequence code number. Therefore, in the case of this embodiment, the voice command for Write uses not only a direct setting operation to the voice control register, but also an indirect setting operation via the simple access controller 2260a and sequencer 2260b. This also includes cases where

In order to realize the above operation, the host control circuit 2100 and the audio/LED control circuit 2200 have a parallel signal line (data bus) that can transmit and receive 1-byte data, and a 2-bit operation management line that can transmit operation management data. It is connected by a data line (address bus), a 2-bit long control signal line that can control read/write operations, and a chip select signal line that selects the audio/LED control circuit 2200.

The parallel signal line is realized by the data bus of the host control circuit 2100, and the operation management data line is realized by the address bus of the host control circuit 2100. The audio/LED control circuit 2200 is assigned three port numbers PORT with the upper 6 bits common and the lower 2 bits 00, 01, and 10, and the host control circuit 2100 controls these ports. The circuit is configured such that when an I/OREAD command or an I/OWRITE command for number PORT is executed, the chip select signal CS becomes active level in either case.

Then, the data output to the lower two bits A0 to A1 of the address bus when executing the I/OREAD command or the I/OWRITE command becomes operation management data A0 to A1 for the audio/LED control circuit 2200, and these two bits A0 ~A1, it is specified whether the 1-byte data on the data bus at that time is a register address, write data, or read data.

In other words, if the address data is [00], the data on the data bus at that timing is evaluated as a register address, while if the address data is [01], the data on the data bus at that timing is evaluated as write data or read data. It becomes data. Note that execution of an I/OREAD instruction is read data, and execution of an I/OWRITE instruction is write data.

Therefore, the operation of transmitting a voice command to write a predetermined setting value into a predetermined voice control register is performed by transmitting an I/OWRITE command while changing the lower two bits A0 and A1 of the port number PORT of the voice/LED control circuit 2200. This is achieved by running it continuously. Specifically, while the lower two bits A0 to A1 of the address data are changed from [00] to [01], the 1-byte data on the data bus is changed from [register address of audio control register] to [voice control register]. [Write data to]], the transmission operation of a predetermined voice command is realized.

If the write data is multiple bytes long and the control If the register addresses of the registers are consecutive, send multiple bytes of write data while repeating the operation management data A0 to A1 of [01] in the order of [00] → [01] → [01] → [01]. .

The voice commands transmitted in this manner are then implemented within the voice/LED control circuit 2200 unless there is a communication abnormality. However, if a communication abnormality is detected, such as when data of multiple byte lengths do not match each other, the voice command will not be implemented. Then, the error flag of the voice control register is set, but this error flag (status information STS) is determined by the I/OREAD instruction that caused the address bus operation management data A0 to A1 to transition from [01] to [10]. can be received by executing

In this way, in this embodiment, multiple bit length error information (abnormal FFH) can be obtained. Then, by retransmitting the voice commands that could not be properly transmitted in parallel, the voice performance can be appropriately advanced. Therefore, according to the configuration of this embodiment, it is possible to eliminate the unnaturalness in which the audio performance suddenly stops.

On the other hand, in the data read operation by the I/OREAD operation, the I/OWRITE command and the I/OREAD command are executed continuously while changing the lower two bits A0 and A1 of the port number PORT of the audio/LED control circuit 2200. This is achieved by Note that if the read data has a length of multiple bytes, the I/OREAD command is continued for the required number of bytes.

To confirm this concretely, first, as an I/OWRITE operation, for the port number PORT whose lower two bits A0 to A1 of the address data are [00], [the register address of the voice control register that stores the operation status etc. 1 byte length)] is output. Next, by executing the I/OREAD command for the port number PORT whose lower two bits A0 to A1 of the address data are [01], necessary data such as the operating status can be obtained from the predetermined audio control register. Can be done.

The audio reproduced by the audio/LED control circuit 2200 having the above configuration is converted into digital audio in the form of a 5-bit signal (SCLK, LRO, SD0, SD1, SD2) as a digital audio signal of the audio/LED control circuit 2200. The signal is transmitted to the power amplifier 2620, class D amplified by the digital audio power amplifier 2620, and supplied to each speaker as an analog audio signal. Specifically, the amplified output (analog audio signal) of the digital audio power amplifier 2620 is supplied to the lower bass speaker, and the amplified output (analog audio signal) of the digital audio power amplifier 2620 is supplied to the player. Four normal speakers (for example, see Figure 13 (L0, R0, L1, R1) and two deep bass (vibration) speakers (for example, see Figure 13 (SUB0, SUB1).

[7. Processing by main control circuit]
Next, various processes executed by the main CPU 101 of the pachinko gaming machine 1 will be explained with reference to FIGS. 30 to 51. However, in the following explanation (description of processing in the main CPU 101), the terms power switch 35, setting switch 332, setting key 328, performance display monitor 334, error notification monitor 336, external terminal board 323, and hall computer 700 are used. These are shown in FIG.

[7-1. Power-on processing]
FIG. 30 is a flowchart illustrating an example of power-on processing by the main CPU 101. For example, when a person involved in the hall turns on the power switch 35, the pachinko game machine 1 is powered on. When the power of the pachinko game machine 1 is turned on, as shown in the figure, the main CPU 101 performs a power-on process (step S10), a setting process related to setting values (step S20), and a game return process (step S20). S30) are executed in order. Each of these processes will be explained below. Although not shown in the figure, the main CPU 101 constantly checks whether the voltage has dropped to a predetermined level, and when the voltage drops to a predetermined level due to a power outage, turning off the power switch 35, etc. Performs processing when a power outage occurs, which will be described later.

[7-1-1. Power-on processing]
FIG. 31 is a flowchart illustrating an example of power-on processing. When the power of the pachinko game machine 1 is turned on, as shown in the figure, the main CPU 101 sets an initial value to the stack pointer (step S11).

Next, the main CPU 101 permits access to the RWM (main RAM 103) (step S12), and then performs a sub-control reception acceptance wait process of waiting until the sub-control circuit 200 becomes able to accept a signal (step S13). After that, the main CPU 101 performs initialization processing for various devices built into the CPU (step S14).

Next, the main CPU 101 activates the switch related to the set value (step S15). The switches related to setting values are the switches used when performing the setting process in step S20, and include, for example, the setting key 328 for starting and ending the setting process, the setting switch 332 for changing the setting value, etc. Equivalent to. Then, the main CPU 101 validates the switches related to the settings (step S15), performs a reading process for each switch (step S16), and then performs a game permission process (step S17).

FIG. 32 is a flowchart showing an example of the game permission process. In the game permission process in step S17 (see FIG. 31), a game permission flag is managed to permit execution of the game. The game permission flag is a flag indicating whether or not to permit the execution of the game, and is set to OFF when the game cannot be executed, for example, when the work area of the RWM (main RAM 103) is not normal. . The game permission process (step S17) will be explained below.

The main CPU 101 first determines whether the power outage situation identification flag is ON (step S1710). The power outage situation identification flag is a flag that identifies the situation when the previous power outage occurred. In other words, for example, if a power outage occurs during the settings change process described below, there is a high possibility that the power will be cut off before the settings change process is properly completed, so when the power is turned on, the game will be allowed to continue playing. Can not do it. Therefore, when the power is turned on, the situation at the time of the previous power outage can be identified. In this embodiment, for example, when a power outage occurs during a normal game or during a setting confirmation process to be described later, the power outage situation identification flag is set to ON until the power is cut off. On the other hand, when a power outage occurs during a setting change process to be described later, the power outage situation identification flag is set to OFF until the power is cut off. Also, when a power outage occurs during an abnormal state in steps S722 to S727, which will be described later, the power outage situation identification flag is set to OFF. Note that in the initial state where the power has not been turned on yet or when the data in the main RAM 103 is lost because the power has not been turned on for a long period of time, the power failure situation identification flag is OFF. The above-mentioned "normal gaming" means a gaming state in which neither the setting change process nor the setting confirmation process is performed, and does not mean the normal gaming state in which both the probability change flag and the time saving flag are OFF. (same as below).

In step S1710, if the power outage situation identification flag is ON (YES in step S1710), the main CPU 101 moves to step S1720, and if the power outage situation identification flag is OFF (NO in step S1710), the main CPU 101 flags the game permission flag. After turning off (step S1750), the process moves to step S1720.

In step S1720, the main CPU 101 checks the work area of the main RAM 103. This checking of the work area also includes checking whether the set value data is within a specified range (in the present embodiment, within the range of "0" to "5").

Note that the work area of the main RAM 103 includes a general work area where data is cleared when a backup clear process is performed, which will be described later, and a general work area where data is generally retained without being cleared even if a backup clear process is performed, which will be described later. It is divided into specific work areas. This specific work area stores, for example, performance display data, set value data, and the like. This is data indicating the setting value. In this embodiment, setting value data of "0" to "5" correspond to each of the six levels of setting values "1" to "6". That is, for example, if the set value is "4", the set value data stored in the main RAM 103 is "3".

In step S1730, the main CPU 101 determines whether the work area of the main RAM 103 is normal or not, and if it is normal (YES in step S1730), the process moves to step S1740, and if it is not normal, that is, abnormal (NO in step S1730). If so, the game permission flag is turned OFF (step S1760), and then the process moves to step S1740. For example, when the setting value data is not within a specified range (in the present embodiment, within the range of "0" to "5"), the main CPU 101 determines that the work area of the main RAM 103 is not normal.

In step S1740, the main CPU 101 determines whether the game permission flag is ON. In this step S1740, if a power outage occurs during a normal game or during a setting confirmation process to be described later (YES in step S1710), and the work area of the main RAM 103 is normal (YES in step S1730), the game permission flag is turned ON. It is determined that On the other hand, if a power outage occurs during the setting change process or in an abnormal state (NO in step S1710), and if the work area of the main RAM 103 is not normal (NO in step S1730), the game permission flag is OFF. It is determined that Then, if the game permission flag is ON (YES in step S1740), the game permission process is ended. If the game permission flag is OFF (NO in step S1740), the process moves to step S1770.

Note that in this specification, power outages that occur during normal gaming, power outages that occur during setting confirmation processing, and power outages that occur during setting change processing are referred to as normal power outages, and are referred to as normal power outages, and will be referred to as steps S722 to S727 described later. A power outage that occurs in this case is considered an abnormal power outage.

In step S1770, the main CPU 101 determines whether the power is turned on with the setting key 328 turned ON (the power switch 35 is turned ON), that is, whether the setting key switch signal is ON. If the setting key switch signal is ON (YES in step S1770), the process moves to step S1780, and if the setting key switch signal is OFF (NO in step S1770), the process moves to step S1810.

In step S1780, the main CPU 101 determines whether the backup clear switch 330 has been pressed, that is, whether the backup clear signal is ON, and the backup clear signal is ON (YES in step S1780). Then, the process moves to step S1790, and if the backup clear signal is OFF, the process moves to step S1810.

In step S1790, the main CPU 101 sets the game permission flag to ON, and moves to step S1800.

In this way, the main CPU 101 turns the setting key switch signal ON ( If the backup clear signal is ON (YES in step S1770) and the backup clear signal is ON (YES in step S1780), the game permission flag is set to ON in step S1790. That is, if both the power-on operation and the pressing operation of the backup clear switch 330 are performed while the setting key 328 is turned ON, the game permission flag is turned ON even if the game permission flag is OFF. However, if at least one of the setting key switch signal and the backup clear signal is OFF, the game permission flag will not be set from OFF to ON.

In step S1800, main CPU 101 sets the backup clear flag to ON, and ends the game permission process. The backup clear flag is a flag that indicates whether or not it is necessary to perform backup clear processing, which will be described later. When it is necessary to perform backup clear processing, the backup clear flag is set to ON, and when backup clear processing is performed, The backup clear flag is set to OFF.

In step S1810, the main CPU 101 sets a notification so that an error code indicating that execution of the game is not permitted (the game permission flag is OFF) is displayed on the error notification monitor 336. After performing the process of step S1810, the main CPU 101 ends the game permission process. In this way, by displaying the error code on the error notification monitor 336, the person concerned with the hall can check the error code displayed on the error notification monitor 336 and confirm that the game is not in a state where the game can be executed (the game permission flag is OFF). ). In this embodiment, when the game permission flag is OFF, the game permission flag is turned on only if both the power-on operation and the pressing operation of the backup clear switch 330 are performed while the setting key 328 is turned on. It is possible to set it to ON. That is, when the game permission flag is OFF, the game permission flag will not be turned ON unless a power cut operation is performed to temporarily stop the power supply and a setting change process described later is executed. In addition, in the above, the game permission process is ended when the process of step S1810 is performed, but instead of this, after the process of step S1810 is performed, the process returns to step S1740 and the condition for turning on the game permission flag is set. The processing from step S1740 to step S1810 may be looped until the following is satisfied (in FIG. 32, until YES is determined in step S1780).

[7-1-2. Setting processing]
FIG. 33(a) is a flowchart showing an example of the setting process in step S20 (see FIG. 30), and FIG. 33(b) is a flowchart showing another example of the setting process in step S20. The only difference between FIG. 33(a) and FIG. 33(b) is the processing when it is determined in step S21 that the game permission flag is OFF (NO in step S21), and the other processing (step The processes from S22 to S28) are common to both. The setting process will be explained below.

As shown in FIG. 33(a), the main CPU 101 first determines whether or not the game permission flag is ON in step S21. If the game permission flag is ON (YES in step S21), the main CPU 101 moves to step S22, and if the game permission flag is OFF (NO in step S21), the main CPU 101 executes a setting change process (step S24) and a setting confirmation process ( The setting process ends without executing any of step S26).

When the setting key switch signal is ON (YES in step S22) and the backup clear signal is ON (YES in step S23), the main CPU 101 performs a setting change process (step S24), and turns the setting key switch signal ON (YES in step S22). ) and the backup clear signal is OFF (NO in step S23), a setting confirmation process (step S26) is performed. Therefore, when the power is turned on with the setting key 328 turned ON, the setting change process (step S24) is executed if the backup clear signal is ON, and the setting confirmation process (step S24) is executed if the backup clear signal is OFF. S26) is executed.

Note that when the setting key switch signal is OFF (NO in step S22) and the backup clear signal is ON (YES in step S27), the main CPU 101 sets the backup clear flag to ON (step S28) and performs the setting change process (step S27). The setting process ends without executing either S24) or the setting confirmation process (Step S26). Furthermore, if the setting key switch signal is OFF (NO in step S22) and the backup clear signal is OFF (NO in step S27), the main CPU 101 ends the setting process (setting change) without executing the process in step S28. The processing (step S24) and setting confirmation processing (step S26) are also not executed).

That is, if the previous power outage was a normal power outage that occurred during a normal game or during a setting confirmation process to be described later, and if the work area of the main RAM 103 is normal, YES is determined in step S21. At this time, the main CPU 101 performs a setting change process (step S24) and a setting confirmation process (step S26) depending on the operation status of the setting key 328 and the press operation status of the backup clear switch 330 when the power is turned on. Alternatively, the backup clear flag process (step S28) is executed. Note that when the power is turned on without operating either the setting key 328 or the backup clear switch 330, the setting change process (step S24), the setting confirmation process (step S26), and the backup clear flag process (step S28) are performed. Without executing any of the above, the process moves to the game return process (step S30), and after the game return process (step S30) is executed, the game can be played.

On the other hand, if the previous power outage was an abnormal power outage, or even if the previous power outage was a normal power outage, it was determined to be NO in step S21. . At this time, the main CPU 101 performs a setting change process (step S24) and a setting confirmation process (step S26) regardless of the operation status of the setting key 328 or the pressing operation of the backup clear switch 330 when the power is turned on. The setting process is ended without executing either of the setting process and the backup clear flag ON (step S28). Therefore, if a power outage occurs during the setting change process or if the previous power outage was an abnormal power outage, the setting key switch signal is turned ON (YES in step S1770) and the backup clear signal is turned ON (YES in step S1780). When it is determined that the setting value is fixed (that is, when the setting key 328 is turned on, both the power-on operation and the pressing operation of the backup clear switch 330 are performed, and the setting is changed). Only then, the setting change process (step S24) is executed and the process moves to the game return process of step S30, and after this game return process (step S30) is executed, the game can be played. Therefore, when neither the setting key 328 nor the backup clear switch 330 is operated, or even if only one of them is operated, the setting change process (step S24) and the setting confirmation process (step S26) are performed. ) and the backup clear flag process (step S28) are not executed, and the process moves to the game return process (step S30). However, in this game return process (step S30), an abnormality process (see step S38 in FIG. 37, which will be described later) is executed, and the game cannot be played and the game is stopped.

In this way, in the example of the setting process shown in the flowchart of FIG. 33(a), if a power outage occurs during the setting change process or if the previous power outage was an abnormal power outage, the power is turned on. Regardless of the operation status of the setting key 328 or the operation status of pressing the backup clear switch 330 at the time, either the setting change process (step S24), the setting confirmation process (step S26), or the backup clear flag ON (step S28) is executed. The setting process has ended without executing either. However, the present invention is not limited to this, and as in another example of the setting process shown in the flowchart of FIG. In this case, the main CPU 101 forcibly executes the setting change process (step S24) regardless of the operation status of the setting key 328 or the press operation of the backup clear switch 330 when the power is turned on. You can do it like this. If a power outage occurs during the setting change process or if the previous power outage was an abnormal power outage, the operation status of the setting key 328 and the pressing operation of the backup clear switch 330 when the power is turned on will be changed. By forcibly executing the setting change process (step S24) regardless of the situation, if you forget to operate the setting key 328 or the backup clear switch 330 and turn on the power, you will not be able to turn on the power again. This makes it possible to reduce the hassle of having to make a decision.

In the flowchart shown in FIG. 33(a), if the determination in step S21 is NO, the setting process is performed without determining either the operating status of the setting key 328 or the operating status of the pressing operation of the backup clear switch 330. It's finished. Similarly, in the flowchart shown in FIG. 33(b), if NO is determined in step S21, the setting is made without determining either the operation status of the setting key 328 or the operation status of the pressing operation of the backup clear switch 330. A change process (step S24) is being executed. However, instead of these, the operation status of the setting key 328 and/or the operation status of pressing the backup clear switch 330 is determined, and regardless of the determination result, the setting process is terminated or the setting change process (step S24) You may also execute

[7-1-2-1. Setting change processing]
FIG. 34 is a flowchart illustrating an example of a setting change process. The setting change process in step S24 (see FIG. 33) is a process for changing the set setting value, but the setting change process can also be ended with the same setting value as the set value. . Further, as described above, when the game permission flag is OFF, the game permission flag will not be turned ON unless a power cut operation is performed to temporarily stop the power supply and a setting change process is executed.

Main CPU 101 first determines whether the game permission flag is ON in step S2410. If the game permission flag is OFF (NO in step S2410), the main CPU 101 ends the process without executing the setting change process. Note that even if the game permission flag is OFF when the power is turned on, if the setting key switch signal is ON and the backup clear signal is ON, the game permission flag is set to ON in step S1790 (see FIG. 32). Therefore, the settings change process is executed.

If the game permission flag is ON (YES in step S2410), the main CPU 101 moves to step S2420 and executes a backup clear process. This backup clearing process will be described later.

After executing the backup clear process in step S2420, the main CPU 101 moves to step S2430, stores the setting value data stored in the main RAM 103 in a register, and moves to step S2440. Note that the backup clearing process may be executed at any timing after the setting change process is started until it ends.

In step S2440, the main CPU 101 sets the output of the setting change security signal. This setting change security signal is transmitted to the hall computer 700 via the external terminal board 323 described above. Note that the setting change security signal is output for a certain period of time or more (for example, 50 msec or more) within the output period of the signal.

In step S2450, the main CPU 101 sets notification so that the setting value information is displayed on the performance display monitor 334. On this performance display monitor 334, the setting value data stored in the register is converted into a setting value and displayed. For example, when the set value data stored in the register is "3", the performance display monitor 334 displays a set value "4" corresponding to the set value data "3". However, as long as the setting value data stored in the register and the set value correspond, the numbers do not necessarily need to be displayed on the performance display monitor. For example, setting value data "0" to "5" are respectively associated with "A" to "F", and when the setting value data stored in a register is, for example, "3", the corresponding "D" is set. may be displayed on the performance display monitor 334. In this step 2450, the setting value data stored in the register is converted to a setting value and displayed on the performance display monitor 334, but as the previous data is discarded, the predetermined value is displayed. The initial value (for example, "1") may be displayed. Also, when the power is turned on to this pachinko gaming machine 1 for the first time, the main CPU 101 displays a predetermined initial value (for example, "1"), a value that is not normally displayed (for example, "8"), etc. on the performance display monitor. 334 may be displayed. When displaying a value that is not normally displayed on the performance display monitor 334, the main CPU 101 does not set a valid setting value and turns off the game permission flag unless it is determined in step S2510 that the setting switch 332 has been pressed. You may also do so.

In step S2460, the main CPU 101 sets the notification so that a setting changing code indicating that the setting is being changed is displayed on the error notification monitor 336. Thereby, by checking the display on the error notification monitor 336, the hall personnel can understand that the setting change process is in progress.

In step S2470, the main CPU 101 determines whether the setting key switch signal is OFF, and if the setting key switch signal is not OFF (NO in step S2470), the process moves to step S2510.

In step S2510, the main CPU 101 determines whether or not the setting switch 332 has been pressed. If the setting switch 332 has been pressed (YES in step S251), the main CPU 101 moves to step S2520, and the setting value stored in the register is After updating the data, the process returns to step S2440. On the other hand, if the setting switch 332 is not pressed (NO in step S2510), the process returns to step S2440. That is, in the setting change process, unless it is determined that the setting key switch signal is ON (unless YES in step S2470), steps S2510, S2520, and steps S2440 to S2470 are looped (step S2510, step S2520, The processes from S2440 to S2470 are repeated).

Note that when the setting switch 332 is pressed (determined as YES in step S2510), the main CPU 101 sets a notification so that the updated setting value information is displayed on the performance display monitor 334 in the subsequent step S2450. .

Further, unless the main CPU 101 determines that the setting key switch signal is OFF (YES in step S2470), each time the setting switch 332 is pressed, the main CPU 101 changes the setting value data stored in the register from "0" to "5". ” (if the setting switch 332 is pressed when the setting value data is “5”, it returns to “0”). Thereby, each time the setting switch 332 is pressed, the display on the performance display monitor 334 is also cycled. However, each time the setting switch 332 is pressed, the setting value data stored in the register may be cyclically decreased from "5" to "0", or the setting value data may be cyclically increased or cyclically reduced depending on the manner in which the setting switch 332 is pressed. It may be possible to perform both the reduction and the reduction.

In step S2470, if the main CPU 101 determines that the setting key switch signal is OFF (YES in step S2470), the process moves to step S2480. Moving to step S2480, the main CPU 101 ends the loop of steps S2510, S2520, and steps S2440 to S2470.

In step S2480, main CPU 101 stores the setting value data stored in the register in main RAM 103. When the process of step S2480 is executed, the set value is determined. That is, in the setting change process, the setting value is determined based on the execution of an operation that turns the setting key switch signal OFF (determined as YES in step S2470), and the setting value is determined based on the execution of an operation that turns the setting key switch signal OFF. If the setting switch 332 is simply pressed without executing (steps S2510, S2520, and steps S2440 to S2470 are simply looped), the setting value data stored in the register is simply updated. The setting value data stored in the main RAM 103 is not updated.

Note that even if the setting key 328 is returned again after it is determined in step S2470 that the setting key switch signal is OFF (YES in step S2470), the operation will not be detected (the setting key switch signal is detected as ON). The set value cannot be changed unless the power is turned off (turning off the power switch 35). Note that at that time (when the setting key 328 is returned again after the setting key switch signal is determined to be OFF (YES in step S2470) in step S2470), the main CPU 101 returns the setting stored in the register. The value data may be displayed on the performance display monitor 334 so that settings can be confirmed (setting confirmation processing is performed). At that time (when performing the setting confirmation process), the main CPU 101 may keep the game permission flag OFF until the setting key switch signal is turned OFF.

By the way, if a power outage occurs during the setting change process or the previous power outage was an abnormal power outage, the operation status of the setting key 328 and the backup when the power is turned on afterwards (at the time of recovery from a power outage) When the setting change process (see FIG. 34) is forcibly executed regardless of the operation status of the clear switch 330 pressing operation (the state of the setting key switch signal or backup clear signal) (see FIG. 33(b)) In this case, the setting change process is executed even if the setting key 328 is not turned on (the setting key switch signal remains OFF). In this way, when the setting key 328 is not turned ON and the setting change process (step S24) is executed, the setting key switch signal may remain OFF, so the main CPU 101 changes the setting key switch signal in step S2470. Instead of immediately determining that the switch signal is OFF (YES in step S2470), it is determined that the setting key switch signal is OFF when the setting key 328 is turned ON and then turned OFF, and the process proceeds to step S2470. The process moves to S2480 (the set value is determined). In this case, the main CPU 101 may determine YES in step S2480 upon detecting that the setting key switch signal has turned ON and further detecting that the setting key switch signal has turned OFF. Alternatively, YES may be determined in step S2480 based on the detection that the setting key switch signal has changed from ON to OFF, without detecting that the setting key switch signal has turned ON.

In addition, in the above, if a power outage occurs during the setting change process or the previous power outage was an abnormal power outage, the power outage will be forcibly canceled regardless of the state of the setting key switch signal or backup clear signal at the time of recovery from the power outage. Although it has been described that the setting change process is executed, the present invention is not limited to this. For example, the main CPU 101 may forcibly change the state to the setting change state regardless of the state of the setting key switch signal or backup clear signal at the time of power recovery. Also, regardless of the state of the setting key switch signal or backup clear signal at the time of power outage recovery, power outage recovery is performed with the settings changed at the time of power outage (in other words, the state is maintained at the time of power outage, and the subsequent At the time of recovery from power failure, processing for returning to the maintained state may be executed, regardless of the state of the setting key switch signal and backup clear signal at the time of recovery from power failure.

In step S2490, the main CPU 101 sets the notification so that the performance display data is displayed on the performance display monitor 334, and in step S2500 sets the notification so that the initialization code is displayed on the error notification monitor 336, and changes the settings. Finish the process.

Note that when it is determined in step S2470 that the setting key switch signal is OFF (YES in step S2470), a command indicating that the setting key switch signal has been turned OFF, that is, a command indicating that the setting change process has been completed, is executed. An initialization command will be sent to host control circuit 2100.

When the setting change process in step S24 (see FIG. 33) ends, the setting process in step S20 (see FIG. 30) ends, and the process moves to the game return process in step S30 (see FIG. 30).

In addition, if it becomes possible to play the game through the game return process described below after the setting change process in step S24 (see FIG. 33) is executed, the Information suggesting that a setting change process may have been executed at a predetermined timing after the start of the process, information suggesting that a setting value may have been changed to a higher value by the setting change process, Information that suggests that the setting value may have been changed to a lower value by the setting change process, or information that the setting value has been changed by more than one level by the setting change process (for example, the setting value has been changed by two or more levels, such as from setting 6 to setting 4). Furthermore, information related to the setting change process, such as information suggesting that there is a possibility, may be displayed on the display device 16, for example. For example, the variation pattern of effects and decorative patterns performed on the display device 16 etc. may be made different depending on when the setting change process is executed and when it is not executed, or the setting value may be changed to a higher setting value by the setting change process. The setting value can be different when the setting value is changed to a low setting value, or when the setting value is changed by more than one step by the setting change process and when it is not changed by more than one step. Also good.

Furthermore, the output period of the setting change security signal described above and the period during which the setting change in progress code is displayed on the error notification monitor 336 are from the start of the setting change process until the completion process of the setting change process. It has become. However, it is not necessary that these periods match completely.

Note that the above setting change process is a process that is executed regardless of whether the internal game permission flag is ON or OFF. Additionally, a command is sent to the sub-control circuit 200 at a predetermined timing, such as when the setting change process in step S24 is started, each time the setting switch is pressed in step S2510, and when executing the process in step S2480. Accordingly, the display device 16, the speaker 24, the LED 25, etc. may be used to notify that the setting is being changed, to notify that the setting value has been changed, to notify that the setting change has been completed, etc.

[7-1-2-1-1. Backup clear processing]
FIG. 35 is a flowchart illustrating an example of the backup clearing process in step S2420 (see FIG. 34). This backup clearing process is a process for clearing information stored in the work area of the main RAM 103. However, in this backup clearing process, as described above, although the information stored in the general work area is cleared, the information stored in the specific work area is not, in principle, cleared.

First, in step S2421, the main CPU 101 determines whether the backup clear flag is OFF. When the backup clear flag is OFF (YES in step S2421), the main CPU 101 ends the process without executing the backup clear process, and when the backup clear flag is ON (NO in step S2421), the main CPU 101 terminates the process in step S2422. Move to.

In step S2422, the main CPU 101 clears the work area of the RWM (main RAM 103). However, if the previous power outage occurred during the setting change process, there is a possibility that all or part of the backup clear process was executed during the setting change process in which the previous power outage occurred. Therefore, if the previous power outage occurred during the setting change process, the work area of the main RAM 103 is cleared along with the backup clear process executed during the setting change process when the previous power outage occurred. In this backup clearing process, it may be possible to only partially clear the data.

Note that in the process of step S2422, as described above, the performance display data and setting value data stored in the specific work area are not cleared in principle. However, if it is determined that the setting value data stored in RWM (main RAM 103) is abnormal (for example, the set value data is outside the specified range), the setting value data will also be cleared. Ru. Furthermore, when it is determined that the performance display data stored in the RWM (main RAM 103) is abnormal, the performance display data is also cleared. Note that when the setting value data is abnormal, the setting value data is also cleared, but in that case, the gaming permission flag is turned OFF and unless the setting change process (for example, see FIG. 34) is performed, gaming is not permitted. The flag may not be turned on.

In step S2423, the main CPU 101 sets notification so that information indicating that the backup clearing process has been executed (information indicating that the work area of the main RAM 103 has been cleared) is displayed. Thereafter, in step S2424, the main CPU 101 sets the backup clear flag to OFF, and ends the backup clear process. Note that the above notification setting (information indicating that the backup clear process has been executed) is sent as a command to the sub control circuit 200, and the display control circuit 2300 (see FIG. 10) indicates that the backup clear process has been executed. The image shown is displayed on the display device 16, for example.

Note that when the backup clearing process is executed in conjunction with the setting change process (for example, see FIG. 34), in step S2450 of the setting change process, the main CPU 101 causes the setting value information to be displayed on the performance display monitor 334. Set notification. Similarly, even when the backup clearing process is executed without the setting change process, notification settings may be made so that the setting value information is displayed on the performance display monitor 334.

[7-1-2-2. Settings confirmation process]
FIG. 36 is a flowchart illustrating an example of setting confirmation processing. The setting confirmation process in step S26 (see FIG. 33) is a process for confirming the set setting values. The set value is stored in the main RAM 103.

Main CPU 101 first determines whether the game permission flag is ON in step S2610. If the game permission flag is OFF (NO in step S2610), the main CPU 101 ends the process without executing the setting confirmation process.

If the game permission flag is ON (YES in step S2610), the main CPU 101 moves to step S2620 and sets the output of a setting confirmation security signal. This setting confirmation security signal is transmitted to the hall computer 700 via the external terminal board 323 described above. Note that the setting confirmation security signal is output for a certain period of time or more (for example, 50 msec or more) within the output period of the signal.

In step S2630, the main CPU 101 sets notification so that the setting value information is displayed on the performance display monitor 334. The setting value information displayed on the performance display monitor 334 is information indicating set value data. For example, when the setting value data stored in the main RAM 103 is "3", "4" corresponding to the setting value data "3" is displayed on the performance display monitor 334 as information indicating the setting value.

In step S2640, the main CPU 101 sets the notification so that a setting confirmation code indicating that the settings are being confirmed is displayed on the error notification monitor 336. Thereby, the hall personnel can understand that the setting confirmation process is in progress by checking the display on the error notification monitor 336.

In step S2650, the main CPU 101 determines whether the setting key switch signal is OFF, and if the setting key switch signal is not OFF (NO in step S2650), the process returns to step S2620. That is, in the setting confirmation process, unless it is determined that the setting key switch signal is ON (unless YES in step S2650), the process from step S2620 to step S2650 is looped (the process from step S2620 to step S2650 is repeated). It happens.

In step S2650, if the main CPU 101 determines that the setting key switch signal is OFF (YES in step S2650), the process moves to step S2660. Moving to step S2660, the main CPU 101 ends each process from step S2620 to step S2650.

Note that when it is determined in step S2650 that the setting key switch signal is OFF (YES in step S2650), a power failure recovery command is sent to the host control circuit 2100 in step S37, which will be described later, as a command indicating that the setting confirmation process has ended. will be sent to.

In step S2660, the main CPU 101 sets the notification so that the performance display data is displayed on the performance display monitor 334, and in step S2670 sets the notification so that no information is displayed on the error notification monitor 336, and performs the setting confirmation process. end.

When the setting confirmation process in step S26 (see FIG. 33) ends, the setting process in step S20 (see FIG. 30) ends, and the process moves to the game return process in step S30 (see FIG. 30).

[7-1-3. Game return processing]
FIG. 37 is a flowchart showing an example of the game return process. In the setting process of step S30 (see FIG. 30), on the premise that the game permission flag is ON, a process of returning to a state where a game can be executed is performed. The game return process will be explained below.

First, in step S31, the main CPU 101 determines whether the game permission flag is ON. If the game permission flag is OFF (NO in step S31), the main CPU 101 executes the abnormality process in step S38. This abnormality processing will be described later.

If the game permission flag is ON (YES in step S31), the main CPU 101 moves to step S32 and performs processing to enable all switches.

In step S33, the main CPU 101 determines whether the backup clear signal is OFF. If the backup clear signal is OFF (YES in step S33), the main CPU 101 moves to step S34.

In step S34, the main CPU 101 determines whether the power outage situation identification flag is ON. If the power outage situation identification flag is ON (YES in step S34), the main CPU 101 moves to step S35. As mentioned above, the power outage status identification flag is set to ON when a power outage occurs during normal gaming (during gaming where neither setting change processing nor setting confirmation processing is being performed) or during setting confirmation processing. If a power outage occurs during the change process, it is set to OFF. Therefore, when the previous power outage occurred during the normal game or during the setting confirmation process, the process of step S35 is performed.

In step S35, the main CPU 101 initializes a work area that requires an initial value at the time of recovery from power outage.

Next, in step S36, if the gaming state at the time of power outage recovery is a high probability gaming state, the main CPU 101 performs notification settings to indicate that the gaming state is a high probability gaming state.

Next, in step S<b>37 , the main CPU 101 performs a process of transmitting a power recovery command (power recovery command) to the sub control circuit 200 . This command also includes setting value information about the setting values that have been set. When this process is finished, the main CPU 101 finishes the game return process in step S30 (see FIG. 30), and the series of power-on processes ends. This allows the game to be played. The power failure recovery command described above functions as a command indicating that it is time to recover from a power failure, or a command indicating that the setting confirmation process has been completed.

In step S33, if the main CPU 101 determines that the backup clear signal is ON (NO in step S33), the main CPU 101 moves to backup clear processing in step S39. This backup clearing process is similar to the backup clearing process in step S2420 shown in FIG. 34 (backup clearing process shown in FIG. 35), and therefore the description thereof will be omitted.

When the backup clear process in step S39 is completed, the main CPU 101 moves to step S40 and initializes a work area that requires an initial value when initializing the RWM (main RAM 103).

Next, in step S41, the main CPU 101 performs a process of transmitting a command for RWM initialization (initialization command) to the sub control circuit 200. When this process is finished, the main CPU 101 finishes the game return process in step S30 (see FIG. 30), and the series of power-on processes ends. This allows the game to be played. Note that the above initialization command can be used as a command to indicate that the settings change process has ended (backup clear process has also been executed), or as a command to indicate that backup clear process without setting change process has been executed. Function.

Furthermore, the output period of the above-mentioned setting confirmation security signal and the period during which the setting confirmation code is displayed on the error notification monitor 336 are from the start of the setting confirmation process until the completion process of the setting confirmation process. It has become. However, it is not necessary that these periods match completely.

[7-1-3-1. Abnormality processing]
FIG. 38 is a flowchart illustrating an example of abnormality processing. As described above, the abnormality process in step S38 (see FIG. 37) is executed when it is determined that the game permission flag is OFF (NO in step S31) in the process in step S31 (see FIG. 37). It is processing.

First, in step S381, the main CPU 101 performs a process of transmitting to the sub control circuit 200 an abnormality command indicating that the game permission flag is OFF, that is, the game cannot be played. When the host control circuit 2100 receives an abnormal command, it can determine that there is a backup failure, and display information that the pachinko gaming machine 1 is not normal on the display device 16 under the control of the host control circuit 2100 (display control circuit 2300). becomes.

Note that the main CPU 101 does not necessarily have to send the abnormal command. For example, if the host control circuit 2100 fails to receive a normal command from the main CPU 101 for a predetermined period of time (for example, 30 seconds) after power supply to the sub-control circuit 200 (see FIG. 9) is started, the host control circuit 2100 detects a backup failure. It may be determined that

In step S382, the main CPU 101 performs output settings for the abnormal security signal. This abnormal security signal is transmitted to the hall computer 700 via the external terminal board 323 described above.

In step S383, the main CPU 101 sets a notification so that an error code indicating that execution of the game is not permitted (the game permission flag is OFF) is displayed on the error notification monitor 336. Thereby, by checking the display on the error notification monitor 336, the hall personnel can understand that the game is not in a state where the game can be executed (the game permission flag is OFF).

In step S384, the main CPU 101 determines whether the power interruption detection signal is ON. The power interruption detection signal is a signal that turns ON when the voltage drops to a predetermined level. When the main CPU 101 determines that the power outage detection signal is ON (YES in step S384), the process moves to step S385, and a power outage process is executed. On the other hand, if the power interruption detection signal is OFF (NO in step S384), the main CPU 101 loops steps S382 to S384 (the processes of steps S382 to S384 are repeated).

[7-1-3-1-1. Processing when power outage occurs]
FIG. 39 is a flowchart illustrating an example of processing when a power outage occurs. As described above, the main CPU 101 constantly checks whether the voltage has dropped to a predetermined level, and when the voltage drops to a predetermined level, performs processing in the event of a power outage.

First, the main CPU 101 performs interrupt prohibition settings so that interrupt processing is not executed (step S3851). Then, a checksum is calculated in the work area of the main RAM 103, and the calculation result and various game data are stored (saved) in the backup area of the main RAM 103 (step S3852). This checksum is used to check whether the contents of the main RAM 103 before the power outage are properly retained when the power is restored. In this way, even if the power supply is stopped, it is possible to retain various game data stored in the main RAM 103.

Next, the main CPU 101 sets a power outage situation identification flag in a backup flag provided in a predetermined area of the main RAM 103 (step S3853). That is, as described above, the main CPU 101 identifies the situation at the time of power outage if the power outage occurs during normal gaming (during gaming where neither setting change processing nor setting confirmation processing is performed) or setting confirmation processing. The flag is set to ON, and if it occurs during the setting change process, it is set to OFF.

When the main CPU 101 finishes the processing of steps S3851 to S3853, the process moves to step S3854, prohibits access to the RWM (main RAM 103), and enters an infinite loop in preparation for stopping the power supply.

When the game permission flag is OFF in this way, as described above, the power supply is temporarily stopped by performing a power cut operation, and the game permission flag is not turned ON unless the setting change process described later is executed. It has become.

By the way, in this process, if the power supply voltage becomes unstable due to a very short power outage (hereinafter referred to as an "instantaneous power outage") and the power outage process is started, it is not possible to recover from the infinite loop. There is a risk that it will disappear. In order to avoid such a problem, the main CPU 101 of this embodiment is provided with a watchdog timer (not shown), and is configured to be reset if the watchdog timer is not updated for a predetermined period of time. The watchdog timer is updated periodically while the process is being performed normally, but it is no longer updated when the process starts when a power-off occurs. As a result, even if the system enters the power-off process due to an instantaneous power failure and enters the infinite loop shown in FIG. 39, it will be reset after a predetermined period of time, and the main CPU 101 will start up in the same process as when the power is turned on.

Note that a rewritable nonvolatile memory (such as EEPROM) may be provided instead of the backup area of the RWM (main RAM 103). In this case, there is an advantage that constant power supply is not required to back up data.

Alternatively, the entire area of the RWM (main RAM 103) may be used as a backup area where data is backed up by constant power supply. In this case, there is no need to save data stored in the main RAM 103 to another area when the power is turned off. Further, even when the power is restored, there is no need to read the saved data to the processing area, so the load required for these processes is reduced.

[7-1-4. Flow of power-on processing from the operator's perspective]
The above is the control flow of the power-on process by the main CPU 101, and the flow of the power-on process from the perspective of the person performing the operation (for example, a person involved in the hall) will be briefly explained.

[7-1-4-1. Setting change process flow]
First, a description will be given of the setting change process, that is, the flow for changing the set setting values. In order to change the set value, it is first necessary to perform a power-off operation (turn off the power switch 35). Then, while the power is not turned on, the setting key 328 is turned on, and both the backup clear switch 330 is pressed and the power switch 35 is turned on.

When the power switch 35 is turned on, all switch operations are disabled, and only settings-related operations (for example, setting key 328 operation, setting switch 332 operation) are enabled, and settings cannot be changed. Processing will start and you will be in a state where you can change settings.

When the setting change process is started, a setting change in progress code indicating that the setting change process is in progress is displayed on the error notification monitor 336. Furthermore, after the power switch 35 is turned on, the display on the performance display monitor 334 switches from a light-off state to information indicating the set value.

In the setting change processing, backup clear processing, that is, initialization processing of the main RAM 103 (clearing the work area of the main RAM 103, notification of clearing of the work area of the main RAM 103, initial setting of the work area of the main RAM 103, commands at the time of RWM initialization) When the backup clearing process is executed, a sound indicating that the backup clearing process has been executed is output from the speaker 24. Note that, as will be described later, there is no display to the effect that the backup clear process has been executed, but instead of or in addition to the audio output from the speaker 24, the display area of the display device 16 indicates that the backup clear process has been executed. It may also be displayed in .

In the setting change process, each time the setting switch 332 is pressed, information indicating the setting value displayed on the performance display monitor 334 is displayed in a cyclical manner. That is, the information indicating the setting value increases by 1 each time the setting switch 332 is pressed when the setting value is "1" to "5", but the information indicating the setting value increases by 1 each time the setting switch 332 is pressed. When you press , the display returns to "1".

If the setting key 328 is turned off during the setting change process, the setting change state ends and the setting value displayed on the performance display monitor 334 is set. Further, the display on the error notification monitor 336 is changed from the setting changing code to the initialization code, the performance display (base value) is displayed on the performance display monitor 334, and the operations of all switches are enabled.

In this way, during the setting change process, only the settings-related operations (for example, operation of the setting key 328 and operation of the setting switch 332) among all the switches are enabled, and all other switches remain disabled. . Then, when the setting key 328 is turned off, all the switches are enabled.

[7-1-4-2. Flow of settings confirmation process]
Next, a description will be given of a setting confirmation process, that is, a flow for confirming the set setting values. The setting confirmation process is a process that is executed on the condition that the game permission flag is internally ON, and is not executed when the game permission flag is internally OFF.

To check the set value, on the condition that the internal game permission flag is ON, turn on the setting key 328 and turn on the backup clear switch 330 while the power is not turned on. Turn on the power switch 35 without pressing it.

When the power switch 35 is turned on, all switch operations are disabled, only the setting key 328 operation is enabled among all the switches, and the setting confirmation process is started, allowing the set settings to be confirmed. becomes.

When the setting confirmation process is started, a setting confirmation code indicating that the setting confirmation process is in progress is displayed on the error notification monitor 336. Furthermore, after the power switch 35 is turned on, the display on the performance display monitor 334 switches from a light-off state to information indicating the set value.

Note that during the setting confirmation process, even if the setting switch 332 is pressed, the information indicating the setting value displayed on the performance display monitor 334 does not change.

If you turn off the setting key 328 during the setting confirmation process, the setting confirmation state ends, the display on the error notification monitor 336 changes from the setting confirmation code to non-display, and the performance display monitor 334 shows the performance display (base value). will be displayed and all switch operations will be enabled.

In this way, during the setting confirmation process, only the setting key 328 among all the switches is enabled, and all other switches remain disabled. Therefore, setting switch 332 also remains disabled. Then, when the setting key 328 is turned off, all the switches are enabled. Note that, as described above, the setting confirmation process may be a process that can be executed during the normal game regardless of the operation of the power switch 35.

[7-1-4-3. Flow of abnormality processing]
As described above, when the game permission flag is internally OFF, although the setting change process can be executed, the setting confirmation process cannot be executed. Therefore, when the internal gaming permission flag is OFF, the operation to execute the setting change process (turning on the setting key 328 and pressing the backup clear switch 330 while the power is not turned on) is necessary. In addition, when an operation is performed to execute a setting confirmation process without turning on the power switch 35), when a backup process that does not involve a setting change process (details will be described later), or when simply If only the operation of turning on the power is performed, abnormality processing is executed. The flow of abnormality processing will be explained below.

After turning on the power switch 35, all switch operations are disabled, and only settings-related operations (for example, setting key 328 operation, setting switch 332 operation) are enabled (internal (In this case, abnormality processing will be started). The reason why operations related to settings are enabled is to enable the game permission flag to be turned on by executing the settings change process.

When the abnormality processing is started, an error code indicating that the game cannot be played is displayed on the error notification monitor 336. This allows the operator to confirm that the game cannot be played. Further, information indicating an error is displayed on the performance display monitor 334.

Furthermore, when abnormality processing is started, operations related to settings are also disabled. In other words, all switch operations are disabled. Therefore, once the abnormality process is started, no matter what operation is performed, the pachinko game will not respond, and unless the power switch 35 is turned OFF and the above setting change process is performed, the pachinko game will not be able to play the game. Machine 1 cannot be restored. Note that disabling the operation of all switches means that each device controlled by the sub-control circuit 200 is also completely stopped, making it impossible to play the game at all, and disabling each device controlled by some of the sub-control circuits 200 (e.g. The LEDs 25) include those that are in a controllable state.

[7-2. System timer interrupt processing]
FIG. 40 is a flowchart showing system timer interrupt processing by the main CPU 101. System timer interrupt processing is executed, for example, every 2 ms. As shown in the figure, the main CPU 101 saves the values of each register to the stack area of the main RAM 103 (step S51).

Next, the main CPU 101 performs a random number update process to update various random numbers (step S52).

Next, the main CPU 101 executes a switch input detection process to detect input signals from various switches (step S353. The switch input detection process will be described later with reference to FIG. 41).

Next, the main CPU 101 performs timer update processing to update the values of various timers (step S54).

Next, the main CPU 101 performs command output processing to output (send) various commands to the sub control circuit 200 (step S55).

Next, the main CPU 101 performs a game information output process of outputting (transmitting) various game information to the sub control circuit 200 (step S56). The game information is information related to the game that is processed in the main control circuit 100, the sub-control circuit 200, the payout/fire control circuit 300, etc., and is transmitted to the sub-control circuit 200, the payout/fire control circuit 300, and the hall computer 700. Ru.

Next, the main CPU 101 performs a process of restoring the saved values of each register (step S57). After completing this process, the main CPU 101 ends the system timer interrupt process.

[7-2-1. Switch input detection processing]
FIG. 41 is a flowchart showing switch input detection processing by the main CPU 101. The switch input detection process is called as a subroutine during execution of the system timer interrupt process described above. As shown in the figure, the main CPU 101 executes a starting opening winning detection process (step S61). The starting opening winning detection process will be described later with reference to FIG. 42.

Next, the main CPU 101 performs a general winning opening passage detection process (step S62). In the general winning hole passage detection process, payout information indicating the number of pieces to be paid out and the like is set when a winning is made to the general winning holes 53, 54, 55, and 56, for example.

Next, the main CPU 101 performs a large winning opening passage detection process (step S63). In the grand prize opening passage detection process, payout information indicating the number of pieces to be paid out and the like is set, for example, at the time of winning to the grand prize opening 540.

Next, the main CPU 101 performs a ball passage detector passage detection process (step S64). In the ball passage detector passage detection process, the lottery result of the normal symbol game ( Random value) is extracted. After completing this process, the main CPU 101 ends the switch input detection process.

[7-2-1-1. Starting opening winning detection processing]
FIG. 42 is a flowchart showing the starting opening winning detection process by the main CPU 101. The starting opening winning detection process is called as a subroutine during the execution of the switch input detection process described above. As shown in the figure, first, the main CPU 101 determines whether a game ball is detected by the first starting port switch 421 (step S71). When a game ball is detected by the first starting port switch 421 (YES in step S71), the main CPU 101 moves to the process of step S52. If the game ball is not detected by the first starting port switch 421 (NO in step S71), the main CPU 101 moves to the process of step S81.

In step S72, the main CPU 101 performs a setting check process. This setting check process will be described later.

In step S73, the main CPU 101 extracts various random numbers such as a jackpot determination random number and a symbol determination random number for the first special symbol, and performs a process of setting payout information according to the first starting opening winning.

Next, the main CPU 101 determines whether the number of pending winnings from the first starting opening (the number of pending first special symbols) is less than four (step S74). If the number of pending items is less than four (YES in step S74), the main CPU 101 moves to step S75. When the number of pending balls is 4 (NO in step S74), the main CPU 101 discards the various random numbers extracted based on the winning of the game ball to the first starting port 420, and moves to the process of step S80.

In step S75, the main CPU 101 performs a process of adding 1 to the number of pending winnings from the first starting opening.

Next, the main CPU 101 performs a process of storing various random numbers extracted based on the winning of the game ball into the first starting hole 420 in the main RAM 103 until the fluctuation start condition (starting condition) of the first special symbol is satisfied. (Step S76). As a result, the variable display of the first special symbol regarding the extracted random number is suspended until the starting condition is satisfied.

Next, the main CPU 101 performs a first special stop symbol determination process (step S77). In the first special stop symbol determination process, a jackpot random number determination table, a symbol determination table, and a jackpot type for the first special symbol are determined based on the random number value for jackpot determination and the random value for symbol determination extracted for the first special symbol. With reference to the table, a symbol designation command, a hit selection symbol command, etc. related to the main symbol (the first special symbol scheduled to be stopped and displayed) are determined.

Next, the main CPU 101 executes a variation pattern determination process (step S78). The fluctuation pattern determination process is called as a subroutine during the execution of the starting opening winning detection process described above. In addition, the main CPU 101 refers to the special symbol variation time determination table in FIG. 23 (or FIG. 25), and selects a variation pattern based on the jackpot determination result, the random number value for reach determination, and the random number value for performance selection. , perform the processing to determine.

Note that, as shown in FIGS. 23 and 25, since the fluctuation patterns are stored in association with the fluctuation display times of decorative symbols, the fluctuations corresponding to the fluctuation patterns determined in the above fluctuation pattern determination process are The pattern designation command essentially becomes information that can represent variation time.

Next, the main CPU 101 performs a process of setting a command to increase the number of pending winnings from the first starting opening (step S79). The command for increasing the number of pending winnings in the first starting opening is a command that indicates that the number of pending winnings in the first special symbol is increased by 1, and is sent to the sub-control circuit 200 together with the command that indicates the fluctuation pattern determined in the process of step S78. is sent.

In step S80, the main CPU 101 performs a process of setting a hold number overflow command for first starting opening winnings, and proceeds to step S81. The first starting opening winning number overflow command is a command that indicates that there is a first starting opening winning when the number of holding first special symbols is at the upper limit (for example, 4 pieces), and is sent to the sub control circuit 200. is sent.

As is clear from FIG. 42, the overflow command for the number of pending winnings from the first starting opening is sent to the sub-control circuit 200 when the setting value data is determined to be normal in the setting check process of step S72, which will be described later. The premise is that

In step S81, the main CPU 101 determines whether a game ball is detected by the second starting port switch 441 (step S81). When a game ball is detected by the second starting port switch 441 (YES in step S81), the main CPU 101 moves to the process of step S82. When the game ball is not detected by the second starting port switch 441 (NO in step S81), the main CPU 101 ends the starting port winning detection process.

In step S82, the main CPU 101 performs a setting check process. This setting check process will be described later, but is the same process as step S72.

In step S83, the main CPU 101 extracts various random numbers such as a jackpot determination random number and a symbol determination random number for the second special symbol, and performs a process of setting payout information according to the second starting opening winning.

Next, the main CPU 101 determines whether the number of pending winnings from the second starting opening (the number of pending second special symbols) is less than four (step S84). If the number of pending items is less than 4 (YES in step S84), the main CPU 101 moves to step S85. If the pending number is 4 (NO in step S84), the main CPU 101 discards the various random numbers extracted based on the winning of the game ball to the second starting hole 440, and ends the starting hole winning detection process.

In step S85, the main CPU 101 performs a process of adding 1 to the number of pending winnings from the second starting opening.

Next, the main CPU 101 performs a process of storing various random numbers extracted based on the winning of the game ball into the second starting port 440 in the main RAM 103 until the fluctuation start condition (starting condition) of the second special symbol is satisfied. (Step S86). As a result, the variable display of the second special symbol with respect to the extracted random number is suspended until the starting condition is satisfied.

Next, the main CPU 101 performs a second special stop symbol determination process (step S87). Similarly to the first special stop symbol determination process, the second special stop symbol determination process also uses the second special symbol based on the extracted jackpot determination random value and symbol determination random value extracted for the second special symbol. A symbol designation command, a jackpot selection symbol command, etc. related to the main symbol (second special symbol scheduled to be stopped and displayed) are determined by referring to the jackpot random number determination table, symbol determination table, and jackpot type determination table.

Next, the main CPU 101 executes a variation pattern determination process (step S88). Similar to step S78, this fluctuation pattern determination process is called as a subroutine during the execution of the starting opening winning detection process described above, and the main CPU 101 refers to the special symbol fluctuation time determination table in FIG. 23 (or FIG. 25). Then, as a result of the jackpot determination, a process is performed to select a variation pattern based on the random number value for reach determination and the random number value for performance selection.

Next, the main CPU 101 performs a process of setting a command to increase the number of pending winnings from the second starting opening (step S89). The command to increase the number of pending winnings in the second starting opening is a command that indicates that the number of pending winnings in the second special symbol is increased by 1, and is sent to the sub-control circuit 200 along with a command that indicates the fluctuation pattern determined in the process of step S88. is sent. When this process is completed, the main CPU 101 ends the starting opening winning detection process.

In addition, when the winning of a game ball to the first starting port 420 and the winning of a game ball to the second starting port 440 are detected at the same time, either the setting check process of step S72 or the setting check process of step S82 is performed. You may perform only one of them.

Further, in this embodiment, when a game ball is detected by the second starting port switch 441 (YES in step S81), it is assumed that the number of pending winnings in the second starting port is 4 (NO in step S84). Also, the main CPU 101 discards various random numbers extracted based on winnings of game balls to the second starting opening 440 and starts the game without transmitting the overflow command for the pending number of winnings to the second starting opening 440 to the sub-control circuit 200. The winning detection process has ended. This is because it is in the non-time-saving gaming state that the setting value suggestion effect, which will be described later, can be effectively performed.

[7-2-1-1-1. Settings check processing]
FIG. 43 is a flowchart showing an example of a setting check process by the main CPU 101, and this setting check process is the same process in step S72 and step S82 (both see FIG. 42). The setting check process is a process of checking whether the set setting values are normal. In this setting check process, for example, a process similar to the work area check of the RWM (main RAM 103) executed in step S1720 (see FIG. 32) may be performed, but in this embodiment, the set setting values are The emphasis is on checking whether it is normal or not.

As shown in the figure, the main CPU 101 first checks in step S721 whether the setting value data stored in the main RAM 103 is appropriate (for example, within a specified range). As described above, in this embodiment, since "0" to "5" are stored in the main RAM 103 as setting value data corresponding to setting values "1" to "6", here the setting value data is "0" to "5". It is determined whether or not the value is within the range of "0" to "5". If the setting value data is within the range of "0" to "5" (YES in step S721), the setting check process ends. If the set value data is outside the range of "0" to "5" (NO in step S721), the process moves to step S722.

In step S722, the main CPU 101 sets the game permission flag to OFF, and moves to step S723.

In step S723, the main CPU 101 determines whether or not the special symbol is being displayed in a variable manner. If the main CPU 101 determines that the special symbol is being displayed in a variable manner (YES in step S723), the process proceeds to step S724, and if the main CPU 101 determines that the special symbol is not in a variable display (NO in step S723), the process proceeds to step S725.

In step S724, the main CPU 101 prohibits the special symbols being displayed in a variable manner from stopping. That is, even if the special symbol variation time determined in step S78 or step S88 (both refer to FIG. 42) with reference to the special symbol variation time determination table shown in FIG. 23 (or FIG. 25) has elapsed, The special symbol continues to be displayed in a fluctuating manner, and the special symbol does not stop displaying. After that, the process moves to step S726.

For example, if a game ball enters the starting hole 420, 440 while the main CPU 101 is displaying a special symbol in a variable manner, a step will be taken during the variable display of the special symbol (before the variable display of the special symbol ends). The setting check process of S72 (or step S82) may be executed. If the main CPU 101 determines that it is not normal in this setting check process (NO in step S721), even if the special symbol is being displayed in a variable manner (the result of jackpot determination for the special symbol that is being displayed in a variable manner is not displayed). ), the game permission flag is turned OFF and abnormality processing is executed. In this case, the game cannot be played unless the power is turned off once and the setting change process is executed, so the jackpot determination result of the special symbol that is being displayed in a variable manner, including pending data, will be cleared in the backup clear process. The Rukoto.

In step S726, the main CPU 101 prohibits the shooting of game balls. That is, the dispensing/firing control circuit 300 (see FIG. 9) is controlled not to supply power to the firing solenoid (not shown). Therefore, even if the player grasps the firing handle 32 and rotates it clockwise, the game ball will not be fired, making it impossible to play the game.

When the main CPU 101 prohibits the firing of game balls in step S726, the main CPU 101 moves to abnormality processing in step S727.

In step S725, the main CPU 101 prohibits the variable display of the special symbol and prevents the next new variable display from starting. For example, even if the special symbol's fluctuating display is put on hold when the special symbol is not being fluctuated, or even if the special symbol's fluctuating display has stopped and you are waiting for the next fluctuating display to start, the special symbol's fluctuating display will start. Not done. When the main CPU 101 finishes the process of step S725, the process moves to step S726.

In the abnormality process in step S727, the main CPU 101 performs the same process as the abnormality process in step S38 (see FIG. 37). That is, the processes from step S381 to step S384 shown in FIG. 38 are performed until the power failure detection signal ON is detected, and when the power failure detection signal ON is detected, the power failure occurrence process of step S385, that is, the process shown in FIG. 39 are performed.

In this way, in the pachinko gaming machine 1 of this embodiment, the setting check process is performed when a game ball enters the first starting port 420 and when a game ball enters the second starting port 440, and the settings are stored in the main RAM 103. If the stored setting value data is not normal, execution of the game is prohibited. Therefore, even if the game is in progress, if the setting value data is not normal, it will be impossible to continue playing the game, and unless the power is turned off and then turned on again to change the settings, Unable to play games. As a result, it is possible to prevent, for example, a game from being played continuously in a state where the settings are not normal.

In addition, when the main CPU 101 determines that the set value data is not appropriate in step S721, even if the variable display of the special symbol has not yet started and is on hold, the main CPU 101 temporarily turns off the power and then turns the power back on as described above. Since the game cannot be played unless the game is inserted and the settings are changed, all of the various data related to the suspension stored in the main RAM 103 (for example, random numbers for jackpot determination, etc.) are cleared. In other words, regardless of whether the various types of data that are withheld are based on the winning of game balls in the first starting port 420 or the winning of game balls in the second starting port 440, all cleared. Thereby, it is possible to prevent the various data related to the above-mentioned suspension from being processed based on incorrect setting values, and it is possible to improve security.

Furthermore, as described above, the same setting check process is performed in step S72 and step S82 (both see FIG. 42). Therefore, when it is determined that the setting value data is not normal in the setting check process (step S72) performed when the game ball enters the first starting port 420 (NO in step S721), in step S724, the main CPU 101 prohibits the stopping of the second special symbol being displayed in a variable manner not only when the special symbol in the variable display is the first special symbol but also when it is the second special symbol. Similarly, when it is determined that the setting value data is not normal in the setting check process (step S82) performed when a game ball enters the second starting port 440 (NO in step S721), in step S724, The main CPU 101 prohibits stopping of the first special symbol that is being displayed in a variable manner not only when the special symbol that is being displayed in a variable manner is the second special symbol but also when it is the first special symbol.

Similarly, when it is determined that the setting value data is not normal in the setting check process (step S72) performed when a game ball enters the first starting port 420 (NO in step S721), in step S725 , the main CPU 101 prohibits the variable display of the second special symbol not only when the special symbol whose variable display is suspended is the first special symbol but also when it is the second special symbol. Similarly, when it is determined that the setting value data is not normal in the setting check process (step S82) performed when a game ball enters the second starting port 440 (NO in step S721), in step S725, The main CPU 101 prohibits the variable display of the first special symbol not only when the special symbol whose variable display is suspended is the second special symbol but also when it is the first special symbol.

Furthermore, in this embodiment, the setting check process is performed not only when the power is turned on (see step S1730 in FIG. 32) but also when a game ball enters the first starting port 420 or the second starting port 440. For example, the variable display of special symbols may start at the time of the setting confirmation process (see step S24 in FIG. 33), the setting change process (see step S26 in FIG. 33), or the execution of the backup clear process (see FIG. 35). When the fluctuation of the special symbol stops, when the passage is detected by the passage gate switch 49a (see FIG. 9), when the fluctuation of the normal symbol starts, when the fluctuation of the normal symbol stops, etc., the setting check process is executed at predetermined timings. You can do it as well. Note that the above predetermined timings are listed as examples. Further, the setting check process may be performed not only at a specific timing, but also at a plurality of timings (for example, all or some of the above timings). Even in such a case, for example, it is possible to prevent the game from being continued in a state where the settings are not normal.

Furthermore, in this embodiment, if it is determined in the setting check process that the setting value data is not normal, it is impossible to immediately turn off the game permission flag and proceed with the game, regardless of whether or not the jackpot game state is in progress. However, the present invention is not limited to this, and the timing at which it is determined that the setting value data is not normal in the setting check process may be shifted from the timing at which the execution of the game is made impossible. Thereby, it is possible to reduce the player's sense of loss that may occur due to the fact that the variable display is not performed even though the game ball has entered the first starting port 420 or the second starting port 440. However, since it is not preferable to perform various judgment processes (for example, jackpot judgment process, etc.) in a state where the set value data is not normal, various judgment processes are not performed, and after the special symbol is displayed fluctuating for a predetermined period of time, the corresponding It is preferable that the special symbol is stopped when the special symbol is lost.

Although not shown in FIG. 43, when the game permission flag is set to OFF in step S722, it is preferable that stopping of the normal symbol is also prohibited if the normal symbol is being displayed in a variable manner. . Further, when the normal symbols are not being displayed in a variable manner, it is preferable to prohibit the variable display of the normal symbols.

[7-3. Main control main processing]
FIG. 44 is a flowchart showing main control main processing by the main CPU 101. When the power is turned on to the pachinko gaming machine 1, the main CPU 101 performs initial setting processing as shown in the figure (step S91). In this process, the main CPU 101 performs processes such as the power-on process described above.

Next, the main CPU 101 performs an initial value random number update process (step S92). In this process, the main CPU 101 performs a process of updating the initial value random number counter.

Next, the main CPU 101 performs special symbol control processing (step S93). The special symbol control process will be described later with reference to FIG. 45.

Next, the main CPU 101 performs normal symbol control processing (step S94). The normal symbol control process will be described later with reference to FIG. 51.

Next, the main CPU 101 performs symbol display section control processing (step S95). In this process, the main CPU 101 controls the special symbol display section (first special symbol display section 73, A process is performed in which control signals for driving the second special symbol display section 74) and the normal symbol display section 71 are stored in the main RAM 103. As a result, the main CPU 101 sends a control signal to the special symbol display section (first special symbol display section 73, second special symbol display section 74) and normal symbol display section 71, The display section 73, second special symbol display section 74) and normal symbol display section 71 perform variable display and stop display of special symbols and normal symbols based on the received control signals.

Next, the main CPU 101 performs game information data generation processing (step S96). In this process, the main CPU 101 generates a gaming state command regarding gaming information data to be transmitted to the sub control circuit 200, the payout/fire control circuit 300, and the hall computer 700, and stores it in the main RAM 103.

Next, the main CPU 101 performs storage/gaming state data generation processing (step S97). In this process, the main CPU 101 generates storage/gaming status data to be transmitted to the sub-control circuit 200 based on the value of the probability change flag and the value of the time saving flag, and stores the storage/gaming status data in the main RAM 103. After completing this process, the main CPU 101 returns to the process of step S92.

[7-3-1. Special symbol control processing]
FIG. 45 is a flowchart showing special symbol control processing by the main CPU 101. The special symbol control process is called as a subroutine during execution of the main control main process mentioned above. Note that the numerical values (“00” to “08”) written in parentheses to the left of each process shown in the figure indicate the value of the control state flag. This control state flag is stored in a predetermined storage area within the main RAM 103. The main CPU 101 advances the special symbol game by executing processing according to the numerical value of the control state flag.

As shown in FIG. 45, the main CPU 101 performs a process of loading a control state flag (step S101). In this process, the main CPU 101 reads the value of the control state flag stored in the main RAM 103. The main CPU 101 determines whether to execute each process of steps S102 to S110, which will be described later, based on the value of the read control state flag. This control state flag indicates the state of the special symbol game, and enables execution of any one of steps S102 to S110. Further, the main CPU 101 executes each process at a predetermined timing determined according to the waiting time set for each process of steps S102 to S110. Note that before this predetermined timing is reached, each process is not executed, and processes related to other subroutines are executed. Of course, the aforementioned system timer interrupt processing (see FIG. 40) is also executed at predetermined intervals.

Next, the main CPU 101 performs a special symbol storage check process (step S102). In this process, the main CPU 101 checks the pending number of special symbol fluctuation displays when the control status flag is a value indicating special symbol memory check processing ("00"), and if the pending number is not "0" (If there is a reserved ball), the jackpot determination result obtained in the starting opening winning detection process, the determination result of the main symbol, the determination result of the special symbol variation pattern, etc. are obtained. In addition, in this process, the main CPU 101 sets the control state flag to a value ("01") indicating the special symbol variable display time management process (step S93), which will be described later, and uses the variable pattern acquired in the current process. Set the variable display time of the corresponding special symbol in the waiting time timer. That is, after the special symbol fluctuation display time corresponding to the fluctuation pattern determined in the starting opening winning detection processing has elapsed, the special symbol fluctuation time management processing to be described later is set to be executed. On the other hand, when the number of balls on hold is "0" (when there are no balls on hold), the main CPU 101 performs a demo display process to display a demo screen. This special symbol memory check process will be described in detail with reference to FIG. 46.

Next, the main CPU 101 performs special symbol variation time management processing (step S103). In this process, the main CPU 101 sets the control state flag to a special symbol, which will be described later, when the control state flag has a value ("01") indicating special symbol variation time management processing and the special symbol variation display time has elapsed. A value ("02") indicating the display time management process (step S104) is set, and the waiting time after confirmation is set in the waiting time timer. That is, after the post-confirmation waiting time set in the process of step S103 has elapsed, the special symbol display time management process to be described later is set to be executed.

Next, the main CPU 101 performs special symbol display time management processing (step S104). In this process, the main CPU 101 determines whether the jackpot is determined if the control status flag is a value ("02") indicating the special symbol display time management process and the post-confirmation waiting time set in the process of step S103 has elapsed. Determine whether the result is a "jackpot" or not. Then, when the result of the jackpot determination is "jackpot", the main CPU 101 sets the control state flag to a value ("03") indicating jackpot start interval management processing (step S105), which will be described later, and sets the jackpot start interval to "03". Set the corresponding time in the waiting time timer. That is, after the time corresponding to the jackpot start interval set in the process of step S104 has elapsed, the jackpot start interval management process to be described later is set to be executed. On the other hand, if the result of the jackpot determination is not a "jackpot", the main CPU 101 sets the control state flag to a value ("08") indicating a special symbol game ending process (step S110), which will be described later. That is, in this case, the special symbol game ending process described later is set to be executed. This special symbol display time management process will be described later with reference to FIG. 47.

Next, the main CPU 101 performs jackpot start interval management processing (step S105). In this process, the main CPU 101 determines whether the control status flag is a value ("03") indicating jackpot start interval management processing and if the time corresponding to the jackpot start interval set in the process of step S104 has elapsed, In order to open the winning hole 540, variables located in the main RAM 103 are updated based on the data read from the main ROM 102. In addition, in this process, the main CPU 101 sets a value (“04”) indicating the later-described big winning hole opening process (step S106) in the control state flag, and also sets the opening upper limit time of the big winning hole 540 (e.g. 30 seconds) to the grand prize opening opening time timer. That is, by this process, the later-described big winning hole opening process is set to be executed.

Next, the main CPU 101 performs a big winning hole opening process (step S106). In this process, first, the main CPU 101 sets the condition that when the control state flag is a value ("04") indicating the process of opening the big winning opening, the winning opening counter is equal to or more than a predetermined number, and It is determined whether one of the conditions that the upper limit time has elapsed (the grand winning opening opening time timer is "0") is satisfied (a predetermined closing condition is satisfied). If one of the conditions is met, the main CPU 101 updates the variables located in the main RAM 103 in order to close the big prize opening 540. Then, the main CPU 101 sets a value (“05”) indicating a residual ball monitoring process in the big winning opening (step S107) to the control state flag, which will be described later, and sets a waiting time timer to the monitoring time for remaining balls in the big winning opening. do. That is, by this process, after the big winning hole remaining ball monitoring time set in step S107 has elapsed, the later-described big winning hole remaining ball monitoring process is set to be executed. In addition, immediately before the end of this big winning hole opening process, an inter-round display command is transmitted to the sub-control circuit 200.

Next, the main CPU 101 performs a residual ball monitoring process in the big winning hole (step S107). In this process, the main CPU 101 controls the number of times the grand prize opening counter is set when the control status flag is a value ("05") indicating the process of monitoring remaining balls in the grand prize opening and the remaining ball monitoring time in the grand prize opening has elapsed. It is determined whether the condition that the value is greater than or equal to the maximum value of the number of openings of the big prize opening (this is the final round) is satisfied. If it is determined that the above conditions are not met, the main CPU 101 sets a value (“06”) indicating the grand prize opening re-opening waiting time management process in the control state flag. Further, the main CPU 101 sets a time corresponding to the inter-round interval in a waiting time timer. That is, by this process, after the time corresponding to the interval between rounds has elapsed, the waiting time management process before the re-opening of the big winning hole, which will be described later, is set to be executed. On the other hand, if it is determined in step S107 that the above conditions are met, the main CPU 101 sets a value ("07") indicating jackpot end interval processing in the control state flag, and sets the time corresponding to the jackpot end interval (jackpot end interval time) in the waiting time timer. That is, after the time corresponding to the jackpot end interval set in this process has elapsed, the jackpot end interval process described below is set to be executed.

Next, when the main CPU 101 determines that the value of the grand prize opening number counter is not equal to or greater than the maximum value of the number of grand prize openings, the main CPU 101 performs a waiting time management process before the grand prize opening is re-opened (step S108). In this process, the main CPU 101 opens the big winning hole when the control status flag is a value ("06") indicating the waiting time management process before the big winning hole is re-opened, and the time corresponding to the interval between rounds has elapsed. The memory is updated so that the value of the number of times counter is incremented by "1". Further, the main CPU 101 sets a value (“04”) indicating the big winning hole opening process to the control state flag. Then, the main CPU 101 sets the opening upper limit time (for example, 30 seconds) to the big winning opening opening time timer. That is, in this process, the above-described big winning hole opening process (step S106) is set to be executed again. In addition, just before the end of the waiting time management process before the grand prize opening is re-opened, a grand prize opening display command is transmitted to the sub-control circuit 200.

Further, when the main CPU 101 determines that the value of the number of times the big winning hole is opened is equal to or greater than the maximum value of the number of times the big winning hole is opened, the main CPU 101 performs the jackpot end interval process (step S109). In this process, the main CPU 101 sets the control state flag to a value ("07") indicating jackpot end interval processing, and when the time corresponding to the jackpot end interval has elapsed, the main CPU 101 sets a value ("07") indicating special symbol game end processing. 08'') is set in the control status flag. That is, by this process, the special symbol game ending process, which will be described later, is set to be executed after the process of step S109. In addition, when the above-mentioned main symbol is any of the special symbols 1-2, 1-8, and 2-2, the main CPU 101 performs control to shift the gaming state to a high probability gaming state. , If the above-mentioned main symbol is any of the special symbols 1-1, 1-3, and 2-1, control is performed to set the gaming state to a low probability gaming state (probability variable flag OFF). conduct.

Next, the main CPU 101 performs a special symbol game ending process when the jackpot gaming state ends or when the result of the jackpot determination is "lose" (step S110). In this process, the main CPU 101 updates the memory so that when the control state flag has a value ("08") indicating special symbol game end processing, the data indicating the number of pending symbols (starting memory information) is decreased by "1". do. In addition, the main CPU 101 updates the special symbol storage area in order to display the next special symbol in a variable manner. Further, the main CPU 101 sets a value (“00”) indicating special symbol storage check processing to the control state flag. That is, by this process, the above-mentioned special symbol memory check process (step S102) is set to be executed after the process of step S110. When this special symbol game ending process ends, the main CPU 101 ends the special symbol control process.

As described above, in the pachinko game machine 1 of this embodiment, the special symbol game is advanced by sequentially setting various values in the control state flag. Specifically, when the gaming state is not a jackpot gaming state and the result of jackpot determination is "loss", the main CPU 101 sets the control state flag to "00", "01", "02", or "08". Set in order. As a result, the main CPU 101 performs the above-described special symbol memory check process (step S102), special symbol fluctuation time management process (step S103), special symbol display time management process (step S104), and special symbol game end process (step S110). are executed in this order at a predetermined timing.

In addition, if the gaming state is not a jackpot gaming state and the result of jackpot determination is "jackpot", the main CPU 101 sets the control state flag in the order of "00", "01", "02", and "03". do. As a result, the main CPU 101 performs the above-described special symbol memory check process (step S102), special symbol fluctuation time management process (step S103), special symbol display time management process (step S104), and jackpot start interval management process (step S105). are executed in this order at a predetermined timing to control the transition to the jackpot gaming state.

Furthermore, when the transition control to the jackpot gaming state is executed, the main CPU 101 sets the control state flags in the order of "04", "05", and "06". As a result, the main CPU 101 executes the above-mentioned process during opening of the grand prize opening (step S106), residual ball monitoring process in the grand prize opening (step S107), and waiting time management process before re-opening of the grand prize opening (step S108) in this order. It is executed at a predetermined timing to execute a jackpot game state.

Note that when the termination condition of the jackpot gaming state is satisfied during the jackpot gaming state, the main CPU 101 sets the control state flags in the order of "04", "05", "07", and "08". As a result, the main CPU 101 performs the above-described big winning hole opening process (step S106), remaining ball monitoring process in the big winning hole (step S107), jackpot end interval process (step S109), and special symbol game ending process (step S110). are executed in this order at a predetermined timing, and the jackpot game state is ended.

As mentioned above, in the special symbol control process, the process flow is branched depending on the status. In addition, the normal symbol control process (see FIG. 51 described later) in step S94 during the main control main process shown in FIG. 44 also branches the processing flow depending on the status, similar to the special symbol control process.

The processing program of this embodiment is programmed so that pure return processing from a small module to a parent module can be performed using a call instruction when processing is branched according to the status. As a result, in this embodiment, the capacity of the program can be reduced compared to the case where a jump table is arranged to execute the above processing.

[7-3-1-1. Special symbol memory check process]
FIG. 46 is a flowchart showing special symbol storage check processing by the main CPU 101. The special symbol storage check process is called as a subroutine during execution of the special symbol control process described above. As shown in the figure, first, the main CPU 101 reads the control state flag from a predetermined storage area in the main RAM 103 by a load process (step S111).

Next, the main CPU 101 determines whether the read control state flag is a value ("00") indicating special symbol storage check processing (step S112). If it is determined that the control state flag is not "00" (NO in step S112), the main CPU 101 ends the special symbol memory check process. On the other hand, if it is determined that the control state flag is "00" (YES in step S112), the main CPU 101 moves to the process of step S113.

In step S113, the main CPU 101 determines whether the pending number (second starting memory number) of second starting opening winnings (fluctuating display of second special symbols) is "0". If the main CPU 101 determines that the number of pending winnings from the second starting opening is "0" (YES in step S113), the process proceeds to step S114, and if the number of pending winnings from the second starting opening is not "0" If it is determined (NO in step S113), the process moves to step S121.

In step S114, the main CPU 101 determines whether the pending number (first starting memory number) of the first starting opening winnings (fluctuating display of the first special symbol) is "0". If the main CPU 101 determines that the number of pending winnings from the first starting opening is not "0" (NO in step S114), the process proceeds to step S115, and if the number of pending winnings from the first starting opening is "0". If it is determined (YES in step S114), the process moves to step S120.

In step S115, the main CPU 101 subtracts "1" from the value of the first starting memory number corresponding to the pending number of winnings from the first starting opening. In this embodiment, the main CPU 101 determines whether data is stored in the first special symbol starting storage area (0) to the first special symbol starting storage area (4) provided in the main RAM 103, and It is determined whether or not there is a memory for starting a special symbol game corresponding to the variable display of the first special symbol that is being displayed in a variable manner or is on hold. The data (information) of the special symbol game corresponding to the variable display of the first special symbol during the variable display is stored in the first special symbol starting storage area (0) as starting memory information. The first special symbol starting memory area (1) to the first special symbol starting memory area (4) are stored in the special symbol game corresponding to the four pending first special symbol variable displays (holding balls). data (information) is stored as starting storage information. The starting memory information of each first special symbol starting memory area includes, for example, data indicating a random number value for jackpot determination, a random number value for symbol determination, a determined fluctuation pattern, etc. extracted at the time of winning in the first starting hole 420. is included.

Next, in step S116, the main CPU 101 performs a special symbol storage transfer process based on the first starting slot winning. In this process, the main CPU 101 shifts the data of the first special symbol starting storage areas (1) to (4) to the first special symbol starting storage areas (0) to (3), respectively. At this time, the main CPU 101 also transmits a pending subtraction command to the sub control circuit 200. After that, the main CPU 101 moves to the process of step S117.

In step S117, the main CPU 101 performs a process of setting the control state flag to a value ("01") indicating special symbol variation time management processing. At this time, the main CPU 101 also transmits a special symbol presentation start command to the sub control circuit 200.

In step S118, the main CPU 101 performs jackpot determination processing. In this process, the main CPU 101 uses the random number value for jackpot determination extracted at the time of winning the starting slot and previously set in the first special symbol starting storage area (0) or the second special symbol starting storage area (0). Based on this, a jackpot determination table (not shown) corresponding to the type of winning start opening is referred to to obtain determination value data. Then, the main CPU 101 determines whether it is a "jackpot" or a "loss" (jackpot determination) based on the acquired determination value data.

Next, in step S119, the main CPU 101 sets a waiting time timer to a variation display time corresponding to the variation pattern of the special symbol determined in the variation pattern determination process of step S78 or step S88 (see FIG. 42). . When this process is completed, the main CPU 101 ends the special symbol memory check process.

Further, in step S120, the main CPU 101 performs a demo display process to display a demo screen. In this process, the main CPU 101 transmits a demonstration display command to the sub control circuit 200. When this process is completed, the main CPU 101 ends the special symbol memory check process.

Further, in step S121, the main CPU 101 subtracts "1" from the value of the second starting memory number corresponding to the pending number of winnings from the second starting opening. In this embodiment, the main CPU 101 determines whether data is stored in the second special symbol starting storage area (0) to the second special symbol starting storage area (4) provided in the main RAM 103, and It is determined whether there is a memory for starting a special symbol game corresponding to the variable display of the second special symbol that is being displayed in a variable manner or is on hold. In the second special symbol start storage area (0), data (information) of the special symbol game corresponding to the variable display of the second special symbol during the variable display is stored as start memory information. Then, the second special symbol starting storage area (1) to the second special symbol starting storage area (4) are stored in the special symbol game corresponding to the variable display of the second special symbol for the four times held (holding ball). data (information) is stored as starting storage information. The starting memory information in each second special symbol starting storage area includes, for example, data indicating random numbers for jackpot determination, random numbers for symbol determination, and determined fluctuation patterns extracted at the time of winning in the second starting opening 440. is included.

Next, the main CPU 101 performs a special symbol storage transfer process based on the second starting opening winning prize (step S122). In this process, the main CPU 101 shifts the data of the second special symbol starting storage areas (1) to (4) to the second special symbol starting storage areas (0) to (3), respectively. At this time, the main CPU 101 also transmits a pending subtraction command to the sub control circuit 200. After that, the main CPU 101 moves to the process of step S117, executes the processes of step S118 and step S119, and then ends the special symbol memory check process.

[7-3-2. Special symbol display time management processing]
FIG. 47 is a flowchart showing special symbol display time management processing by the main CPU 101. The special symbol display time management process is called as a subroutine during execution of the special symbol control process described above. As shown in the figure, the main CPU 101 determines whether the control state flag is a value ("02") indicating special symbol display time management processing (step S131). When it is determined that the control state flag is not a value ("02") indicating the special symbol display time management process (NO in step S131), the main CPU 101 ends the special symbol display time management process. On the other hand, when it is determined that the control state flag is a value ("02") indicating special symbol display time management processing (YES in step S131), the main CPU 101 moves to processing in step S132.

In step S132, the main CPU 101 determines whether the value of the waiting time timer (waiting time) is "0". In this process, the main CPU 101 determines whether or not the waiting time after the fluctuation display is confirmed (the fluctuation display start waiting time) set in the waiting time timer has expired. If it is determined that the value of the waiting time timer is not "0" (NO in step S132), the main CPU 101 ends the special symbol display time management process. On the other hand, if it is determined that the value of the waiting time timer is "0" (YES in step S132), the main CPU 101 moves to the process of step S133.

In step S133, the main CPU 101 determines whether or not the special symbol game is a "jackpot". When it is determined that the special symbol game is a "jackpot" (YES in step S133), the main CPU 101 moves to the process of step S134. On the other hand, if it is determined that the special symbol game is not a "jackpot" (NO in step S133), the main CPU 101 moves to the process of step S140.

In step S134, the main CPU 101 performs processing to set a jackpot flag indicating a jackpot. After finishing this process, the main CPU 101 moves to the process of step S135.

In step S135, the main CPU 101 performs processing to clear the time saving number counter, the time saving flag, and the probability change flag. After completing this process, the main CPU 101 moves on to the process of step S136.

In step S136, the main CPU 101 performs a process of setting the control state flag to a value ("03") indicating the jackpot start interval management process.

Next, the main CPU 101 performs a process of setting the jackpot start interval time (for example, 5000 ms) corresponding to the special symbol (first special symbol or second special symbol) in the waiting time timer (step S137).

Next, the main CPU 101 performs a process of setting a jackpot start command corresponding to the special symbol in the main RAM 103 (step S138). As a result, a jackpot start command is transmitted to the sub-control circuit 200.

Next, the main CPU 101 refers to the jackpot type determination table (see FIG. 22, FIG. 26, or FIG. 27), and determines the round number upper limit (big winning hole opening number upper limit) corresponding to the special symbol (type of symbol designation command). ) is set in the main RAM 103, and a round number display LED pattern flag is set (step S139). Note that the round number display LED pattern flag is a flag indicating whether or not to display the remaining round number in a predetermined pattern. When this process is completed, the main CPU 101 ends the special symbol display time management process.

In step S140, the main CPU 101 performs time saving count subtraction processing. This time saving number subtraction process will be described later with reference to FIG. 48.

Next, the main CPU 101 performs a process of setting the control state flag to a value ("08") indicating special symbol game end processing (step S141). When this process is completed, the main CPU 101 ends the special symbol display time management process.

[7-3-2-1. Time saving number subtraction process]
FIG. 48 is a flowchart showing the time saving frequency subtraction process performed by the main CPU 101. The time saving number subtraction process is called as a subroutine during execution of the special symbol display time management process described above or the jackpot end interval process described later. As shown in the figure, the main CPU 101 determines whether the value of the time saving number counter is 0 or not (step S151). The time saving number counter is a subtraction counter that counts until the set time saving number becomes 0. When the value of the time saving number counter is 0 (YES in step S151), the main CPU 101 moves to the process of step S154. If the value of the time saving number counter is not 0 (NO in step S151), the main CPU 101 ends the time saving number subtraction process. Although the details will be described later, in this embodiment, the number of times set as the time saving number counter is 100 times or 10,000 times.

In step S152, the main CPU 101 performs a process of subtracting 1 from the value of the time saving counter.

Next, the main CPU 101 again determines whether the value of the time saving number counter is 0 (step S153). If the value of the time saving number counter is 0 (YES in step S153), the main CPU 101 moves to the process of step S154. If the value of the time saving number counter is not 0 (NO in step S153), the main CPU 101 ends the time saving number subtraction process.

In step S154, the main CPU 101 performs processing to set the time saving flag to "0". When this process is completed, the main CPU 101 ends the time saving number subtraction process.

[7-3-3. Jackpot end interval processing]
FIG. 49 is a flowchart showing the jackpot end interval process by the main CPU 101. The jackpot end interval process is called as a subroutine during execution of the special symbol control process described above. As shown in the figure, the main CPU 101 determines whether the control state flag is a value ("07") indicating the jackpot end interval process (step S161). If it is determined that the control state flag is not a value (“07”) indicating the jackpot end interval process (NO in step S161), the main CPU 101 ends the jackpot end interval process. On the other hand, when it is determined that the control state flag is a value ("07") indicating the jackpot end interval process (YES in step S161), the main CPU 101 moves to the process of step S162.

In step S162, the main CPU 101 determines whether the value of the waiting time timer is "0". In this process, the main CPU 101 determines whether or not the jackpot end interval time set in the waiting time timer has expired. If it is determined that the value of the waiting time timer is not "0" (NO in step S161), the main CPU 101 ends the jackpot end interval process. On the other hand, if it is determined that the value of the waiting time timer is "0" (YES in step S161), the main CPU 101 moves to the process of step S163.

In step S163, the main CPU 101 clears the LED pattern flag indicating the number of openings of the big winning opening. The big winning opening number display LED pattern flag is used as a management flag indicating whether or not the number of rounds at the time of a jackpot is displayed by an LED light emitting pattern.

Next, the main CPU 101 clears the round number distribution flag (step S164). This round number allocation flag is one of the management flags stored in the main RAM 103, and is used to indicate whether or not to periodically open and close the grand prize opening 540 a predetermined number of times even during one round. This is the flag. If the big prize opening 540 is opened and closed periodically even during one round, the round number distribution flag becomes "1". At this time, the main CPU 101 also transmits a special symbol jackpot end display command to the sub control circuit 200.

Next, the main CPU 101 performs a process of setting the control state flag to a value ("08") indicating special symbol game end processing (step S165).

Next, the main CPU 101 determines whether or not the special symbol game is a "jackpot" (step S166). If it is determined that the special symbol game is a "jackpot" (YES in step S166), the main CPU 101 moves to the process of step S167. On the other hand, if it is determined that the special symbol game is not a "jackpot" (NO in step S166), the main CPU 101 moves to the process of step S174.

In step S167, the main CPU 101 performs processing to set a jackpot flag in a predetermined area of the main RAM 34 to ON.

Next, the main CPU 101 determines whether or not it is a probability variable jackpot (step S168). If it is a probability variable jackpot (YES in step S168), the main CPU 101 moves to the process of step S169. If it is not a probability variable jackpot (NO in step S168), the main CPU 101 moves to the process of step S171.

In step S169, the main CPU 101 performs processing to set the probability change flag to "1".

Next, the main CPU 101 performs a process of setting the time saving flag to "1" (step S171).

Next, the main CPU 101 performs a process of setting a prescribed number of time reductions in the time reduction number counter (step S172). In this embodiment, with reference to the jackpot type determination table (FIG. 22, FIG. 26, or FIG. etc.), the time saving number counter is set to 100 times, and the time saving continues until the next jackpot game state is executed. etc.), set the time saving number counter to 10,000 times. However, the time saving number counter that is set when the time saving continues until the next jackpot game state is executed is not limited to 10,000 times, and even if the game continues from the opening of the hall to the closing. It is fine as long as it is a number of times that cannot realistically occur. In this way, by setting the time saving number counter to a number of times that would not realistically occur even if the game continues from opening to closing of the hall, time saving will continue until the next jackpot game state is executed. I will do it. Furthermore, if it is a jackpot with 100 times of time saving, it performs counter processing (sets 100 times in the time saving number counter), and if it is a jackpot that will continue to save time until the next jackpot game state is executed, flag processing is performed. (The time-saving gaming state may be continued as long as the time-saving flag is ON).

Next, the main CPU 101 executes a variation pattern table setting process (step S173). The variation pattern table setting process will be described later with reference to FIG. 50. When this process is completed, the main CPU 101 ends the jackpot end interval process.

In step S174, the main CPU 101 performs processing to clear the jackpot flag, that is, processing to set the jackpot flag set to ON in a predetermined area of the main RAM 34 to OFF.

In step S175, the main CPU 101 executes the above-described time saving frequency subtraction process (step S175). When this process is completed, the main CPU 101 ends the jackpot end interval process.

[7-3-3-1. Fluctuation pattern table setting process]
FIG. 50 is a flowchart showing the variation pattern table setting process by the main CPU 101. The fluctuation pattern table setting process is called as a subroutine during the power-on process or the jackpot end interval process described above. As shown in the figure, the main CPU 101 determines whether or not the power is turned on (step S181). When the power is turned on (YES in step S181), the main CPU 101 moves to processing in step S182. If the power is not turned on (NO in step S181), the main CPU 101 moves to step S183.

In step S182, the main CPU 101 performs a process of setting table pattern 1 as a table pattern when referring to the special symbol variation time determination table shown in FIG. 23 (or FIG. 25). Table pattern 1 corresponds to the table pattern when both the probability variation flag and the time saving flag are ON (both jackpot and loss) in the special symbol variation time determination table shown in FIG. 23 (or FIG. 25). .

Next, the main CPU 101 determines whether the time saving flag is ON (step S183). If the time saving flag is ON (YES in step S183), the main CPU 101 moves to the process of step S184. If the time saving flag is OFF (NO in step S183), the main CPU 101 moves to the process of step S185.

In step S184, the main CPU 101 performs a process of setting table pattern 2 as a table pattern when referring to the special symbol variation time determination table shown in FIG. 23 (or FIG. 25). After completing this process, the main CPU 101 ends the variation pattern table setting process. Table pattern 2 corresponds to the table pattern when the time saving flag is OFF (both jackpot and loss) in the special symbol variation time determination table shown in FIG. 23 (or FIG. 25).

In step S185, the main CPU 101 performs a process of setting table pattern 3 as a table pattern when referring to the special symbol variation time determination table shown in FIG. 23 (or FIG. 25). After completing this process, the main CPU 101 ends the variation pattern table setting process. Table pattern 3 corresponds to the table pattern when the time saving flag is ON (both jackpot and loss) in the special symbol variation time determination table shown in FIG. 23 (or FIG. 25).

[7-4. Normal symbol control processing]
FIG. 51 is a flowchart showing normal symbol control processing by the main CPU 101. The normal symbol control process is called as a subroutine during the execution of the main control main process described above. In addition, the numerical values (“00” to “04”) written in parentheses to the right of each process in the flowchart shown in FIG. 51 indicate the normal symbol control state flag, and this normal symbol control state flag is is stored in a predetermined storage area within. The main CPU 101 advances the normal symbol game by executing each process corresponding to the numerical value of the normal symbol control state flag.

As shown in FIG. 51, the main CPU 101 performs a process of loading the normal symbol control state flag (step S191). In this process, the main CPU 101 reads the normal symbol control state flag stored in the main RAM 103. The main CPU 101 determines whether to execute various processes of steps S192 to S196, which will be described later, based on the read value of the normal symbol control state flag. This normal symbol control state flag indicates the gaming state of the normal symbol game, and enables execution of any one of steps S162 to S166. Further, the main CPU 101 executes each process at a predetermined timing determined according to the waiting time set for each process of steps S162 to S166. Note that before this predetermined timing is reached, other subroutine processes are executed without executing each process. Of course, the aforementioned system timer interrupt processing (see FIG. 40) is also executed at predetermined intervals.

Next, the main CPU 101 performs a normal symbol memory check process (step S192). In this process, when the normal symbol control state flag is a value indicating normal symbol memory check processing ("00"), the main CPU 101 checks the number of pending symbols in the fluctuating display of normal symbols, and if the pending number is "0". If not, processing such as jackpot determination is performed. In addition, in this process, the main CPU 101 sets the normal symbol control state flag to a value ("01") indicating the normal symbol fluctuation time monitoring process (step S193), which will be described later, and sets the fluctuation time determined in this process to Set the wait time timer. That is, by the process of step S192, after the determined normal symbol variation time has elapsed, the normal symbol variation time monitoring process, which will be described later, is set to be executed.

Next, the main CPU 101 performs normal symbol fluctuation time monitoring processing (step S193). In this process, the main CPU 101 sets the normal symbol control state flag to a value ("01") indicating the normal symbol fluctuation time monitoring process, and when the normal symbol fluctuation time has elapsed, the normal symbol control state flag is set to the normal symbol control state flag. A value ("02") indicating the normal symbol display time monitoring process (step S194) is set, and a waiting time after confirmation (for example, 0.5 seconds) is set in the waiting time timer. That is, by the process of step S193, after the set post-confirmation waiting time has elapsed, the normal symbol display time monitoring process to be described later is set to be executed.

Next, the main CPU 101 performs normal symbol display time monitoring processing (step S194). In this process, the main CPU 101 determines that if the normal symbol control state flag is a value ("02") indicating the normal symbol display time monitoring process and the post-confirmation waiting time set in the process of step S193 has elapsed, the jackpot is determined. It is determined whether the result of the determination is a "big hit" or not. Then, when the result of the jackpot determination is "jackpot", the main CPU 101 performs a normal electric accessory release setting process, and sets the normal symbol control state flag to a value ( "03"). That is, through this process, the normal electric accessory opening process described below is set to be executed. On the other hand, if the result of the jackpot determination is not a "jackpot", the main CPU 101 sets the normal symbol control state flag to a value ("04") indicating a normal symbol game end process (step S195), which will be described later. That is, in this case, the normal symbol game ending process described below is set to be executed.

Next, if the result of the jackpot determination is determined to be a "jackpot" in step S194, the main CPU 101 performs a normal electric accessory release process (step S195). In this process, the main CPU 101 determines that a predetermined number of prizes have been won while the normal electric accessory 460 is being released when the normal symbol control state flag is a value (“03”) indicating the normal electric accessory opening process. It is determined whether one of the conditions and the condition that the upper limit opening time of the normal electric accessory 460 has elapsed (the ordinary electric accessory opening time timer is "0") is satisfied. When one of the above conditions is satisfied, the main CPU 101 updates the variables located in the main RAM 103 in order to bring the blade member 4620 (see FIG. 5, for example) of the normal electric accessory 460 into the closed state. Then, the main CPU 101 sets the normal symbol control state flag to a value (“04”) indicating a normal symbol game end process (step S196), which will be described later. That is, through this process, the normal symbol game ending process described below is set to be executed.

Next, the main CPU 101 performs normal symbol game end processing (step S196). In this process, the main CPU 101 decreases the data indicating the pending number of fluctuating displays of normal symbols by "1" when the normal symbol control state flag has a value ("04") indicating normal symbol game end processing. Update the memory. Further, the main CPU 101 updates the normal symbol storage area in order to perform the next variable display of the normal symbols. Further, the main CPU 101 sets the normal symbol control state flag to a value (“00”) indicating the normal symbol memory check process. That is, after the process of step S196, the above-described normal symbol memory check process (step S192) is set to be executed. When this process is finished, the main CPU 101 ends the normal symbol control process.

[8. Sub control main processing]
On the other hand, the sub control circuit 200 (host control circuit 2100) including the sub CPU processor executes sub control main processing. This sub-control main processing will be explained using FIG. 52. FIG. 52 is a flowchart showing an example of main sub-control, and this process is started when the power is turned on. Note that FIGS. 61, 72, 73, 74, and 98, which will be described later, are also flowcharts showing examples of sub-control main processing executed by the host control circuit 2100 when the power is turned on. However, FIG. 52 is one typical example.
It is processing.

As shown in FIG. 52, the host control circuit 2100 performs initialization processing such as RAM access permission, work area initialization, hardware initialization, device initialization, application initialization, and backup recovery initialization (step S201). ).

Next, the host control circuit 2100 performs processing to clear the counter value of the watchdog timer (step S202). A reset time (for example, 2000 ms) is set for the watchdog timer when it is started, and a power-off process is executed when a service pulse is not written (at time-out).

Next, the host control circuit 2100 executes operation means input processing (step S203).

Next, the host control circuit 2100 executes command analysis processing (step S204). The command analysis process will be described later with reference to FIG. 53.

Next, the host control circuit 2100 executes production mode determination processing (step S205). The performance mode determination process is a process for determining the performance mode displayed on the display device 16 based on various commands transmitted from the main control circuit 100.

The presentation mode determined in the above presentation mode determination process (step S205) also includes a setting suggestion presentation that suggests the set setting value. This setting suggestion effect will be explained using a first example and a second example.

(First example)
The first example of the setting suggestion performance is performed on the condition that the winning of the game ball to the first start opening 420 (see FIG. 5, for example) exceeds the reservation upper limit. For example, the host control circuit 2100 counts the first starting winning hole overflow point, and when the overflow command for the number of pending winnings of the first starting winning hole is sent from the main control circuit 100, the first starting winning hole overflow point is counted. Add 1. Then, when this first starting prize opening overflow point reaches a predetermined point (for example, 50 points), the main CPU 101 determines to execute the setting suggestion performance in the above performance mode determination process. In a non-time-saving gaming state where the time-saving flag is OFF, such as the normal gaming state, it is not easy to enter the game ball into the first starting opening 420, so if the first starting winning opening overflows, the player will be extremely disappointed. . Therefore, by performing a setting suggestion effect on the condition that the first starting winning hole overflow occurs in the non-time-saving gaming state, it is possible to suppress player disappointment without directly causing a loss to the hole. It becomes possible. Furthermore, some players interrupt the firing of game balls when the number of game balls entered into the first starting port 420 is at the pending upper limit. In this regard, it is also possible to promote the game by performing the setting suggestion performance on the condition that the winning number of game balls in the first starting opening 420 exceeds the reservation upper limit.

In addition, in the first example of the above-mentioned setting suggestion performance, the setting suggestion performance is performed when the first starting winning opening overflow point reaches a predetermined point, but this is not necessarily limited to this. The setting suggestion effect may be performed when the pending number overflow command is transmitted from the main control circuit 100. In this case, since the setting suggestion effect is executed more frequently, it is preferable that the setting suggestion effect be difficult to guess by performing the setting suggestion effect only once. For example, it is difficult to infer the setting from only the information obtained from one setting suggestion performance, but it becomes possible to infer the setting by collecting multiple pieces of information obtained from multiple setting suggestion performances. It is possible to do so.

Furthermore, as described above, the reason that the first starting slot prize pending number overflow command is sent to the sub-control circuit 200 is on the premise that the setting value data is determined to be normal in the setting check process of step S72. be. Therefore, if the setting value data is not determined to be normal in the setting check process, even if the game ball is placed in the first starting port 420 (for example, see FIG. 5) beyond the reservation upper limit. , the host control circuit 2100 does not add to the first starting winning slot overflow point. Therefore, if the winning of game balls to the first starting opening 420 (for example, see FIG. 5) exceeds the reservation upper limit, the first starting winning opening overflow point will reach a predetermined point (for example, a predetermined point 49 points compared to 50 points), when the number of game balls entered into the first starting port 420 (for example, see FIG. 5) exceeds the reservation upper limit, the setting check process of step S72 (see FIG. 42) is performed. (see) is determined to be abnormal, the main CPU 101 turns off the game permission flag (step S722, which will be described later) without the host control circuit 2100 performing a setting suggestion effect, making it impossible to proceed with the game. becomes.

In addition, in the first example of the setting suggestion performance, even if the winning of the game ball to the second starting port 440 (for example, see FIG. 5) exceeds the reservation upper limit, the setting suggestion performance is not performed ( (see FIG. 42), on the condition that the winning of game balls to the second starting port 440 exceeds the pending upper limit, the settings are made in the same way as when the winning of game balls to the first starting port 420 exceeds the pending upper limit. Suggestive effects may be performed.

(Second example)
A second example of the setting suggestion performance is performed when a game ball enters a specific winning hole during execution of the ready-to-win performance. For example, the host control circuit 2100 selects a specific winning hole from among the first starting hole 420, the second starting hole 440, and the general winning holes 53, 54, and 55 (all of which are shown in FIG. 5, for example) at the start of the ready-to-win effect. , for example, randomly determined by lottery. Then, when the winning command of the game ball to the determined winning hole is transmitted from the main control circuit 100 during execution of the ready-to-win effect, it is decided to execute the setting suggestion effect. For example, some players interrupt the firing of game balls when a reach effect with a long variable time is executed. Therefore, by executing a setting suggestion effect based on the detection of a winning of a game ball in a specific prize opening while executing a reach effect, it becomes possible to encourage the firing of game balls even during a reach effect. . In addition, there are cases in which it is immediately obvious that the level of expectation for a reach effect is low at the time the reach effect is started. In such a case, for the player, the next variable display will not start until the ready-to-win effect ends, which may reduce the player's interest. In this regard, by executing the setting suggestion performance based on the winning detection of the game ball in a specific winning opening during the execution of the ready-to-win performance, it becomes possible to suppress the decline in interest. Moreover, if the setting values can be set by the gaming machine manager, players may become suspicious that the setting values of the pachinko machines they play are low. According to the above example, such fear can be alleviated, and a decline in interest can be suppressed.

In addition, when the above-mentioned specific winning hole is randomly determined from among the first starting hole 420, the second starting hole 440, and each general winning hole 53, 54, and 55 (for example, see FIG. 5), for example, by lottery, It is preferable to keep it secret without disclosing which is the specific winning opening. This makes it more interesting for the player to decide which winning opening to aim for.

In addition, in the second example of the setting suggestion effect, the specific winning opening is set to the first starting opening 420, the second starting opening 440, and each general winning opening 53, 54, and 55 (for example, see FIG. 5). From among these, for example, it is randomly determined by lottery, but the specific winning opening is not necessarily determined at random, and a fixed winning opening may be used as the specific winning opening.

Further, in both the first example and the second example of the setting suggestion effect, the host control circuit 2100 decides to execute the setting suggestion effect, but the main CPU 101 may also decide to execute the setting suggestion effect. .

In addition, when a game ball wins a prize in a specific winning hole during execution of the reach effect, if the specific winning hole is the starting hole, the setting check process of step S72 or step S82 (both refer to FIG. 42) is performed. be exposed. The setting suggestion performance in this case is performed only when it is determined that the settings are normal in the above setting check process (YES in step S721). When the main CPU 101 determines that it is not normal in the above setting check process (NO in step S721), it not only does not perform the setting suggestion effect, but also prohibits the special symbols that are being displayed in a variable manner from stopping by the process in step S734. do. Furthermore, even if the host control circuit 2100 is in the process of performing a fluctuating display of decorative symbols accompanied by a ready-to-reach performance, it continues to perform the fluctuating display of the decorative symbols. However, the host control circuit 2100 may stop the output of the sound effect by the audio/LED control circuit 2200, or may reduce the output volume.

Next, the host control circuit 2100 executes command transmission processing (step S206). The command transmission process will be described later with reference to FIG. 54.

Next, the display control circuit 2300 executes drawing control processing (step S207). In this process, the display control circuit 2300 performs drawing control to display an image on the display device 16 based on the message (effect designation information) transmitted from the host control circuit 2100.

Next, the audio/LED control circuit 2200 executes audio control processing (step S208). In this process, the audio/LED control circuit 2200 performs audio control to cause the speaker 24 to output audio based on the message (effect designation information) transmitted from the host control circuit 2100.

Next, the audio/LED control circuit 2200 executes control processing regarding the light emission mode of the LED 25 (step S209). In this process, the audio/LED control circuit 2200 performs light emission control to turn on or blink the LED 25 based on the message (effect designation information) transmitted from the host control circuit 2100.

Next, the host control circuit 2100 executes accessory control processing (step S210). This accessory control process operates the accessory objects that operate among the accessory objects that make up the accessory group 1000 and the actuating members that make up the accessory objects, based on the production designation information, via the I2C controller 2610 and the motor controller 2700. This is a process for controlling the drive of the performance drive motor, and details will be described later. In such sub-control main processing, after the initialization processing of step S201 is completed, each processing of steps S202 to S210 is repeatedly executed.

[8-1. Command analysis processing]
FIG. 53 is a flowchart showing command analysis processing by the host control circuit 2100. The command analysis process is called as a subroutine during execution of the sub-control main process described above. As shown in the figure, after receiving the command from the main control circuit 100 (main CPU 101), the host control circuit 2100 performs a process of analyzing the command stored in the reception buffer of the sub-work RAM 2100a (step S241).

Next, the host control circuit 2100 performs a consistency check on the received command (step S242). The consistency check is performed to verify that the target data exists when the command is received, and that there are no errors or omissions in the data.

Next, the host control circuit 2100 performs sub-lottery processing (step S243). In this process, when the received command is a variation pattern designation command, the host control circuit 2100 selects a production pattern by lottery based on the variation pattern designation command. After completing this process, the host control circuit 2100 ends the command analysis process. In addition, in the sub-lottery process, all matters related to the performance including the performance pattern may be selected by lottery, or only the type of performance (presence or absence of dialogue preview, presence or absence of SU notice, etc.) may be selected as the performance pattern. The production contents (type of effect, type of cut-in, etc.) selected by lottery and executed in the production may be selected as production information in another process that is separately formed into a subroutine. In this embodiment, a performance pattern indicating the type of performance is selected in the sub-lottery process, and then the performance content to be executed based on the performance pattern is selected as performance information in the performance mode determination process described later. ing.

By the way, in the pachinko gaming machine 1 of this embodiment, during the execution of the game, a setting check process is performed in step S72 and step S82 (see FIG. 42), and in this setting check process, the setting value data is "0" to "5". ” (NO in step S721 in FIG. 43), the processes in steps S722 to S726 are executed, and then the abnormality process in step S727 is executed. However, for example, if the main control board 30 is illegally replaced, there is a high possibility that the setting check process in step S72 or step S82 will not be executed. Further, in the case where the set value is changed due to input of an unauthorized signal, there is a possibility that the set value data is within the range of "0" to "5". Therefore, in the pachinko gaming machine 1 of this embodiment, there are cases where the setting check process is not executed in step S72 or step S82, or the setting value data is set to "0" even though the setting value may have been changed illegally. - "5" (for example, when the determination is YES in step S721), the host control circuit 2100 executes a setting determination process to determine whether or not the setting value information is appropriate. . This setting determination process will be explained below without being shown.

First, the main CPU 101 starts the variable display of the special symbol at a specific timing (for example, when a game ball enters the first starting port 420 or the second starting port 440, and when the variable display of the special symbol is suspended. (e.g., when the main RAM 103 is sent), a command indicating the setting value information stored in the main RAM 103 is transmitted. After receiving this command, the host control circuit 2100 determines whether the setting value information (hereinafter referred to as "current setting value") indicated by the currently received command is appropriate. This suitability determination is, for example, a process of determining whether setting value information indicated by the previously received command (hereinafter referred to as "previous setting value") matches the current setting value.

Then, the host control circuit 2100 determines that the set value is normal if the previous set value and the current set value match, and the set value is abnormal if the previous set value and the current set value do not match. It is determined that

Furthermore, when the received setting value information is abnormal, the host control circuit 2100 executes a setting value abnormality process. This abnormality execution processing may, for example, display an image in the display area of the display device 16 to notify that the set value is abnormal, or alternatively or in addition to this, display an image to notify that the set value is abnormal. This is the process of outputting the audio that will be heard.

Note that the above-mentioned determination of the suitability of the setting value information is not limited to determining whether the previous setting value and the current setting value match. Alternatively, it may be determined whether some of the setting value information received multiple times (for example, the setting value indicated by the command received two times before and the current setting value) match. Alternatively, it may be determined whether or not there is one. However, when the host control circuit 2100 receives a command (for example, a setting change start command or an initialization command) indicating that the setting change process (see step S24 in FIG. 33) has been executed, the current setting value is stored in the subwork RAM 2100a. It is not determined whether the current setting value matches the past setting value including the previous setting value.

In addition, it is preferable that the above-mentioned setting determination process (determining the suitability of setting value information) is executed not only during the game, but also when the power is turned on after a power outage, as long as the setting change process is not executed. . The setting determination process executed when the power is turned on after the power is cut off will be described later with reference to FIG. 114.

The setting determination process executed by the host control circuit 2100 described above may be executed during the command analysis process (step S204) or after exiting the subroutine of the command analysis process.

[8-2. Command sending process]
FIG. 54 is a flowchart showing command transmission processing by the host control circuit 2100. The command transmission process is called as a subroutine during execution of the sub-control main process described above. As shown in the figure, the host control circuit 2100 executes a message setting process when transmitting a control command (message) to each of the control circuits 204 to 207 (step S251). In this process, the host control circuit 2100 generates a message (effect designation information) based on the effect information obtained in the effect mode determination process, and temporarily stores the message in the direct buffer of the sub-work RAM 2100a. conduct. This message setting process will be described later with reference to FIG. 55.

Next, the host control circuit 2100 executes a directory table registration process (step S252). In this process, the host control circuit 2100 performs a process of setting a corresponding direct table in a predetermined area of the sub-work RAM 2100a based on the message and effect information stored in the direct buffer. This directory table registration process will be described later with reference to FIG. 56.

Next, the host control circuit 2100 executes message transmission processing (step S253). In this process, the host control circuit 2100 reads the message stored in the direct buffer at a predetermined timing based on the direct table, and performs a process of transmitting the message to a predetermined control circuit 204 to 207. After completing this process, host control circuit 2100 ends the command transmission process. This message sending process will be described later with reference to FIG. 57.

[8-2-1. Message setting processing]
FIG. 55 is a flowchart showing message setting processing by the host control circuit 2100. The message setting process is called as a subroutine during execution of the command sending process described above. As shown in the figure, the host control circuit 2100 sets the devices (control circuits 204 to 207) to transmit based on the effect information (step S261).

Next, the host control circuit 2100 performs a process of setting whether or not the system is operating (step S262).

Next, the host control circuit 2100 sets stage information and each performance information (step S263).

Next, the host control circuit 2100 sets a notice pattern (step S264). As a result, messages indicating destination devices (control circuits 204 to 207), presence or absence of system operation, stage information, each performance information, and preview pattern are stored in the direct buffer. After completing this process, host control circuit 2100 ends the message setting process.

[8-2-2. Director table registration process]
FIG. 56 is a flowchart showing the directory table registration process by the host control circuit 2100. The directory table registration process is called as a subroutine during execution of the command transmission process described above. As shown in the figure, the host control circuit 2100 performs a process of registering a single table (step S271).

Next, the host control circuit 2100 performs a process of registering a master table based on the performance information determined in the performance mode determination process (step S272).

Next, the host control circuit 2100 performs a process of registering a slave table to be used in the master table (step S273).

Next, the host control circuit 2100 performs a process of registering the direct table corresponding to the message set in the direct buffer as a slave table (step S274). After completing this process, the host control circuit 2100 ends the directory table registration process.

[8-2-3. Message sending process]
FIG. 57 is a flowchart showing message transmission processing by the host control circuit 2100. The message transmission process is called as a subroutine during execution of the command transmission process described above. As shown in the figure, if a message is registered in the direct buffer corresponding to the direct table, the host control circuit 2100 sends each device (control circuits 204 to 207) according to the "destination device" set in the message. The process of transmitting a message to is performed (step S281).

Next, after the message transmission is completed, the host control circuit 2100 performs a process of discarding unnecessary directory tables (step S282). After completing this process, host control circuit 2100 ends the message sending process.

[9. Expandability of gaming machine according to this embodiment]
As described above, in the pachinko game machine 1 of the present embodiment, the jackpot probability, reach probability, special symbol variation time, main symbol selection rate (number of rounds, probability variable entry rate, time saving) are determined according to the set values. However, it is not necessarily necessary to change all of these according to the setting value, and it is possible to change only one or a plurality of them according to the setting value.

In addition, in the pachinko gaming machine 1 of the present embodiment, when the normal symbol stopped and displayed in the normal symbol display section 71 is in a predetermined mode (the "normal win" mode), the normal electric accessory 46 is displayed in a predetermined manner. It changes from the closed state to the open state for a period of . Therefore, the player may be informed of the timing at which the normal electric accessory 46 changes from the closed state to the open state or from the open state to the closed state (that is, the timing at which the game ball is fired). In this case, the frequency at which the game ball launch timing is notified may be changed depending on the setting value (the higher the setting value, the higher the launch timing notification frequency).

Furthermore, in the pachinko gaming machine 1 of this embodiment, when the backup clear process (for example, step S39) is performed, the data stored in the general work area of the work areas of the main RAM 103 is cleared. This backup clearing process is always performed when the setting change process (step S24) is executed, so when the backup clearing process is performed, the data stored in the general work area of the work area of the main RAM 103 is always is cleared. However, instead of this, the clear address range of the main RAM 103 where data is cleared can be determined by the backup clear process performed when the settings change process is executed and the backup clear process performed without executing the settings change process. It may be made to be different. For example, after the jackpot game state ends, the high-probability game state remains until a predetermined number of games are executed (until the special symbol is displayed fluctuating a predetermined number of times), and after the predetermined number of games are completed, the high-probability game state remains In a pachinko game machine (a pachinko game machine called a so-called "ST machine") that shifts to a probability game state, when it is controlled to a high probability game state (before the execution of a predetermined number of games is finished), a setting change process is performed. When the backup clear process is performed without the setting change process, the probability change flag is set to OFF, and when the backup clear process is performed with the execution of the setting change process, the probability change flag is continued to be set to ON (remaining high probability gaming state). The memory of the number of games may be retained). Furthermore, when the backup clear process is performed with the execution of the setting change process, the probability change flag continues to be set ON when the setting value is the same as the previous one, and when it is set to a different setting value from the previous time. The probability variation flag may be set to OFF.

In addition, in the pachinko gaming machine 1 of the present embodiment, in each round game in the jackpot game state, the big winning hole 540 is opened when the count of game balls that have entered the big winning hole 540 reaches 10 balls, and when the big winning hole 540 is in the open state. When either one of the following conditions is satisfied, the closed state is reached. Therefore, in each round game in the jackpot game state, the conditions under which the jackpot 540 changes from the open state to the closed state may be changed according to the set value. For example, a plurality of conditions are prepared in which the grand prize opening 540 changes from an open state to a closed state (for example, a plurality of conditions are prepared in which the expected value of the number of game balls that can enter the grand prize opening 540 during one round is different). By preparing conditions) and changing the conditions according to the set value, the higher the set value, the higher the above-mentioned expected value is likely to be selected. As a specific example, it is considered that the opening time of the grand prize opening 540 in the round game is determined by lottery according to the setting value, so that the higher the setting value is, the longer the opening time of the grand prize opening 540 is likely to be. It will be done. In addition, by changing the count of game balls when the grand prize opening 540 changes from an open state to a closed state in a round game according to the setting value, the higher the setting value, the more likely the number of gaming balls to enter the grand prize opening 540 will increase. It is also possible to do so.

In addition, in the pachinko game machine 1 of the present embodiment, when the stopped and displayed normal symbol is in a normal winning mode, the normal electric accessory 46 changes from the closed state to the open state for a predetermined period; The time during which the accessory 46 is in the open state (opening time) may be varied depending on the setting value, so that the higher the setting value, the longer the opening time of the normal electric accessory 46 tends to be.

In addition, in the pachinko game machine 1 of the present embodiment, when the jackpot is such that the probability change flag is turned ON, as in special drawings 1-2 and 1-4, the next jackpot game is executed after the jackpot gaming state ends. The high probability gaming state continues until the game is played, but it is not necessarily limited to this. For example, when a game ball enters the first starting port 420 or the second starting port 440, the display of the special symbol changes may be suspended. (when the variable display of special symbols is started), a transition lottery may be executed to determine whether to transition from a high probability gaming state to a low probability gaming state. In this case, by varying the probability of transition from a high probability gaming state to a low probability gaming state depending on the setting value, the higher the setting value, the higher the probability of continuation of the high probability gaming state (from the high probability gaming state to the low probability gaming state) (lower the transition probability). In addition, in the pachinko gaming machine 1 of this embodiment, for example, a setting check process (step S72, step S82) is performed when a game ball enters the first starting port 420 or the second starting port 440. When it is determined in the process that it is not normal (NO in step S721), the result of the transition lottery is also cleared in the backup clear process (step S2420) by executing the setting change process (step S24) (the probability change flag is also turned OFF). ).

As mentioned above, in this embodiment, the jackpot probability, reach probability, special symbol variation time, and main symbol selection rate (number of rounds, variable entry rate, time-saving entry rate) are changed according to the set values. Although the pachinko gaming machine 1 has been described, the provision of setting differences is not limited to the above-described embodiment, and a part of the configuration may be changed. Another example of expansion in which the configuration is partially changed will be described below. Note that the configurations that are not particularly mentioned in the explanation of other expansion examples below are the same as the configuration of this embodiment, but in the following, codes are intentionally added to each component such as the main CPU, with the exception of step numbers. I haven't.

[9-1. Expansion example 1]
In the pachinko gaming machine of expansion example 1, when the result of the jackpot determination of the special symbol is a jackpot, if a predetermined condition is met, a high probability game is played after the jackpot gaming state ends until the next jackpot gaming state starts. This will be explained by taking as an example a so-called "variable loop machine" in which the state continues. In this extended example 1, an upper limit is set on the number of times that the jackpot gaming state and the high probability gaming state are repeatedly executed (hereinafter referred to as the "loop number"), and when the loop number reaches this upper limit, the jackpot gaming state ends. In addition to controlling the subsequent gaming state to a low probability gaming state, the upper limit of the number of loops (hereinafter referred to as the "limiter number") can vary depending on the set value (such a gaming machine is called a "limiter number"). (also called machine). This will be explained with reference to FIG. 58. Note that FIG. 58 is a table showing an example of the selection rate of the limiter number of times in the pachinko game machine of the expansion example 1 for each set value.

The main CPU of the pachinko gaming machine according to expansion example 1 includes a loop number checking means that checks the number of loops when the result of jackpot determination of a special symbol is a jackpot, and a limiter number of times that performs a limiter number lottery when the number of loops is 0. A lottery means, a loop number counting means that increments the number of loops when the number of loops is within a prescribed range (in the range of 1 to 4 in this example), and a loop number counting means that increments the number of loops when the number of loops is a prescribed value (in this example, the limiter upper limit is 5). This includes a game state control means for controlling the game state to a low probability state after the end of the jackpot game state, and a loop number reset means for resetting the number of loops when the number of loops is a specified value. The limiter number lottery may be performed at any timing when the result of the jackpot determination is a jackpot, at the start of the jackpot gaming state, during the jackpot gaming state, or at the end of the jackpot gaming state.

As shown in FIG. 58, in setting 1, the limiter number is determined to be once with a probability of 25%, twice with a probability of 30%, three times with a probability of 25%, There is a 15% probability that it will be determined 4 times, and a 5% probability that it will be determined 5 times. In setting 2, the limiter number of times is determined to be once with a 25% probability, twice with a 25% probability, three times with a 25% probability, and four times with a 20% probability. 5 times with a probability of 5%. In setting 3, the limiter count is determined to be once with a 15% probability, twice with a 25% probability, three times with a 25% probability, and four times with a 20% probability. 5 times with a probability of 15%. In setting 4, the limiter number of times is determined to be 1 time with a 15% probability, 2 times with a 20% probability, 3 times with a 25% probability, and 4 times with a 25% probability. 5 times with a probability of 15%. In setting 5, the limiter number of times is determined, for example, once with a 5% probability, twice with a 20% probability, three times with a 25% probability, and four times with a 25% probability. 5 times with a probability of 25%. In setting 6, the limiter number is determined to be once with a 5% probability, twice with a 10% probability, three times with a 25% probability, and four times with a 30% probability. 5 times with a probability of 25%. That is, the higher the set value is, the higher the expectation is that the limiter count will be determined to be larger.

In this way, the degree of expectation for the number of limiters is varied depending on the setting value, and the higher the setting value, the more likely the jackpot gaming state and high probability gaming state will be repeated. It is possible to vary the amount of prize balls given to the player in each opportunity (until the game is controlled to a low-probability gaming state when the player wins once) in accordance with a set value. Furthermore, although the expected value for the limiter count is different depending on the set value, the limiter count is determined by lottery, so it is possible to prevent players from guessing the set value based on the limiter count. It has become.

In addition, in the above expansion example 1, the limiter count is determined by lottery according to the set value, but the lottery is not necessarily essential, and although there is a concern that the set value may be guessed by the player, The limiter number may be uniquely determined according to the set value, such as 3 times for settings 1 and 2, 4 times for settings 3 and 4, and 5 times for settings 5 and 6.

In addition, the above limiter count may be set separately for each of the first special symbol and the second special symbol, or may be set for both the first special symbol and the second special symbol. good.

For example, if the above limiter count is determined separately for the first special symbol and the second special symbol, if the result of the jackpot determination for the first special symbol is a jackpot, the first limiter count for the first special symbol is set. is determined, and when a jackpot game state is controlled during the loop based on the jackpot determination result of the first special symbol, the number of loops for the first special symbol is incremented. However, when the jackpot game state is controlled based on the jackpot determination result of the second special symbol during the above loop, the number of loops for the first special symbol is not incremented, and the second limiter number for the second special symbol is set. Determine. In this case, the loop may be ended (controlled to a low probability gaming state) when either the first limiter number of times or the second limiter number of times reaches the limiter number, or the first limiter number of times and the second limiter number of times The loop may be terminated when both the number of times and the number of times reach the limiter number of times.

Also, for example, if the above limiter count is set for both the first special symbol and the second special symbol, the result of jackpot determination regardless of whether it is the first special symbol or the second special symbol. When it is a jackpot, the limiter number of times is determined, and during the loop, when it is controlled to a jackpot gaming state based on the result of jackpot determination regardless of whether it is the first special symbol or the second special symbol, the loop Increment the count. Then, when the number of loops reaches the limiter number, the loop ends.

Further, although the pachinko game machine of expansion example 1 described above is a so-called fixed variable loop machine, it does not necessarily have to be a fixed variable loop machine. For example, the above technical idea can be applied to a pachinko gaming machine called a so-called "ST machine". You can also. "ST machine" is a machine that controls the gaming state after the end of the jackpot gaming state to a high probability gaming state without fail or based on a predetermined lottery result, and maintains the high probability gaming state a predetermined number of times (hereinafter referred to as "ST number of times"). This pachinko game machine continues until the variable display of the special symbols is performed, and when the variable display of the special symbols is performed the predetermined number of times, the high probability game state is ended and the control is controlled to the low probability game state. Even in such a "ST machine", the degree of expectation regarding the limiter number can be varied depending on the setting value. In other words, the higher the setting value, the more times the jackpot gaming state and the high probability gaming state can be repeated. ), it is possible to vary the amount of prize balls given to the player according to a set value.

In addition, in the so-called "ST machine", it is possible to set the "ST number" to a predetermined number (for example, 70 times), but it is also possible to set the ST number to vary depending on the set value. . For example, the main CPU of the "ST machine" can determine the number of STs by lottery, and the expected value of the number of STs determined according to a set value can be set to be different. As a specific example, the expected value of the number of STs determined by lottery is 60 times for setting 1, 63 times for setting 2, 66 times for setting 3, 69 times for setting 4, 72 times for setting 5, and 60 times for setting 6. By setting the number of times to 75, the higher the set value, the higher the expected value of the number of STs can be. However, it is not essential to determine the number of STs by lottery, and the number of STs may be uniquely determined according to a set value. Note that when the number of STs is set to differ depending on the setting value, it is preferable to make the number of time saving times common to all setting values. For example, when the ST number or the expected value of the ST number is 60 times for setting 1, 63 times for setting 2, 66 times for setting 3, 69 times for setting 4, 72 times for setting 5, and 75 times for setting 6. It is conceivable to set the number of time saving times to 60 times, for example, in common to all settings. Then, the sub CPU performs, for example, on the display device 16, an effect that allows the user to understand that a high probability gaming state is in effect until the number of STs reaches a certain number of games (for example, 60 games), and when the number of STs reaches a certain number of games, Regardless of whether or not the game is in a high-probability gaming state, it is preferable to use, for example, a liquid crystal display device to provide an effect that makes it difficult to recognize that the player is in a high-probability gaming state. This makes it possible to vary the number of STs and the expected value of the number of STs depending on the set value while preventing the player from noticing the set value.

Further, in the pachinko game machine of the first expansion example, a setting check process (step S72, step S82) is performed, for example, when a game ball enters the first starting hole or the second starting hole. Then, when it is determined that this setting check process is not normal (NO in step S721), even if the loop is in progress (that is, when the jackpot gaming state and the high probability gaming state are being repeatedly executed), Without the number of loops reaching the limiter number, the number of loops is also cleared in the backup clearing process (step S2420) by executing the setting change process (step S24) (the probability change flag is also set to OFF).

[9-2. Extension example 2-1]
The pachinko game machine of expansion example 2 has a specific area in which a specific opening is provided. This specific area is separated from the downstream area of the game ball by, for example, an accessory, and it is normally difficult (or impossible) for the game ball to enter the specific area. In addition to the jackpot, a small win is also prepared as a result of the jackpot determination of the special symbol.

Specifically, the main CPU performs a jackpot determination of a special symbol with a jackpot probability determined according to a set value, and when the result of this jackpot determination is a loss, performs a small hit determination. Then, when the result of the small win determination is a small win, a small win game is executed. That is, the above-mentioned jackpot is a hit that involves the operation of a conditional device, but the above-mentioned small hit is not a hit that involves the operation of a conditional device.

In addition, in this expansion example 2, for example, in a normal game state such as a non-time saving game state where the time saving flag is set to OFF, the first special symbol game based on the winning of the game ball to the first starting hole, and the second The first special symbol game is mainly played among the second special symbol game based on winning of the game ball in the starting hole. On the other hand, in a probability variable time saving game state such as a time saving game state where the time saving flag is set to ON, the second special symbol game is mainly played between the first special symbol game and the second special symbol game. Furthermore, in the second special symbol game, when the result of the jackpot determination is a loss, the player wins a small hit with a predetermined probability. Note that when the result of the jackpot determination in the first special symbol game is a loss, there is no need to perform a small hit determination.

In addition, if the result of the jackpot determination for the special symbol, which is performed based on the entry (acceptance) of the game ball into the starting hole, is a small hit, the main CPU operates a predetermined movable piece to close the specific area. A small winning game execution means that executes a small winning game that changes from the small winning game to an open mode, and a payout/launch control circuit based on a game ball winning a prize in a specific area that becomes an open mode by executing the small winning game. and a payout means for paying out a predetermined number (for example, 10 balls) of game balls as prize balls.

In addition, in this second expansion example, the number of time saving times is set to, for example, five times, and a specific opening is provided in a specific area. For example, in the time-saving game state 5 times, when a game ball enters the starting hole as a result of a normal win, and a small win is achieved, a predetermined movable piece is activated and a specific area is opened. At this time, when it is detected that the game ball that has entered the specific area has further entered the specific opening, the main CPU executes the jackpot game. Further, if the game does not normally win in the time-saving game state five times, the main CPU ends the time-saving game state and controls the game to a non-time-saving game state. In addition, in the time-saving gaming state, the game is played by right-handed hitting, in which the game ball is fired towards the right side area of the gaming area, and in the non-time-saving gaming state, the game is played in left-handed hitting, in which the game ball is fired towards the left side area of the gaming area. A game is played.

In such a pachinko game machine, in this second expansion example, the small hit probability in at least the second special symbol game is varied according to a set value, so that the second special symbol game is mainly played, for example, in a time-saving game state. In this case, it is possible to vary the opening frequency of a specific area and, therefore, the ball output depending on the set value.

For example, the probability of a small hit is 1/9 with setting 1, 1/8 with setting 2, 1/7 with setting 3, 1/6 with setting 4, 1/5 with setting 5, and 1/5 with setting 6. Make it 1/4. In this case, the higher the setting value is, the longer the fluctuation time of the normal symbol is, or the higher the setting is, the longer the normal symbol fluctuation time is, or the higher the setting is, the more difficult the opening mode of the normal electric accessory is to make it difficult for the game ball to enter the starting hole. It becomes easier for game balls to enter the starting slot. As a result, the higher the set value is, the higher the frequency of winning of game balls in the specific area becomes, and in turn, it becomes possible to provide a difference in the speed of ball delivery depending on the set value.

In addition, in this extended example 2, in the time-saving gaming state, the probability change flag may be set to ON, but it is not necessarily necessary to set the probability change flag to ON.

Furthermore, if a game ball enters the first starting hole or the second starting hole while the main CPU is displaying the special symbols in a variable manner, the setting check process of step S72 or step S82 is executed in this case as well. . If the main CPU determines in this setting check process that it is not normal (NO in step S721), the main CPU turns off the game permission flag, even if the result of the jackpot determination for the special symbol that is being displayed in a variable manner is a small hit. Execute abnormality processing. Therefore, even if the result of the jackpot determination for the special symbol being displayed as a variable is a small hit, if it is determined in the setting check process that it is not normal, the main CPU executes the small win game based on the above small win. The game permission flag is turned OFF without any problem, and abnormality processing is executed. Therefore, the game permission flag will not be set to ON unless various data, including the fact that the result of jackpot determination for the special symbol being displayed in a variable manner is a small hit, are cleared in the backup clear process.

[9-3. Extension example 2-2]
The pachinko game machine of expansion example 2-2 includes a first starting port and a second starting port. The main CPU determines the jackpot of the first special symbol (hereinafter referred to as "first special lottery") based on the winning of the game ball in the first starting hole, and determines the winning of the game ball in the second starting hole. Based on this, a jackpot determination of the second special symbol (hereinafter referred to as "second special lottery") is performed.

In addition, the main CPU operates in a first gaming state (for example, a probability variable flag and a normal gaming state where both the time saving flag and time saving flag are set to OFF), and a second gaming state where the second special symbol lottery (hereinafter referred to as "second special lottery") is mainly performed (for example, the probability change flag is set to ON). The present invention includes a gaming state control means capable of controlling any one of a plurality of gaming states including an advantageous gaming state in which the time saving flag is set to OFF and the time saving flag is set to OFF. In this pachinko game machine, when a jackpot is won with a specific symbol in the first game state, after the jackpot game ends, the machine is controlled to the second game state.

Further, a regular game ball gate is provided in the right side area of the game area, and when a game ball passes through the regular gate, a regular lottery is held. If the result of this normal lottery is a specific result (for example, a normal win), the main CPU releases a predetermined movable member (for example, an electric tulip), thereby facilitating the entry of the game ball into the second starting slot. be done. Therefore, when a game is played by firing a game ball towards the right side area of the game area, the second starting port The frequency of winning of game balls is increased.

In the first special lottery, the main CPU performs a jackpot determination of the first special symbol with a jackpot probability determined according to the set value, and when the result of this jackpot determination is a jackpot, a predetermined jackpot is opened for multiple rounds. A first jackpot game execution means is provided for executing a jackpot game that is opened over several numbers.

In addition, the main CPU performs a jackpot determination of the second special symbol with a jackpot probability determined according to the set value in the second special lottery, and when the result of this jackpot determination is a jackpot, a predetermined jackpot is opened. A second jackpot game execution means is provided for executing a jackpot game that is opened over a plurality of rounds. In addition, in the second special lottery, when the result of the jackpot determination of the second special symbol is a loss, the main CPU determines a small hit, and when the result of the small hit determination is a small hit. Also provided is a small winning game execution means for executing a small winning game.

Note that the jackpot probability in the first special lottery and the jackpot probability in the second special lottery are the same. The jackpot probability in the first gaming state where the variable probability flag is set to OFF is, for example, 1/300 for setting 1, 1/290 for setting 2, 1/280 for setting 3, and 1/270 for setting 4. , setting 5 is 1/260, and setting 6 is 1/250. In addition, the jackpot probability in the second gaming state where the variable probability flag is set to ON is, for example, 1/30 with setting 1, 1/29 with setting 2, 1/28 with setting 3, and 27 minutes with setting 4. 1, setting 5 is 1/26, and setting 6 is 1/25.

The main CPU includes a first jackpot game execution means for executing a jackpot game in which a predetermined big prize opening is opened over a plurality of rounds when the result of the first special lottery is a jackpot; and a second jackpot game execution means for executing a jackpot game in which a predetermined jackpot opening is opened over a plurality of rounds when a jackpot is won. Even if the big winning hole that is opened when the result of the first special lottery is a jackpot and the big winning hole that is opened when the result of the second special lottery is a jackpot are the same big winning hole, It's fine, and it can be a different big prize opening.

Further, the small winning probability in the first special lottery is 0 (common to settings 1 to 6) regardless of whether the probability change flag is ON or OFF. In addition, the small winning probability in the second special lottery is, for example, 1/9 with setting 1, 1/8 with setting 2, and 1/7 with setting 3, regardless of whether the variable probability flag is ON or OFF. , setting 4 is 1/6, and setting 5 is 1/6. In this way, the small winning probability in the second special lottery differs depending on the set value, but any set value is higher than the small winning probability in the first special lottery.

Further, the main CPU has a small winning game execution means for executing a small winning game when the result of the second special lottery is a small winning. The small winning game is a game in which the same big winning hole as the big winning hole that is opened when the result of the second special lottery is a jackpot is opened. When a game ball enters the big prize opening, the payout/launch control circuit operates the payout device and controls so that a predetermined number of game balls are paid out as a prize. However, in the small winning game, the number of game balls that can be entered into the big winning slot is smaller than in the jackpot game, so the degree of advantage for the player is lower in the small winning game than in the jackpot game.

Further, as described above, the small winning probability in the first special lottery is 0. That is, the main CPU performs a small hit determination with a small hit probability of 0 when the result of the jackpot determination for the first special symbol is a loss. However, instead of this, when the result of the jackpot determination for the first special symbol is a loss, the main CPU may not perform the small hit determination itself.

Note that the above-mentioned jackpot is a hit that involves the operation of a conditional device, but the above-mentioned small hit is not a hit that involves the operation of a conditional device.

The main CPU also includes a first special symbol fluctuation display control means that displays a variable display of the first special symbol based on the winning of the game ball to the first starting hole, and a first special symbol fluctuation display control means that performs a fluctuating display of the first special symbol based on the winning of the game ball to the second starting hole. and a second special symbol fluctuation display control means for variably displaying the second special symbol. The first special symbol fluctuation display control means causes the first special symbol to be variably displayed for a predetermined period of time, and then stops the first special symbol so that the result of the first special lottery is displayed. Further, the second special symbol fluctuation display control means causes the second special symbol to be variably displayed for a predetermined period of time, and then stops the second special symbol so that the result of the second special lottery is displayed.

The variable display of the first special symbol by the first special symbol variation display control means and the variable display of the second special symbol by the second special symbol variation display control means are configured to be able to be performed at the same timing. That is, if a game ball enters the second starting port while the first special symbol is being displayed in a variable manner based on the winning of the game ball in the first starting port, the first special symbol is being displayed in a variable manner. The variable display of the second special symbol also starts. If a game ball enters the first starting port while the second special symbol is being displayed in a variable manner based on the winning of the game ball in the second starting port, even if the second special symbol is being displayed in a variable manner. The variable display of the first special symbol is started.

Moreover, the average time of the variation time of the first special symbol executed by the first special symbol variation display control means is almost the same when the probability variation flag is ON and when it is OFF, but the second special symbol The average time of the variation time of the second special symbol executed by the variation display control means is significantly different between when the probability variation flag is ON and when it is OFF. For example, the average time of the fluctuation time of the first special symbol is 10 seconds in the first game state and 10 seconds in the second game state, while the average time of the fluctuation time of the second special symbol is 1000 seconds in the first game state, In the second game state, the time is 1 sec. The special lottery (first special lottery, second special lottery) is held when the variable display of the special symbols (first special symbol, second special symbol) starts, but the results of the special lottery are not displayed. is when the variable display of the special symbol has stopped. Therefore, when a game ball enters the second starting slot in the first gaming state, although the second special lottery has already been held, it takes a considerable amount of time until the results of the second special lottery are displayed. becomes.

In this way, in the first game state in which the probability change flag is set to OFF, even if the game ball is launched toward the right side area of the game area and the game ball enters the second starting hole, the second special symbol It takes time for the variable display to stop. Moreover, since the second special symbol is displayed in a variable manner in one of a plurality of patterns with different variation times, even if the second special symbol stops in a manner indicating a small hit (it may not be a small hit). Even if the big winning opening is opened for a predetermined time (for example, 1.8 seconds), it is difficult to grasp the timing when the second special symbol is confirmed as a small win. For this reason, it is difficult to perform so-called targeted hitting, such as placing a game ball in the big winning hole at the timing when it is confirmed that the second special symbol is a small win. Furthermore, in the first game state, when a game ball is launched toward, for example, the right side area of the game area, a warning sound is output from the speaker under the control of, for example, the sub CPU. Therefore, in the first game state, a game is played by firing a game ball toward, for example, the left side area of the game area. On the other hand, in the second game state, by passing the game ball through the normal pattern gate, not only is it easier to enter the game ball into the second starting slot through the normal lottery, but also the fluctuation time of the second special pattern is It is as short as 1 sec, and in the second special lottery, the probability of winning a small hit is higher than 1 in 10 no matter which setting value is used. It will be done.

The average time of fluctuation of the second special symbol in the first gaming state (for example, 1000 seconds) is, for example, 50 times or more of the average time of fluctuation of the first special symbol in the first gaming state (for example, 10 seconds). is preferable, but preferably at least 10 times or more.

In addition, the sub-CPU is a decorative symbol fluctuation display control means that controls the fluctuating display of the decorative symbols to be displayed on, for example, a liquid crystal display device in synchronization with the fluctuating display of the special symbols (first special symbol, second special symbol). Equipped with However, in the first gaming state, this decorative symbol fluctuation display control means does not display the decorative symbols fluctuating in synchronization with the second special symbol in a conspicuous manner even if a game ball enters the second starting hole. When a game ball enters a first starting hole, a variable display of a decorative pattern synchronized with a first special pattern is displayed in a conspicuous manner.

To explain in detail the example of the above-mentioned "conspicuous aspect," the liquid crystal display device displays, for example, a left symbol (first symbol), a middle symbol (second symbol), and a right symbol (third symbol) approximately in the center of the display area. It is possible to display the results of the special lottery by changing the display. In addition, in a small area, for example, one of the four corners of the display area, a fourth symbol (for example, ○ or △) that can be displayed variably (for example, blinking) in synchronization with the first special symbol and the second special symbol, respectively. shape) can be displayed. Since the proportion of the display area occupied by the first to third symbols is extremely large compared to the proportion of the display area occupied by the fourth symbol, the player's attention is more focused on the first to third symbols than on the fourth symbol. I will be heading towards it. For example, in the first gaming state, when a game ball enters the second starting hole, the sub CPU does not variably display the first to third symbols, but only variably displays the fourth symbol. When a game ball enters the first starting hole, the first to third symbols are displayed in a variable manner, and the fourth symbol is also displayed in a variable manner. In this way, in the first gaming state, even if a game ball enters the second starting hole, the decorative pattern synchronized with the second special symbol is not displayed in a conspicuous manner, and the game ball enters the first starting hole. It is possible to display a variable display of the decorative pattern synchronized with the first special pattern in a conspicuous manner when the player wins a prize.

According to the pachinko game machine of expansion example 2-2 described above, in the first game state, even if a game ball enters the second starting slot, the result of the second special lottery is hardly displayed, but in the second game state In this case, not only is it easier to enter the game ball into the second starting hole, but also the average time of fluctuation of the second special symbol is as short as 1 sec. Moreover, in the second game state, when the game ball enters the second starting slot, the probability that the result of the second special lottery will be a small hit (1/9 to 1/4 depending on the setting) is a jackpot. Since the probability is higher (1/30 to 1/25 depending on the setting), the opening of the big prize opening by the small winning game is performed with high frequency, without setting the time saving flag (i.e., the opening of the big prize opening by the small winning game). (without increasing the frequency of execution), it is possible to increase the chances of game balls being paid out as prizes. Moreover, the probability that the result of the second special lottery will be a small hit differs depending on the set settings, so even if a jackpot game is not being executed, the balls will be paid out according to the set value. It is possible to make them different.

Furthermore, if a game ball enters the first starting hole or the second starting hole while the main CPU is displaying the special symbols in a variable manner, the setting check process of step S72 or step S82 is executed in this case as well. . Therefore, the main CPU performs the setting check process of step S72 or step S82, for example, in the second game state, even when a game ball enters the first starting hole during the variable display of the second special symbol. If the main CPU determines in this setting check process that the setting is not normal (NO in step S721), it turns off the game permission flag and executes the abnormality process. That is, in the second gaming state, even if the result of the jackpot determination for the second special symbol that is being fluctuated and displayed is a small hit, if it is determined that it is not normal in the setting check process, the main CPU executes the small hit described above. To turn off a game permission flag and execute abnormality processing without executing a small winning game based on a winning. Therefore, even if the result of the jackpot determination for the second special symbol that is being fluctuated and displayed in the second gaming state is a small hit, the information that it is in the second gaming state and the information that it is a small hit are also included. Unless the various data are cleared in the backup clear process, the game permission flag will not be set to ON.

[9-4. Expansion example 3]
The pachinko game machine of expansion example 3 is a pachinko game machine that has two routes for being controlled to a jackpot game state, and therefore has a specific area where a specific opening is provided. This specific area is separated from the downstream area of the game ball by, for example, an accessory, and it is normally difficult (or impossible) for the game ball to enter the specific area. In addition to the jackpot, a small win is also prepared as a result of the jackpot determination of the special symbol.

Specifically, the main CPU performs a jackpot determination of a special symbol with a jackpot probability determined according to a set value, and when the result of this jackpot determination is a loss, performs a small hit determination. Then, when the result of the small win determination is a small win, a small win game is executed. That is, the above-mentioned jackpot is a hit that involves the operation of a conditional device, but the above-mentioned small hit is not a hit that involves the operation of a conditional device.

In addition, in this expansion example 3, for example, in a normal game state such as a non-time saving game state where the time saving flag is set to OFF, the first special symbol game based on the winning of the game ball to the first starting hole, and the second The first special symbol game is mainly played among the second special symbol game based on winning of the game ball in the starting hole. On the other hand, in a probability variable time saving game state such as a time saving game state where the time saving flag is set to ON, the second special symbol game is mainly played between the first special symbol game and the second special symbol game. Furthermore, in the second special symbol game, when the result of the jackpot determination is a loss, the player wins a small hit with a predetermined probability. Note that when the result of the jackpot determination in the first special symbol game is a loss, there is no need to perform a small hit determination.

In addition, if the result of the jackpot determination for the special symbol, which is performed based on the entry (acceptance) of the game ball into the starting hole, is a small hit, the main CPU operates a predetermined movable piece to move the inside of the specific area. A small winning game execution means is provided for executing a small winning game that allows a game ball to enter the game ball. When the predetermined movable piece operates in this way, a game ball enters the specific area, and when the game ball that has entered the specific area is detected to have entered (accepted) into the specific opening, the main The CPU controls the jackpot game state. That is, when the result of the jackpot determination process performed based on the winning of the game ball in the starting slot is a jackpot, the main CPU executes a first jackpot game in which a round game in which the jackpot is opened is played over multiple rounds. a first jackpot game control means that controls the state, and a round game that operates the predetermined movable piece over a plurality of rounds based on the fact that a game ball enters the specific opening when the small win game is executed. and second jackpot game control means for controlling the second jackpot game state to be played.

In such a pachinko game machine, in this expansion example 3, the ease of winning a game ball into the starting hole (for example, the frequency of execution of small winning games, the release pattern of normal electric accessories) is set to a set value. It differs depending on the situation. In addition, in this extended example 3, the main CPU determines that the result of the normal symbol determination, which is performed based on the fact that the game ball passes through a gate that can be passed when the player hits the right ball, is a normal hit. Sometimes, normally electric accessories are controlled from a closed state to an open state. When the normal electric accessory is in the open state, it becomes easier to put the game ball into the starting hole. As a method of varying the execution frequency of small winning games depending on the set value, for example, the probability of a normal hit in normal symbol judgment may be varied depending on the set value, or the fluctuation time of the normal symbol may be varied depending on the set value. This can be achieved by

As a method for varying the ease with which a game ball enters the starting hole in accordance with a set value, a method for varying the probability of a normal win in normal symbol determination according to a set value will be described as an example.

For example, the probability of winning normally is 1/60 for setting 1, 1/50 for setting 2, 1/40 for setting 3, 1/30 for setting 4, 1/20 for setting 5, and 1/20 for setting 6. 1/10. In this case, the higher the setting value is, the longer the fluctuation time of the normal symbol is, or the higher the setting is, the longer the normal symbol fluctuation time is, or the higher the setting is, the more difficult the opening mode of the normal electric accessory is to make it difficult for the game ball to enter the starting hole. It becomes easier for game balls to enter the starting slot. As a result, the higher the setting value is, the higher the frequency of execution of the small winning game becomes, and the chance of being controlled to a jackpot gaming state by the second jackpot game control means is promoted. In this way, it is possible to provide a difference in ball delivery speed depending on the set value.

In addition, also in this extended example 3, if a game ball enters the first starting hole or the second starting hole while the in-CPU 101 is performing a variable display of special symbols, the setting check process of step S72 or step S82 is executed. executed. If the main CPU 101 determines that it is not normal in this setting check process (NO in step S721), the main CPU 101 turns off the game permission flag even if the result of the jackpot determination for the special symbol that is being displayed in a variable manner is a small hit. Execute abnormality processing. Therefore, even if the result of the jackpot determination for the special symbol being displayed in a variable manner is a small hit, if it is determined in the setting check process that it is not normal, the main CPU 101 executes the small win game based on the small win. The game permission flag is turned OFF without any problem, and abnormality processing is executed. Therefore, the game permission flag will not be set to ON unless various data, including the fact that the result of jackpot determination for the special symbol being displayed in a variable manner is a small hit, are cleared in the backup clear process.

[9-5. Expansion example 4]
In the pachinko gaming machine of expansion example 4, even if the result of the jackpot determination of the special symbol is a jackpot, the control is not immediately controlled to the jackpot gaming state just because of that, but the result of the jackpot determination of the special symbol is a jackpot. The condition device is activated based on the condition device, and the accessory continuous activation device is activated based on the game ball passing (or entering) a predetermined area on the premise that the condition device is activated. This will be explained below with reference to FIGS. 59 and 60. FIG. 59 is a diagram showing an example of a mode in which a game ball passes through the right gate of continuous operation of the accessory, and FIG. 60 is a diagram showing an example of a mode in which the game ball passes through the left gate of continuous operation of the accessory.

As shown in FIGS. 59 and 60, the pachinko game machine of this expanded example 4 is equipped with a left gate 1100 for continuously operating an accessory and a right gate 1110 for continuously operating an accessory in the game area. Further, a sorting device 1120 capable of sorting the game balls flowing down the game area to either the accessory continuous operation left gate 1100 or the accessory continuous operation right gate 1110 is configured to include the accessory continuous operation gate 1100, It is located above 1110.

The accessory continuous operation left gate 1100 and the accessory continuous operation right gate 1110 are each provided with a left gate sensor and a right gate sensor (both not shown) that can detect passage of a game ball. Normally, the left gate sensor and the right gate sensor are disabled in detecting passage of a game ball, but are enabled based on the activation of the condition device. Further, the left gate sensor and the right gate sensor are activated based on the activation of the condition device, and then the game ball moves either of the accessory continuous operation left gate 1100 or the accessory continuous operation right gate 1110. Disabled based on detection of passing.

When the left gate sensor detects passage of a game ball to the accessory continuous operation left gate 1100, the main CPU controls to an 8R jackpot game state in which a round game of 8 rounds is executed, for example. In addition, when the right gate sensor detects the passage of the game ball to the right gate 1110 that continuously operates the accessory, the main CPU selects the 2R jackpot game state (selection rate 50%) in which 2 rounds of round games are executed, and the 16 rounds. Which of the 16R jackpot game states (selection rate 50%) in which round games are executed is determined by lottery, and the jackpot game state determined by the lottery is controlled.

In addition, a jackpot occurs when the left gate sensor detects the passing of the game ball to the left gate 1100 that continuously operates the accessory and when the right gate sensor detects the passage of the game ball to the right gate 1110 that continuously operates the accessory. The expected value of the amount of prize balls paid out in the game state is the same.

In addition, the game balls that have passed through the left gate 1100 for continuous action of the accessory object or the right gate 1110 for continuous action of the accessory flow down the gaming area as they are, but are instead discharged outside the pachinko game machine from the exit port. It may be configured as follows.

The sorting device 1120, by regular operation, sorts the game balls that have arrived above the sorting device 1120 to either the accessory continuous action left gate 1100 or the accessory continuous action right gate 1110. In the first position in which the sorting device 1120 is tilted to the left, the game ball easily passes through the right gate 1110 (see FIG. 59), and in the second posture in which the sorting device 1120 is tilted to the right, the game ball is easy to pass through the right gate 1110 (see FIG. 59). It is easy for objects to pass through the continuous operation left gate 1100 (see FIG. 60).

In this extended example 4, the ease with which a game ball can pass is made different between the accessory continuous operation left gate 1100 and the accessory continuous operation right gate 1110, depending on the set value. For example, in setting 1, the operation of the sorting device 1120 is a repeating operation of 0.5 seconds in the first posture and 1.5 seconds in the second posture, and in setting 2, the operation is repeated for 0.7 seconds in the first posture and 1.3 seconds in the second posture. In setting 3, the action repeats 0.9 seconds in the first posture and 1.1 seconds in the second posture, and in setting 4, the action repeats 1.1 seconds in the first posture and 0.9 seconds in the second posture. In setting 5, the first posture is repeated for 1.3 seconds and the second posture is 0.7 seconds, and in setting 6, the first posture is repeated for 1.5 seconds and the second posture is repeated for 0.5 seconds. Therefore, it is possible to change the aspect of the jackpot game state according to the set value.

In addition, in this expansion example 4, when the left gate sensor detects the passing of the game ball to the left gate 1100 of continuous action of the accessory, and the right gate sensor detects the passage of the game ball to the right gate 1110 of the continuous action of the accessory. The expected value of the amount of prize balls paid out in the jackpot game state is the same. In other words, although it is possible to change the aspect of the jackpot game state according to the set value, there is no difference in the amount of prize balls paid out in the jackpot game state according to the set value, but the left gate sensor is paid out in the jackpot game state when the game ball detects passage of the game ball to the left gate 1100 of the continuous action of the accessory and when the right gate sensor detects the passage of the game ball to the right gate 1110 of the continuous action of the accessory. The expected value of the amount of prize balls may be different. For example, when the left gate sensor detects the passage of a game ball to the left gate 1100 that continuously operates the accessory, it is possible to select one of the 2R jackpot gaming state (selection rate 70%) and the 16R jackpot gaming state (selection rate 30%). It is determined by a lottery held at the selection rate as described above, and when the right gate sensor detects the passing of the game ball to the right gate 1110 that continuously operates the accessory, the 2R jackpot game state (selection rate 30%) It is also possible to decide which of the 16R jackpot game state (selection rate 70%) to be executed by a lottery conducted at the above-mentioned selection rate. In this case, it is possible to make a difference in the amount of prize balls paid out in the jackpot game state according to the setting value, and the higher the setting value, the higher the expected value of the jackpot game state in which a large amount of game balls are paid out as prize balls. This makes it possible to increase the possibility of

In addition, in this expansion example 4, when the game ball passes through either of the two gates (accessory object continuous operation left gate 1100, accessory object continuous operation right gate 1110) under the condition that the condition device is activated, the accessory object continuous operation is activated. The device is configured to operate and be controlled to a jackpot gaming state. However, even if the conditional device is activated based on the result of the jackpot judgment of the special symbol based on the winning of the game ball in the starting gate, the game ball does not hit either of the above two gates. A game ball may land in the starting slot before passing through. In this case, under the condition that the condition device has been activated but the game ball has not yet passed through either of the two gates, the main CPU 101 performs a setting check process (for example, (see step S72 in FIG. 42), and the setting check process may determine that the setting is not normal (for example, NO in step S721 in FIG. 43). In this case, even if the conditional device is activated, the main CPU 101 turns off the game permission flag (step S722, which will be described later), making it impossible to proceed with the game.

In addition, in this expansion example 4, below the sorting device 1120, there are two gates (accessory continuous activation device) that operate when the passage of a game ball is detected on the premise that the condition device is activated. Although a left gate 1100 and a right gate 1110 for continuous operation of accessories are provided, what is provided below the sorting device 1120 is not necessarily limited to the continuous operation of accessories, but for example, a starting opening and a general winning opening. Also good. In other words, in this case, the sorting device 1120, through regular operation, divides the game balls that have reached the upper part of the sorting device 1120 into the starting hole, which is the trigger for determining the jackpot of the special symbol, and the general winning hole, which is not the trigger for determining the jackpot. Divide between mouth and mouth. Then, the operation of the sorting device 1120 is, for example, in setting 1, the operation of repeating the first posture for 0.5 seconds and the second posture for 1.5 seconds, and in the setting 2, the operation of repeating the first posture for 0.7 seconds and the second posture for 1. In setting 3, the action repeats 0.9 seconds in the first posture and 1.1 seconds in the second posture, and in setting 4, the action repeats 1.1 seconds in the first posture and 0.9 seconds in the second posture. Setting 5 is an action that repeats the first posture for 1.3 seconds and second posture 0.7 seconds, and setting 6 is an action that repeats the first posture for 1.5 seconds and the second posture for 0.5 seconds. By doing so, it is possible to vary the winning rate in the starting slot depending on the set value. Moreover, according to such pachinko gaming machines, although it is possible to vary the winning rate in the starting slot depending on the set value, no matter what the set value is, the timing at which the game ball is launched by the player may vary. It is possible to add the fun of being able to aim for winning the starting slot.

[9-6. Expansion example 5]
The pachinko game machine of expansion example 5 does not change the data related to the basic specifications of the pachinko game machine according to the setting values, but allows the game performance of the pachinko game machine to be changed according to the setting values. . In addition, in this extended example 5, the configuration is such that the setting value can be set to any one of the five stages from setting 1 to setting 5, but it does not necessarily have to be five stages, and it can be set to multiple stages. It can be determined arbitrarily.

Specifically, when the setting value is set to 1, the main CPU performs a jackpot judgment for a special symbol with a probability of, for example, 1/99, and if the result of the jackpot judgment is a jackpot, the main CPU executes, for example, 5 rounds. Control to a jackpot gaming state. In other words, when the setting value is set to 1, the jackpot probability is relatively high at less than 1/100, but the amount of prize balls paid out in one jackpot game state is relatively small, which is called a sweet digital game. It becomes possible to play a game-like game.

In addition, when the setting value is set to setting 2, the main CPU performs a jackpot judgment of a special symbol with a probability of, for example, 1/300, and if the result of the jackpot judgment is a jackpot, the main CPU performs a jackpot judgment, for example, for 12 rounds (e.g., The game is controlled to a jackpot game state of approximately 1,500 pieces. In other words, when the setting value is set to setting 2, the jackpot probability is 1/300, and the amount of prize balls paid out in one jackpot game state is about 1,500, which is a game with a general game style called DigiPachi. It becomes possible to execute. In this gaming machine, the main CPU controls the gaming state to a high-probability gaming state after the jackpot gaming state ends, and when a predetermined period has elapsed, the high-probability gaming state ends and changes to a low-probability gaming state. Control. That is, when the setting value is set to setting 2, it becomes possible to play a game with a so-called ST machine.

In addition, when the setting value is set to setting 3, the main CPU performs a jackpot judgment of a special symbol with a probability of, for example, 1/300, and if the result of the jackpot judgment is a jackpot, the main CPU executes a jackpot judgment, for example, for 12 rounds (e.g., The game is controlled to a jackpot game state of approximately 1,500 pieces. In other words, when the setting value is set to setting 2, the jackpot probability is 1/300, and the amount of prize balls paid out in one jackpot game state is about 1,500, which is a game with a general game style called DigiPachi. It becomes possible to execute. In this gaming machine, when the result of the jackpot determination is a jackpot, the main CPU determines whether or not to set the probability variation flag to ON using, for example, a symbol random number, and when the probability variation flag is set to ON, the jackpot game After the state ends, the game state is controlled to a high probability game state until the next jackpot game state is executed. That is, when the setting value is set to setting 3, it becomes possible to play a game with a so-called fixed loop machine.

In addition, when the setting value is set to setting 4, the main CPU performs a jackpot judgment of a special symbol with a probability of 1/300, for example, and if the result of the jackpot judgment is a jackpot, the main CPU performs a jackpot judgment for example 12 rounds (for example, The game is controlled to a jackpot game state of approximately 1,500 pieces. In other words, when the setting value is set to setting 2, the jackpot probability is 1/300, and the amount of prize balls paid out in one jackpot game state is about 1,500, which is a game with a general game style called DigiPachi. It becomes possible to execute. In this gaming machine, when the result of the jackpot determination is a jackpot, the main CPU determines whether or not to set the probability variation flag to ON using, for example, a symbol random number, and when the probability variation flag is set to ON, the jackpot game After the state ends, the game state is controlled to a high probability game state until the next jackpot game state is executed. However, an upper limit is set on the number of times that the jackpot gaming state and the high probability gaming state are repeatedly executed (the above-mentioned "loop number"), and when the loop number reaches this upper limit, the main CPU will notify that the jackpot gaming state has ended. The current gaming state is controlled to a low probability gaming state. That is, when the setting value is set to setting 4, it becomes possible to play a game with a so-called limiter game. In addition, in the above game, if the gaming state after the jackpot gaming state ends is a high probability gaming state, the high probability gaming state continues until the next jackpot gaming state is executed. However, the present invention is not limited to this, and may be a so-called ST machine in which a high probability gaming state after a jackpot gaming state ends is controlled to a low probability gaming state after a predetermined period has elapsed.

In addition, when the setting value is set to setting 5, the main CPU performs a jackpot judgment of a special symbol with a probability of, for example, 1/300, and if the result of the jackpot judgment is a jackpot, the main CPU executes, for example, 12 rounds (for example, a ball is put out). The game is controlled to a jackpot game state of approximately 1,500 pieces. In other words, when the setting value is set to setting 2, the jackpot probability is 1/300, and the amount of prize balls paid out in one jackpot game state is about 1,500, which is a game with a general game style called DigiPachi. It becomes possible to execute. In this gaming machine, when the jackpot gaming state ends, the main CPU always or with a certain probability sets the probability variation flag to ON, and when the probability variation flag is set to ON, the main CPU sets the gaming state after the jackpot gaming state ends. , control to a high probability gaming state. In addition, the main CPU performs a game state transition lottery when determining a jackpot for a special symbol in a high probability game state, and when it is determined to change the game state in the game state transition lottery, it sets the probability change flag to OFF. , executes control to shift from a high probability gaming state to a low probability gaming state. That is, when the setting value is set to setting 5, it becomes possible to play a game in which a lottery for transition to a low probability game state is performed in a high probability game state.

In this way, the pachinko game machine of expansion example 5 can change the game play of the pachinko game machine according to the setting value, rather than the specifications such as jackpot probability, making it possible to play pachinko with a wide variety of game play. It becomes possible to run the game on one device.

In addition, in the above, in setting 1, it is possible to play a game with a so-called sweet digital game, in setting 2, it is possible to play a game with a so-called ST machine game, and in setting 3, a game with a so-called ST machine can be played. It is possible to execute a game with a game characteristic called a variable loop machine, and with setting 4, it is possible to execute a game with a game characteristic called a so-called limiter machine, and with setting 5, it is possible to execute a game with a game characteristic called a limiter machine, and with a setting 5, it is possible to execute a game with a game characteristic called a limiter machine. Although it is possible to play a game with a game feature in which a lottery for transition to a probability game state is performed, it is not essential to be able to execute all of these game features in accordance with set values. However, it is preferable to be able to switch between a so-called ST game style and a so-called fixed variable loop game style depending on the setting value. The so-called ST machine game and the so-called fixed loop machine have a common feature in that they may be controlled to a high probability game state after the end of the jackpot game state, but the high probability game state is It makes a big difference whether the game continues until the next jackpot game state or ends midway. In this way, by making it possible to switch between two seemingly similar but substantially different game features, it allows game machine managers and others to have more flexibility in how they utilize pachinko machines. It is possible to provide a pachinko game machine that can improve the player's interest at the same time.

[9-7. Other expansion examples]
The present invention can be applied to the pachinko game machine 1 of this embodiment to all types of game machines in which a game is played using game media and a benefit is awarded based on the result of the game. That is, not only is the game played by ejecting or inserting game media through the physical actions of the player, and the game media are paid out based on the result of the game, but the main control circuit 100 itself It may also be possible to electromagnetically manage game media owned by a player, and to enable games played by circulating enclosed game balls or games played without medals. Further, the device that electromagnetically manages the game media owned by the player may be a game media management device that is attached to (connected to) the main control circuit 100 and manages the game media.

When managed by a gaming media management device connected to the main control circuit 100, the gaming media management device is a device that has a ROM and RWM (or RAM) and is installed in the gaming machine, It is connected to a two-way communication function via a media handling device and a predetermined interface, and provides the gaming media necessary for the gaming media lending operation (i.e., when the player performs the gaming media insertion operation). operation) or the payout operation of the game media when a prize is won (the role is established) related to the payout of the game media (i.e., payout of the game media to the player and win the necessary game media) It may be possible to perform an operation of electromagnetically recording a game medium used for a game. In addition, the game media management device not only manages the actual number of game media, but also displays the number of game media held on the front of the pachinko gaming machine 1 based on the management result of the number of game media. A game media number display device (not shown) may be provided, and the number of game media displayed on this owned game media number display device may be managed. In other words, the game media management device may be capable of recording and displaying the total number of game media that can be used by a player in a game using an electromagnetic method.

In addition, in this case, the game media management device has the ability to allow the player to freely transmit a signal indicating the number of recorded game media to the external game media handling device, and In addition to being operated directly by a person, the number of recorded game media cannot be reduced, and an external connection terminal board (not shown) is provided between the player and an external game media handling device. In some cases, it is desirable to have the ability to allow a player to transmit a signal indicating the number of recorded game media except through the external connection terminal board.

In addition to the above, the gaming machine is equipped with a lending operation means, a return (payment) operation means, and an external connection terminal board that can be operated by the player, and the gaming media handling device has an input slot for valuables such as banknotes, and a recording medium. (For example, an IC card) insertion slot, a non-contact communication antenna for depositing electronic money etc. from a mobile terminal, various operation means such as lending operation means, return operation means, external connection terminal board on the side of the gaming media handling device. (both not shown).

The flow of the game at that time is, for example, when the player deposits valuable value into the gaming media handling device using one of the methods, and subtracts a predetermined number of valuable values based on the operation of one of the lending operation means described above. Then, the amount of game media corresponding to the value subtracted from the game media handling device to the game media management device is increased. The player then plays the game and repeats the above operations if more game media are required. After that, as a result of the game, a predetermined number of game media are acquired, and when the game is finished, the number of game media is transmitted from the game media management device to the game media handling device by operating one of the return operation means, and the game The medium handling device ejects the recording medium on which the number of game media is recorded. When the game media management device transmits the number of game media, it clears the number of game media stored in itself. The player takes the ejected recording medium to a prize counter or the like to exchange it for prizes, or moves the game machine to play a game based on the game medium recorded on another machine.

In the above example, all game media are sent to the game media handling device, but the game machine or game media handling device only transmits the number of game media desired by the player, and the game media owned by the player is transmitted. It is also possible to divide and process. Furthermore, instead of just ejecting the recording medium, cash or cash equivalent may be ejected, or it may be stored in a mobile terminal or the like. Further, the game media handling device may be configured to be able to insert a member recording medium of a gaming parlor, and to store the membership recording medium in the member recording medium so that it can be played again at a later date.

Further, in the gaming machine or the gaming media handling device, by operating a predetermined operation means (not shown), a locking operation for locking the data communication of gaming media or valuable value can be performed on the gaming media handling device or the gaming media management device. Good too. In this case, information that only the player can know, such as a one-time password, may be set, or the player may be recorded using an imaging means provided in the game medium handling device.

In addition, although the above describes the case where the game media management device is applied to a pachinko game machine, the game media management device can also be applied to a pachislot machine, a slot machine that uses game balls, and an enclosed game machine. A player's gaming media can also be managed.

In this way, by providing the above-mentioned game media management device, the number of parts inside the game machine can be reduced compared to the case where game media are physically used in the game, and the cost and manufacturing cost of the game machine can be reduced. Not only can players be prevented from coming into direct contact with gaming media, the gaming environment can be improved, noise can be reduced, and the power consumption of gaming machines can also be reduced by reducing the number of parts. It also happens. In addition, it is possible to prevent fraudulent acts through the game media and the game media input and payout ports. That is, it is possible to provide a gaming machine that can improve various environments surrounding the gaming machine.

In addition, communication cables are used to transmit data regarding increases and decreases in gaming media due to consumption, lending, and payout of gaming media to enclosed gaming machines that are configured to allow gaming without the gaming media being ejected to the outside. When the present invention is applied to a gaming system having a gaming media management device connected to the gaming media management device so as to be able to transmit and receive optical signals via the gaming media management device, the gaming system may be configured as follows.

Below, an outline of the enclosed gaming machine will be explained. In the enclosed game machine, the firing device is located above the game area and fires game balls as game media from above into the game area. When the player operates the handle, the ball feed solenoid is driven by the payout control circuit, and the ball feed pestle pushes out the waiting game ball toward the launch pad. This moves the game ball to the launch pad. Further, a subtraction sensor is provided on the path from the standby position to the launch pad, and detects the game ball moving to the launch pad. When a game ball is detected by the subtraction sensor, the number of balls held is subtracted by 1. Since the game ball is thus configured to be launched from above as a game medium into the game area, so-called return balls (foul balls) can be avoided in the enclosed game machine. The game balls ejected from the game area after rolling in the game area are polished by a ball polishing device. The game balls polished by the ball polishing device are transported upward by the lifting device and guided to the firing device. The game balls are not discharged to the outside of the enclosed game machine, but are configured so that a certain number (for example, 50) of game balls circulate through a series of paths in the game machine.

In an enclosed type game machine, the game balls are not discharged to the outside of the game machine, so an upper tray or a lower tray for temporarily holding the game balls is not provided. In an enclosed game machine, the game balls are not discharged to the outside, so the game balls are not actually in the hands of the player, and the number of game balls does not actually increase or decrease as a result of playing a game. In an enclosed game machine, a player starts playing after acquiring balls lent from a game media management device. Here, obtaining a ball means that the player obtains game media in terms of data management. Then, by firing the game balls from the firing device, the balls held are consumed, and the number of balls held decreases. In addition, when the game balls pass through each winning hole provided in the gaming area, the number of balls is paid out in accordance with the conditions set according to the winning hole, and the number of balls held increases. Furthermore, the number of balls held increases by lending from the game media management device. Note that "consumption, lending, and payout of game media" indicates that the balls held are consumed, loaned, and paid out. Further, "increase/decrease in game media" indicates an increase/decrease in the number of balls held due to consumption, lending, and payout. Furthermore, "data regarding increases and decreases in game media due to consumption, lending, and payout of game media" is data regarding the decrease in the number of balls held due to game balls being fired and the increase in the number of balls held due to lending and payout.

The enclosed gaming machine has a payout control circuit and a touch panel type liquid crystal display device. The payout control circuit is connected to various sensors that detect when the game ball passes through each winning hole. The payout control circuit manages the number of balls held. For example, when a game ball passes through each winning hole, the number of game balls paid out due to this is added to the number of balls held. Furthermore, when a game ball is fired, the number of balls held is subtracted. The payout control circuit transmits data regarding the number of balls held to the game media management device by the player's operation. Further, the above liquid crystal display device is located at the top of the gaming machine, and accepts requests for converting the gaming value managed by the gaming media management device into balls held (renting balls) and counting balls held (returning). Then, these requests are transmitted to the payout control circuit via the game media management device, and the payout control circuit is instructed to transmit data regarding the current number of balls held to the game media management device. Here, "gaming value" refers to money/banknotes, prepaid media, tokens, electronic money, tickets, etc., which can be converted into balls by the gaming media management device. In this embodiment, the game media management device is a so-called CR unit, and is configured to be able to accept banknotes, prepaid media, and the like. Further, the counted balls can be used for exchanging prizes, etc. at a game hall where the game system is installed.

Furthermore, the enclosed gaming machine has a backup power source. As a result, even if the power is turned off at night, the data immediately before the power is turned off can be retained. Further, by using this backup power source, for example, the door opening sensor may continue to detect the opening of the door frame. This can also prevent fraudulent acts at night. In this case, information such as the number of times the door frame has been opened may be stored. Furthermore, when the power is turned on, information such as the number of times the door frame has been opened may be output to a liquid crystal display device or the like of the gaming machine.

The gaming media management device has a gaming machine connection board. The game media management device is configured to transmit and receive data (transmission signals) to and from the game machine via the game machine connection board. The transmitted and received data includes the unique ID of the CPU provided in the main control circuit, the unique ID of the CPU provided in the payout control circuit, the gaming machine manufacturer code stored in the gaming machine, the security chip manufacturer code, and the gaming machine manufacturer code stored in the gaming machine. This is information such as the model code of the machine. Then, when the transmission source transmits a transmission signal with one of the gaming machine and the gaming media management device as the transmission source and the other as the transmission destination, the transmission destination that received the transmission signal receives the same signal as the transmission signal. A confirmation signal is transmitted to the transmission source, and the transmission source compares the transmission signal and the confirmation signal to determine whether or not they are the same.

In this way, by comparing the confirmation signal sent from the destination with the transmission signal at the transmission source and determining whether they are the same, the signal transmitted from the transmission source can be prevented from being tampered with. You can confirm that the message is being sent to the sender. Thereby, fraudulent acts such as tampering with transmission/reception signals between the gaming machine and the gaming media management device can be suppressed.

Further, in the gaming system, the transmission source has a modulation section that modulates a signal, and the transmission source transmits the signal modulated by the modulation section as the transmission signal, and the transmission destination transmits the signal modulated by the modulation section. It is also possible to include a demodulation section that performs demodulation.

As a result, even if the transmission and reception signals between the gaming machine and the gaming media management device were read, it would be difficult to decipher the signals, and the transmission and reception signals between the gaming machine and the gaming media management device would be difficult to decipher. Fraudulent acts such as falsification can be suppressed.

In addition, in the gaming system, when the transmission destination receives the transmission signal from the transmission source, the transmission destination sends an approval signal, which is a signal indicating that the transmission signal has been received, separately from the confirmation signal. It may also be sent to the sender.

By comparing the transmitted signal and the confirmation signal, it is possible to not only confirm that a legitimate signal has been transmitted and received, but also to confirm that a legitimate signal has been transmitted and received based on the authorization signal. Therefore, it is possible to further strengthen the suppression of fraudulent acts.

[10. Processing executed by host control circuit]
Next, the contents of various processes executed by various control circuits in the sub-board 2020 (see FIG. 10, for example) of the sub-control circuit 200 will be described. Note that the sub-control circuit 200 receives various commands transmitted from the main control circuit 100 (see, for example, FIG. 10), and performs various processes based on these various commands.

In the following, first, processes related to various devices etc. will be explained, and then processes related to the hall menu task will be explained. Note that both the processing related to the hall menu task and the processing related to various devices are executed by the host control circuit 2100 (more specifically, the CPU processor included in the host control circuit 2100), but for convenience of explanation, Each will be explained using separate flowcharts.

[10-1. Processing related to various devices, etc.]
Processing related to various devices will be described with reference to FIGS. 61 to 99. 61, FIG. 72, FIG. 73, FIG. 74, and FIG. 98, including FIG. 52 described above, all show an example of the sub-control main processing (overall flow) executed when the power is turned on. FIG. These are all processes executed by the host control circuit 2100 (more specifically, the CPU processor included in the host control circuit 2100), but for convenience of explanation, the processes are omitted as appropriate depending on various situations. For example, in FIGS. 52 and 61, the accessory control process (step S210, step S1213) is illustrated, but in FIGS. 72, 73, 74, and 98, illustration of the accessory control process is omitted. Furthermore, in FIGS. 61, 72, 73, 74, and 98, even the same processing is given different numerals for convenience of explanation. For example, to explain initialization processing as an example, various initialization processing (step S1201) in FIG. 61, initialization processing (step S1381) in FIG. 72, initialization processing (step S1391) in FIG. 74, and initialization processing in FIG. The initialization process (step S401) is essentially the same initialization process, and to explain the accessory control process as an example, the accessory control process (step S210) in FIG. 52 and the accessory control process (step S210) in FIG. Step S1213) is essentially the same process.

As shown in FIG. 61, the host control circuit 2100 performs various initialization processes (step S1201). In this process, the host control circuit 2100 performs various initial setting processes such as, for example, hardware initialization processing, device initialization processing, various application initialization processing, backup data restoration initialization processing, and RTC acquisition processing. conduct. Note that when the game data is erased by clearing the RAM, random number initialization processing is also performed. Furthermore, the host control circuit 2100 clears the counter of the watchdog timer each time each initialization process is completed. Note that at startup, a watchdog timer reset time is set, and if no service pulse is written after that (timeout), power-off processing is performed. Further, the timing to clear the watchdog timer is at the start of each process in the main loop in the sub-control main process, at the start of each initialization process, and at the time of transition to the power-off process.

Next, the host control circuit 2100 enters the main loop and performs an RTC acquisition process based on the RTC time, that is, a process to acquire the current time (step S1202).

The host control circuit 2100 performs random number initialization processing in step S1203. This random number initialization process will be described later.

The host control circuit 2100 acquires the control code of the accessory in step S1204, and performs a synchronization process between the accessory and the solenoid (step S1205). These processes will be explained in "accessory object solenoid control process" below.

The host control circuit 2100 performs subdevice input processing in step S1206. In this process, the host control circuit 2100 performs an operation content information acquisition process based on the input state of the operation means (determination process of whether or not the player has performed an operation on the operation means such as a button). etc. This sub-device input processing (step S1206) includes brightness adjustment of LEDs and the like by operations by the player and the like.

The host control circuit 2100 performs various request control processes in step S1207. In this process, the host control circuit 2100 performs various request control processes such as a sound request control process, an LED request control process, an accessory request control process, and an accessory control process. Note that the sound request, LED request, accessory request, etc. are stored in a buffer and output to each device after a bank flip in step S1214, which will be described later. This allows synchronization with drawing. Note that a bank flip is a process of switching the function of one frame buffer from a drawing function to a display function, and switching the function of the other frame buffer from a display function to a drawing function.

By the way, in addition to being performed in various request control processes (S1207), the accessory control process is shown to be performed in step S1213 after the drawing control process (step S1212) in FIG. What is performed in step S1213 after step S1212) is not essential. In the accessory processing, considering that the accessory requests stored in the buffer in the animation construction processing (step S1210) and the animation update processing (step S1211) one frame before are output, the animation construction processing (step S1210) Preferably, this is also done before. However, if the accessory request stored in the buffer is to be output in the same frame as the frame stored in the buffer, the accessory control process is performed in step S1213 after the drawing control process (step S1212). Also good.

Next, the host control circuit 2100 enters the packet reception loop in the main loop and performs main-sub command control processing (step S1208). In this process, the host control circuit 2100 performs a process of reading command data (command reception process) when receiving command data from the main CPU 101 and a process of storing the command data in the sub-work RAM 2100a (received data storage process).

The host control circuit 2100 performs game data backup processing in step S1209. In the pachinko gaming machine 1 of this embodiment, first data (magic code, program version, and SUM value) and second data (magic code, which is information set in the hole menu) are used as game data for RAM clear determination. and SUM value). In the game data backup process, the first data is saved in the game data and then backed up to the SRAM 2100b (see FIG. 10). The game data is also backed up (mirrored) in another area of the SRAM 2100b. After the power is turned on, the game data is restored from the data backed up to the SRAM 2100b. At this time, the first data is used to check whether there is any damage to the backed up data. If the backed up data is damaged, check whether the second data is damaged. At this time, all data stored in the SRAM 2100b, such as hall menu information, is also initialized.

Next, the host control circuit 2100 performs animation construction processing (step S1210). In this process, the host control circuit 2100 performs command analysis, status setting, and lottery processing, and upon receiving these processes, generates an animation request necessary for performing production control using the display device 16, and generates an animation request necessary for performing production control using the display device 16. In response to the performance control (display) on the display device 16 executed based on the above, various requests (drawing request, sound request, LED request, and accessory request) for operating various performance devices are generated.

The host control circuit 2100 executes the processes from step S1208 to step S1210 until the process is executed for the number of received commands, and exits the packet reception loop when the process is executed for the number of received commands. Thereafter, the host control circuit 2100 performs animation update processing (step S1211), drawing control processing (step S1212), accessory control processing (step S1213), and waiting for bank flip/bank flip completion (step S1214), and then enters the main loop. Each process is repeated.

The host control circuit 2100 repeatedly executes the above-described example process of steps S1202 to S1214 (main loop process) at a predetermined FPS cycle. Note that the FPS cycle is set to, for example, approximately 16.7 msec (60 FPS), approximately 33.3 msec (30 FPS), etc. The predetermined FPS period is time adjusted in step S1214.

The following are timer interrupt processing, subdevice input processing, backlight control processing, brightness adjustment of the backlight and various LEDs, RTC acquisition processing, composition playback control, sound amplifier control processing, and sound request control processing (for the same channel). (when there are multiple sound requests), sound request control processing (when volume adjustment is performed), LED brightness adjustment processing, accessory solenoid control processing, data loading processing, and sub random number processing will be described in this order. Note that the order of explanation of each of the above-mentioned processes is different from the order of processing for convenience of explanation.

[10-2. Timer interrupt processing]
In the pachinko gaming machine 1 of this embodiment, the host control circuit 2100 performs interrupt processing at a cycle of 1 msec. Interrupt processing will be explained in each process described later, but here, an example of a typical interrupt processing will be briefly explained with reference to FIG. 62. FIG. 62 is a flowchart showing an example of timer interrupt processing executed by the host control circuit (sub control circuit). Note that in the timer interrupt process briefly described with reference to FIG. 62 and the timer interrupt process described later (see FIGS. 69 and 71), different codes are given for convenience of explanation even if the processes are the same. For example, to explain the accessory motor control as an example, the accessory motor control (step S1251) in FIG. 62, the accessory motor control (step S1352) in FIG. 69, and the accessory motor control (step S1371) in FIG. are essentially the same process, but are given different symbols.

Referring to FIG. 62, in the timer interrupt process, host control circuit 2100 first performs accessory motor control (step S1251). Next, the host control circuit 2100 performs input state determination processing based on the input information of the subdevice (step S1252). Next, the host control circuit 2100 performs control processing, such as the backlight of the liquid crystal display device used as the display device 16, based on the brightness value (step S1253). Next, the host control circuit 2100 performs a sound amplifier check process (step S1254).

[10-3. Subdevice input processing]
In this embodiment, the host control circuit 2100 creates sub-device input discrimination information in main processing every 33.3 msec based on the input state of the sub-device detected by a timer interrupt every 1 msec. The subdevice is controlled based on the subdevice input discrimination information.

When the host control circuit 2100 detects the input state of the subdevice using a timer interrupt every 1 msec, the host control circuit 2100 generates subdevice input information and subdevice input information as the subdevice input discrimination information created in the main processing based on the detection result. Input ON edge information, sub device input ON edge information (with repeat function), and sub device input OFF edge information are created.

The sub device input process shown in FIG. 61 will be described below with reference to FIGS. 63 to 66. The subdevices are controlled by the host control circuit 2100 based on input (eg, manipulation) information, such as push buttons. Note that FIG. 63 is a diagram illustrating an example of the sub-device input discrimination information that is created. (c) Diagram showing sub-device input ON edge information created in main processing; (c) Diagram showing sub-device input ON edge information (with repeat function) created in main processing (d) is a diagram showing sub-device OFF edge information created in main processing. FIG. 64 is a flowchart illustrating an example of subdevice input processing. FIG. 65 is a flowchart illustrating an example of sub-device input ON edge information (with repeat function) processing. FIG. 66 shows an example of sub-device input ON edge information (with repeat function) processing, and is a flowchart continued from FIG. 65.

The subdevice input information created in the main process is created in accordance with the subdevice input state detected by the timer interrupt (see FIG. 63(a)), as shown in FIG. 63(b). That is, when the subdevice input state detected by the timer interrupt is ON, 1 is set. Further, if the subdevice input state detected by a timer interrupt is OFF, 0 is set.

As shown in FIG. 63(c), the sub device input ON edge information is set to 1 for only one frame in the main processing when it is detected that the sub device input state detected by the timer interrupt changes from OFF to ON. is set.

Subdevice input ON edge information (with repeat function) is information used for control when debugging or when an operation button is pressed for a long time, and is detected by a timer interrupt as shown in Figure 63(d). When it is detected that the sub-device input state changed from OFF to ON, 1 is set for each frame in the main processing. If the input state of the sub device continues to be ON after that, 1 is set for each frame after 10 frames elapse in the main processing as a fixed time until the start of key repeat, and after that, for example, in the main processing, 1 is set for each frame. 1 is set every 4 frames. In this way, the reason why only the first frame is made long at 10 frames is so that it can be determined whether or not the subdevice has been pressed for a long time.If the first frame is short, it can be determined that it is not a long press. Can be done.

As shown in FIG. 63(e), the sub device input OFF edge information is set to 1 for only one frame in the main processing when it is detected that the sub device input state detected by the timer interrupt changes from ON to OFF. is set.

In this embodiment, assuming that there are a plurality of subdevices, the host control circuit 2100 manages subdevice input determination information in bit units. For example, bit 0 is the main button, bit 1 is the left button, bit 2 is the right button, and so on, so that sub-device input discrimination information can be managed for a maximum of, for example, 32 devices.

Next, with reference to FIG. 64, sub-device input processing (for example, see step S1206 in FIG. 61) will be described. This sub-device input processing uses, for example, four types of sub-device input discrimination information such as sub-device input information, sub-device input ON edge information, sub-device input ON edge information (with repeat function), and sub-device input OFF edge information. This is the process of creating type information.

The host control circuit 2100 first creates current sub-device input information based on the current sub-device input state (step S1301). Specifically, 1 is set if the subdevice is in the ON state, and 0 is set if the subdevice is in the OFF state.

Next, the host control circuit 2100 updates the subdevice input information in accordance with the current subdevice input information, that is, the subdevice input information created in step S1301 (step S1302).

Next, the host control circuit 2100 determines whether the previous subdevice input information is 0 and the current subdevice input information is 1 (step S1303). If the previous subdevice input information is 0 and the current subdevice input information is 1 (YES in step S1303), the host control circuit 2100 sets the subdevice input ON edge information to 1 (step S1304), and The process moves to S1306. On the other hand, if the previous subdevice input information is 0 and the current subdevice input information is 1 (that is, if the previous subdevice input information is 1 and/or the current subdevice input information is 0), the host The control circuit 2100 sets the subdevice input ON edge information to 0 (step S1305), and moves to step S1306.

In step S1306, the host control circuit 2100 determines whether the previous subdevice input information is 1 and the current subdevice input information is 0. If the previous subdevice input information is 1 and the current subdevice input information is 0 (YES in step S1306), the host control circuit 2100 sets the subdevice input OFF edge information to 1 (step S1307), and The process moves to S1309. On the other hand, if the previous subdevice input information is 1 and the current subdevice input information is 0 (that is, if the previous subdevice input information is 0 and/or the current subdevice input information is 1), the host The control circuit 2100 sets the subdevice input OFF edge information to 0 (step S1308), and moves to step S1309.

The host control circuit 2100 performs subdevice input ON edge information (with repeat function) processing in step S1309. Details of this sub-device input ON edge information (with repeat function) processing will be described later.

After completing the subdevice input ON edge information (with repeat function) processing in step S1309, the host control circuit 2100 sets the current subdevice input information to the previous subdevice input information (step S1310), and Finish the process.

Next, subdevice input ON edge information (with repeat function) processing will be described with reference to FIGS. 65 and 66.

As shown in FIG. 65, in the subdevice input ON edge information (with repeat function) process, the host control circuit 2100 first determines whether or not the previous subdevice input information is 0 (step S1321). . If the previous subdevice input information is 0 (YES in step S1321), the process moves to step S1322.

The host control circuit 2100 determines whether the current subdevice input information is 1 in step S1322. If the current subdevice input information is 1 (YES in step S1322), that is, if the previous subdevice input information is 0 and the current subdevice input information is 1, the process moves to step S1323. On the other hand, if the current subdevice input information is not 1 (NO in step S1322), that is, if the previous subdevice input information is 0 and the current subdevice input information is 0, the subdevice input is ON. Ends edge information (with repeat function) processing.

Next, the host control circuit 2100 sets the subdevice input ON edge information (with repeat function) to 1 (step S1323), sets 10 frames as the elapsed frame (step S1324), and sets the subdevice input ON edge information to 1 (step S1323). (with repeat function) Ends the process.

In step S1321, if the previous subdevice input information is 1 (NO in step S1321), the host control circuit 2100 moves to step S1325 in FIG. 66.

Referring to FIG. 66, host control circuit 2100 determines whether the current subdevice input information is 1 in step S1325. If the current subdevice input information is 1 (YES in step S1325), that is, if the previous subdevice input information is 1 and the current subdevice input information is 1, subtract 1 from the elapsed frame. (Step S1326), the process moves to step S1327.

The host control circuit 2100 determines whether the elapsed frame is 0 in step S1327. If the elapsed frame is 0 (YES in step S1327), the sub device input ON edge information (with repeat function) is set to 1 (step S1328), the elapsed frame is set to 4 (step S1329), and the sub device Input ON edge information (with repeat function) processing ends.

In step S1325, if the current subdevice input information is not 1 (NO in step S1325), that is, if the previous subdevice input information is 1 and the current subdevice input information is 0, the host control The circuit 2100 sets the elapsed frame to 0 (step S1330) and moves to step S1331.

When the host control circuit 2100 sets the sub-device input ON edge information (with repeat function) to 0 in step S1331, it ends the sub-device input ON edge information (with repeat function) processing.

In this way, the host control circuit 2100 creates the above-mentioned four types of sub-device input discrimination information in the main processing every 33.3 msec based on the input state of the sub-device detected by the timer interrupt every 1 msec, By controlling the subdevice based on these four types of subdevice input discrimination information, it is easy to control the subdevice's continuous press effect, long press effect, time setting control, and other operations. becomes possible.

[10-4. Backlight control processing]
Next, backlight control processing (for example, backlight control processing for controlling the backlight of a liquid crystal display, etc.) will be described with reference to FIGS. 67 and 68. FIG. 67 is a diagram illustrating an example for conceptually explaining backlight control processing. FIG. 68 is a flowchart illustrating an example of backlight control processing.

The backlight control process of this embodiment uses the SPI asynchronous data write (SPI+DMA) function to continuously and continuously write data from the serial output terminal of a serial peripheral interface (hereinafter referred to as "SPI"), for example. It outputs a signal equivalent to pulse width modulation (hereinafter referred to as "PWM"), and the duty (brightness) can be changed. This makes it possible to perform backlight control without using a driver for backlight control.

In this embodiment, for example, the frequency of the SPI clock is 100 kHz, the SPI1 clock is 0.01 msec, the time required for data transmission of 16 bits (1 data of luminance data is 16 bits) by SPI is 0.16 msec, and the regular timing of the host control circuit 2100 is The interrupt is 1 msec, and the number of luminance data transmitted from the SPI between regular interrupts of the host control circuit 2100 is 100 bits. Therefore, the number of luminance data transmitted between regular interrupts of the host control circuit 2100 is 6.25 (100/16) (see FIG. 67). Therefore, for example, the number of scheduled interrupts that are executed until 32 pieces of luminance data are replenished in a FIFO (First In First Out) data area that can set (storage) 64 pieces of 16-bit luminance data is 5 to 6 times. it is conceivable that. Note that this number of times differs depending on the periodic interrupt time of the host control circuit 2100.

For example, if the number of luminance data set (stored) in a FIFO (First In First Out) data area that can set (storage) 64 pieces of 16-bit luminance data falls below 32 pieces, a callback function is called, so the FIFO data The space is not always filled. Therefore, if the process of setting (storing) luminance data in the FIFO data area takes time due to other processes in the main process that is executed at a cycle of 33.3 msec, the FIFO data area becomes empty. (the backlight may become completely dark).

Therefore, in this embodiment, after the power is turned on, 64 pieces of brightness data of 16 bits per data are first set to fill the FIFO data area, and then 32 pieces of brightness data set in the FIFO data area are set. When the value falls below this, a callback function is called, and 32 pieces of data are set in the callback function to prevent the FIFO data area from becoming empty.

As shown in FIG. 68, in the backlight control process, the host control circuit 2100 first determines whether or not the process is for initialization (step S1341). When the host control circuit 2100 determines that the process is the initial setting process (that is, one of the processes in step 201 in FIG. 61) (YES in step S1341), the host control circuit 2100 stores 64 pieces of brightness data with a brightness of 0 in the data area of the FIFO. is set (step S1342), and the process moves to step S1343. On the other hand, if it is determined that the process is not the initial setting process (that is, the process in step S1253 in FIG. 62) (NO in step S1341), the process in step S1342 is skipped and the process moves to step S1343.

In step S1343, host control circuit 2100 determines whether the brightness value has been changed. If the host control circuit 2100 determines that the brightness value has been changed (YES in step S1343), it changes the brightness data set in the FIFO data area (step S1344), and proceeds to step S1345. On the other hand, if it is determined that the brightness value has not been changed (NO in step S1343), the process of step S1344 is skipped and the process moves to step S1345.

In step S1345, the host control circuit 2100 determines whether the number of luminance data set in the FIFO data area is less than 32, and determines whether the number of luminance data set in the FIFO data area is 32. If the number is less than 32 (YES in step S1345), 32 pieces of luminance data are set or replenished in the FIFO data area (step S1346), and the backlight control process ends. On the other hand, if the number of luminance data set in the FIFO data area is greater than 32 (NO in step S1345), host control circuit 2100 ends the backlight process.

In this way, by processing the luminance data set in the FIFO data area so that it does not become empty, it is possible to continuously output a signal equivalent to PWM from the SPI serial data output terminal, and back It becomes possible to perform backlight control without using a driver for light control.

Note that the processes of steps S1343 to S1346 of the backlight control process of this embodiment can be replaced as follows. That is, after setting 64 pieces of luminance data of 0 (see step S1342), a process is performed to determine whether or not the number of luminance data set in the FIFO data area is less than 32 pieces. After that, it is determined whether the brightness value has been changed, and if it is determined that the brightness value has been changed, 32 pieces of brightness data according to the settings are set in the FIFO data area, and if it is determined that the brightness value has not been changed, the previous Set 32 pieces of the same luminance data in the FIFO data area. In this manner, the luminance data may be set in the FIFO data area and the backlight control process may be completed.

Furthermore, in this embodiment, when the number of luminance data set in the data area of the FIFO falls below 32 pieces (half of the number of data that can be set in the FIFO), 32 pieces of luminance data are replenished. The timing of replenishing and the number of luminance data to be replenished are not limited to these, and it is sufficient to replenish the predetermined number of luminance data when the luminance data set in the data area of the FIFO falls below a predetermined number. Furthermore, the luminance data to be replenished in the FIFO data area does not need to be the predetermined number mentioned above; for example, if the luminance data set in the FIFO data area falls below the first number, The brightness data may be supplemented. However, from the viewpoint of not setting brightness data in the FIFO data area too frequently and preventing the brightness data set in the FIFO data area from becoming empty, the above predetermined number or the first The number of brightness data is preferably about half the number of data that can be set in the FIFO data area, but as described above, it is not limited to this. Note that the above-mentioned "about half" is sufficient as long as the frequency of setting luminance data in the FIFO data area does not become too high and the luminance data set in the FIFO data area does not become empty. There are various methods of determining whether the brightness data is less than half or less than half, depending on the consumption speed of the luminance data set in the data area. For example, in the FIFO data area in this embodiment, up to 64 pieces of 16-bit luminance data can be set, so when the number of pieces of luminance data set in the FIFO data area is 1 to 64, one or more new pieces of luminance data can be set. Although it is possible to set the brightness data, from the viewpoint of preventing the backlight from becoming dark (the brightness data set in the FIFO data area becomes 0), it is necessary to set the FIFO data. It is preferable to newly set one or more pieces of brightness data when there are two or more pieces of brightness data set in a region. Further, the number of luminance data that can be set in the FIFO data area is not limited to 64, but it is sufficient that at least two or more luminance data can be set. In this way, when the number of brightness data that can be set in the FIFO data area is, for example, two or more, if the brightness data set in the FIFO data area is less than the first number (for example, two), the second number (For example, one piece of brightness data) may be supplemented.

[10-4-1. Modified example of backlight control processing]
Next, a modification of the backlight control process will be described with reference to FIGS. 69 and 70. FIG. 69 is a flowchart illustrating an example of timer interrupt processing according to a modified example of backlight control processing. FIG. 70 is a flowchart showing a modification of the backlight control process.

In a modified example of the backlight control processing, when there is a possibility that the processing takes time in the 1 msec timer interrupt processing, the backlight control processing determines whether a predetermined period of time or more has elapsed since data was set in the FIFO data area. If a predetermined period of time has elapsed, data is set in the FIFO data area.

In the timer interrupt processing in FIG. 69, the host control circuit 2100 first performs backlight control processing (step S1351). Hereinafter, for convenience of explanation, the backlight control process in step S1351 will be explained with reference to FIG. 70 before explaining the processes after step S1352.

As shown in FIG. 70, in the backlight control process, the host control circuit 2100 first determines whether the process is for initial setting (step S1361). When the host control circuit 2100 determines that the process is the initial setting process (that is, one of the processes in step 201 in FIG. 61) (YES in step S1361), the host control circuit 2100 stores 64 pieces of brightness data with a brightness of 0 in the data area of the FIFO. is set (step S1362), and then the process moves to step S1366. On the other hand, if it is determined that the process is not the initial setting process (that is, the process in step S1351) (NO in step S1361), the process moves to step S1363.

In step S1363, the host control circuit 2100 determines whether the number of luminance data set in the FIFO data area is less than 32, and determines whether the number of luminance data set in the FIFO data area is 32. If the number is less than 32 (YES in step S1363), 32 pieces of luminance data are set or replenished in the FIFO data area (step S1364), and the process moves to step S1365. On the other hand, if the number of luminance data set in the FIFO data area is greater than 32 (NO in step S1363), the process moves to step S1366. As mentioned above, the above 32 pieces of data are half of the number of data that can be set in the FIFO.

In step S1365, the host control circuit 2100 resets the elapsed time (step S1365) and starts measuring the elapsed time (step S1366). After starting to measure the elapsed time in step S1366, the host control circuit 2100 ends the backlight control process.

Returning to FIG. 69, the host control circuit 2100 performs accessory motor control after completing the backlight control process in step S1351 (step S1352).

In this modification, the host control circuit 2100 determines whether or not the elapsed time from which time counting was started in step S1366 has elapsed, after performing processing that may require time, such as accessory motor control. (Step S1353). If the predetermined time or more has elapsed (YES in step S1353), 32 pieces of luminance data are set in the data area of the FIFO (step S1354). On the other hand, if the predetermined time or more has not elapsed (NO in step S1353), there is no need to replenish the FIFO data area with luminance data, and the process moves to step S1357.

As mentioned above, since the time required to transmit 16 bits (16 bits of luminance data) with SPI is 0.16 msec, it is assumed that 5.12 msec is required to transmit 32 pieces of luminance data. It will be done. Therefore, in this modification, in step S1353, it is determined whether a predetermined time of 5.12 msec or more has elapsed.

After performing the process in step S1354, the host control circuit 2100 resets the elapsed time (step S1355) and starts measuring the elapsed time again (step S1356). After starting to measure the elapsed time in step S1356, the host control circuit 2100 performs input state determination processing (step S1357) and ends the timer interrupt processing.

In this way, time measurement is started when luminance data is set in the FIFO data area, and after processing that may require time, the luminance data is replenished if the above clock time has elapsed for a predetermined time or more. By doing so, it is possible to prevent the luminance data in the FIFO data area from becoming empty.

In this modification, an example has been described in which the processing of steps S1353 to S1357 is performed after accessory motor control (step S1352), but this is just an example. In other words, from the viewpoint of preventing the luminance data set in the FIFO data area from becoming empty, it is better to perform the processing from step S1353 to step S1357 after processing that may require time. Often, such processing is not limited to any particular processing.

[10-5. Brightness adjustment of backlight and various LEDs]
Next, variations in brightness adjustment of the backlight and various LEDs will be explained. Various LEDs correspond to board-side LEDs (for example, LEDs arranged on the game board unit 17), frame-side LEDs, etc., and in this specification, the lamp group 25 etc. including LEDs (for example, see FIG. 9) correspond to these. corresponds to Further, in this specification, three variations of the first to third embodiments, as variations of brightness adjustment of the backlight and various LEDs, will be described with reference to FIGS. 71 to 74, respectively. FIG. 71 is a flowchart illustrating an example of timer interrupt processing illustrating backlight control processing. FIG. 72 is a sub-control main process (overall flow) executed by the host control circuit 2100 for explaining the first embodiment of the process of adjusting the brightness of the backlight and various LEDs. FIG. 73 is a sub-control main process (overall flow) executed by the host control circuit 2100 for explaining a second embodiment of the backlight and various LED brightness adjustment processes. FIG. 74 is a sub-control main process (overall flow) executed by the host control circuit 2100 for explaining the third embodiment of the process of adjusting the brightness of the backlight and various LEDs. However, in FIGS. 72 to 74, only processes necessary for explanation are shown, and other processes are omitted. Note that in the first to third embodiments described below, as described above, when the luminance data set in the FIFO data area becomes about half, the host control circuit 2100 transfers the data to the FIFO data area. Replenish brightness data.

Note that the timing for replenishing the FIFO data area with luminance data is not limited to when the luminance data set in the FIFO data area becomes about half. In the FIFO data area in this embodiment, for example, up to 64 pieces of 16-bit luminance data can be set, so when the number of pieces of luminance data set in the FIFO data area is 1 to 64, one or more new pieces of luminance data can be set. Just set the brightness data. However, from the perspective of preventing the backlight from becoming dark (the brightness data set in the FIFO data area becomes 0), the brightness data set in the FIFO data area becomes 2. It is preferable to newly set one or more pieces of brightness data when the number of pieces of brightness data is more than one. Further, the number of luminance data that can be set in the FIFO data area is not limited to 64, but it is sufficient that at least two or more luminance data can be set. In this way, when the number of brightness data that can be set in the FIFO data area is, for example, two or more, if the brightness data set in the FIFO data area is less than the first number (for example, two), the second number (For example, one piece of brightness data) may be supplemented.

(First example)
For example, when the brightness of the backlight (for example, the backlight of a liquid crystal display, etc.) is adjusted by a player's operation, the brightness of the backlight is changed, but at this time, the control of the board side LED and frame side LED is may affect. In this embodiment, in such a case, the brightness settings of the backlight and the brightness settings of the panel side LEDs and the frame side LEDs are set as a common setting, and the backlight, panel side LEDs, and frame side LEDs are adjusted according to the settings. It is designed to perform control. Thereby, even if the update timing of the backlight control and the update timing of the panel side LED and frame side LED controls are different, processing can be facilitated.

In the timer interrupt process in FIG. 71, the host control circuit 2100 performs accessory motor control (step S1371), input state determination process (step S1372), and backlight control process (step S1373) in this order.

As shown in FIG. 72, the host control circuit 2100 performs initialization processing (step S1381), then moves to the main loop and performs LED request control processing (step S1382). The LED request made in step S1382 was created in the animation construction process one frame before (step S1386, which will be described later).

After performing the process of step S1382, the host control circuit 2100 performs the above-described process of generating sub-device (button) input discrimination information (step S1383) based on the input state of the sub-device, and proceeds to step S1384.

In step S1384, the host control circuit 2100 adjusts the brightness of the backlight based on the input state of the subdevice (for example, the player or the like operated the brightness setting screen displayed on the liquid crystal display device used as the display device 16). Set. The brightness of the backlight is set, for example, in three levels: high, medium, and low.

After performing the process in step S1384, the host control circuit 2100 moves to a packet reception loop, and first sets the brightness values of the board side LED and frame side LED according to the performance mode to be executed and the brightness value setting. (Step S1385). The brightness of the panel side LED and the frame side LED is also set in three levels, for example, strong, medium, and weak, similarly to the backlight.

Here, by setting the brightness settings of the panel side LEDs and the frame side LEDs and the brightness settings of the backlight as a common setting, the brightness of the panel side LEDs and the frame side LEDs can be adjusted while suppressing an increase in the control load. Both the settings and the backlight brightness settings can be changed by operations by the player or the like. For example, based on the player or the like operating the brightness setting screen displayed on the liquid crystal display device used as the display device 16, the host control circuit 2100 changes the brightness value of the backlight (step S1384), and The brightness values of the panel side LED and frame side LED are also changed (step S1385). At this time, the brightness value level of the backlight is the same as the brightness value level of the panel side LEDs and the frame side LEDs. For example, if the brightness value of the backlight is medium, the brightness values of the board side LED and frame side LED are also medium. As shown in FIG. 72, the brightness update timing of the backlight is different from the brightness update timing of the panel side LED and the frame side LED, so after the backlight brightness is updated, the brightness of the panel side LED and the frame side LED is The brightness of the screen is now updated. However, the brightness update timing of the backlight and the brightness update timing of the board-side LED and frame-side LED may be controlled to be the same.

Note that the brightness of the backlight, the board side LEDs, and the frame side LEDs are changed based on the player's operation of the brightness setting screen displayed on the liquid crystal display device used as the display device 16. However, the present invention is not limited to this, and for example, the brightness of the backlight, the brightness of the panel side LED, and the frame side LED may be changed based on the operation of a push button for presentation. In this case, it is necessary to judge whether or not the period for functioning as a push button for presentation (push button valid period) is reached, so the brightness of the board side LED and frame side LED is adjusted during the main flow. It is necessary to control the backlight according to the brightness of the LEDs.

The host control circuit 2100 performs animation construction processing in step S1386. In the animation construction process of step S1386, an LED request is created. This created LED request is waited in a buffer and then output in the LED request control process of the next frame (see step S1382).

Host control circuit 2100 repeatedly performs steps S1385 and S1386 depending on the received packet.

When the host control circuit 2100 exits the packet reception loop, it performs animation update processing (step S1387), and then waits for bank flip/bank flip completion (step S1388).

The host control circuit 2100 repeatedly performs each process from step S1382 to step S1388 in the main loop at a cycle of 33.3 msec.

(Second example)
For example, when a player or the like performs a brightness adjustment operation, the control of the board-side LEDs and frame-side LEDs may be affected, as described above. In this embodiment, in such a case, for example, when a player or the like performs a brightness adjustment operation, the brightness value of the backlight is immediately changed, but the control of the board side LED and frame side LED is controlled by the special symbol. This is executed after the fluctuation ends or between bank flips.

As described above, the host control circuit 2100 performs the accessory motor control (step S1371), the input state determination process (step S1372), and the backlight control process (step S1373) in this order in the timer interrupt process in FIG. conduct.

As shown in FIG. 73, after performing initialization processing (step S1391), the host control circuit 2100 moves to the main loop and performs LED request control processing (step S1392). The LED request made in step S1392 was created in the animation construction process one frame before (step S1395, which will be described later).

After performing the process in step S1392, the host control circuit 2100 generates the sub-device (button) input determination information generation process (step S1393) based on the input state of the sub-device (for example, a brightness adjustment operation by a player, etc.). ), and the process moves to step S1394.

In step S1394, the host control circuit 2100 sets the brightness of the backlight based on the input state of the subdevice (for example, a brightness adjustment operation by a player or the like). The brightness of the backlight is set, for example, in three levels: high, medium, and low.

After performing the process in step S1394, the host control circuit 2100 moves to a packet reception loop and performs animation construction processing (step S1395). In the animation construction process of step S1395, an LED request is created. This created LED request is waited in a buffer, and then output in the LED request control process of the next frame (see step S1392).

The host control circuit 2100 repeatedly performs the process of step S1395 depending on the received packet.

When the host control circuit 2100 exits the packet reception loop, it performs animation update processing (step S1396), then waits for bank flip/bank flip completion (step S1397), and proceeds to step S1398.

In step S1398, the host control circuit 2100 determines whether or not the variation of the production identification displayed on the liquid crystal display device as the display device 16 has ended, that is, whether the variation time of the production identification symbol has elapsed. (Step S1398). If the variation of the presentation identification symbol has ended (YES in step S1398), the host control circuit 2100 changes the brightness of the board side LED and frame side LED according to the set value at that time (step S1399). On the other hand, if the variation of the special symbol has not ended (NO in step S1398), the processing of steps S1392 to S1399 in the main loop with a period of 33.3 msec is repeated. Note that the process in step S1399 may be performed during the bank flip in step S1397, instead of or in addition to when the special symbol variation ends.

As described above, in the second embodiment, the host control circuit 2100 controls the brightness of the backlight that directly affects the eyes of the player based on the input state of the subdevice (for example, a brightness adjustment operation by the player or the like). The brightness of the board side LED and frame side LED is controlled to be changed immediately, but the brightness of the board side LED and frame side LED is changed after the brightness of the backlight has been changed and after the fluctuation of the production identification symbol has finished. Control as follows. In addition, if a brightness adjustment operation is performed by a player or the like while the presentation identification symbols are changing, the brightness of the board side LED and frame side LED must be changed by LED request control processing, but regarding the backlight can be changed immediately. Therefore, the brightness of the backlight is controlled to be changed immediately based on the input state of the subdevice, but the brightness of the panel side LED and frame side LED is changed by LED request control processing, which reduces the control load. can be minimized. That is, for example, by performing only one brightness adjustment operation by a player or the like, it is possible to change the brightness of the backlight and the brightness of the board side LEDs and the frame side LEDs while minimizing the control load.

Note that when the brightness of the backlight is changed based on the input state of the subdevice (for example, a brightness adjustment operation by a player, etc.), the host control circuit 2100 stores the brightness data related to the changed brightness in the FIFO. Set in the data area.

(Third example)
For example, when a player or the like performs a brightness adjustment operation, the control of the board-side LEDs and frame-side LEDs may be affected, as described above. In such a case, for example, when a player performs a brightness adjustment operation, the present embodiment changes the brightness value of the backlight and performs limited effects on the board side LEDs and frame side LEDs. This is how it was done. Performing in a limited manner means, for example, limiting the number of LEDs that emit light in the effects of the board-side LEDs and frame-side LEDs, or limiting the number of effects performed by the board-side LEDs and frame-side LEDs. . Limiting the number of performances corresponds to, for example, performing performances 1 to 3 only, and omitting performances 4 and 5 so that they are not performed, whereas performances 1 to 5 would normally be performed. As a result, the effects of the board-side LEDs and frame-side LEDs are restricted without directly changing the brightness value, so the intensity of light received by the player from the board-side LEDs and frame-side LEDs is suppressed. Become. Further, even if the update timing of the backlight control is different from the update timing of the control of the board side LED and the frame side LED, it is possible to simplify the process.

As described above, the host control circuit 2100 performs the accessory motor control (step S1371), the input state determination process (step S1372), and the backlight control process (step S1373) in this order in the timer interrupt process in FIG. conduct.

As shown in FIG. 74, after performing initialization processing (step S1401), the host control circuit 2100 moves to the main loop and performs LED request control processing (step S1402). The LED request made in step S1402 was created in the animation construction process one frame before (step S1407, which will be described later).

After performing the process of step S1402, the host control circuit 2100 performs the above-described process of generating sub-device (button) input discrimination information (step S1403) based on the input state of the sub-device, and proceeds to step S1404.

In step S1404, the host control circuit 2100 sets the brightness of the backlight based on the input state of the subdevice (for example, a brightness adjustment operation by a player or the like). The brightness of the backlight is set, for example, in three levels: high, medium, and low.

After performing the process in step S1404, the host control circuit 2100 determines whether the brightness setting has been changed (step S1405). If there is a brightness setting change (YES in step S1405), the host control circuit 2100 limits the brightness of the panel side LED and frame side LED according to the setting at that time (step S1406), and moves to the packet reception loop. On the other hand, if there is no change in the brightness value setting (NO in step S1405), the host control circuit 2100 moves to the packet reception loop without performing the process in step S1406.

Moving to the packet reception loop, the host control circuit 2100 performs animation construction processing (step S1407). In the animation construction process of step S1407, an LED request is created. This created LED request is waited in a buffer, and then output in the LED request control process of the next frame (see step S1402).

The host control circuit 2100 repeatedly performs the process of step S1407 depending on the received packet.

When the host control circuit 2100 exits the packet reception loop, it performs animation update processing (step S1408), and then waits for bank flip/bank flip completion (step S1409).

The host control circuit 2100 repeatedly performs steps S1402 to S1409 in the main loop with a period of 33.3 msec.

Regarding the brightness adjustment of the backlight and various LEDs described above (first to third embodiments), the backlight control process of this embodiment uses the SPI asynchronous data write (SPI+DMA) function as described above. For example, a signal equivalent to PWM is continuously output from the SPI serial output terminal. On the other hand, regarding the panel side LEDs and the frame side LEDs, as shown in step S1382 in FIG. 72, for example, the LEDs are controlled based on the LED request created one frame before the main loop. Therefore, even if the brightness of the backlight and various LEDs is adjusted, the timing at which the brightness of the backlight is changed is different from the timing at which the brightness of the board-side LEDs and frame-side LEDs is changed.

[10-6. RTC acquisition processing]
Next, the RTC acquisition process will be explained with reference to FIG. 75. As described above, the RTC acquisition process is performed both within various initialization processes (see step S1201 in FIG. 61) and within the main loop (see step S1201 in FIG. 61). Note that FIG. 75 is a flowchart illustrating an example of RTC acquisition processing.

For example, if accurate time cannot be obtained due to an abnormality in the RTC, such as when communication with the RTC cannot be performed or an abnormality has occurred in the RTC itself, the time is not updated and remains the same as the previous time. Therefore, when executing an RTC effect (for example, a Christmas-related effect during the Christmas season) based on the RTC time, if an RTC abnormality occurs, there is a risk that the RTC effect cannot be executed. Furthermore, since the RTC time is not updated when the RTC or more occurs, there is a risk that the RTC effect may continue to be executed or the RTC effect may be executed at an unexpected time.

Therefore, in the RTC acquisition process of this embodiment, when there is an RTC abnormality, that is, when the previous RTC time and the current RTC time are different, the RTC effect is executed based on the current time. Note that the RTC is provided with a secondary battery, so that it is possible to manage the time even when the host control circuit 2100 is powered off. In addition, the host control circuit 2100 acquires time from the RTC and manages error occurrence times and the like.

As shown in FIG. 75, in the RTC acquisition process, the host control circuit 2100 first acquires the RTC time (step S1412), and then moves to step S1413.

The host control circuit 2100 updates the previous time in step S1413. In this update of the previous time, the current time updated in step S1416, which will be described later, is updated as the previous time. After that, the host control circuit 2100 determines whether or not the RTC is abnormal (step S1414). If the RTC is abnormal (YES in step S1414), the current time is maintained (step S1415), and the process moves to step S1417. On the other hand, if the RTC is not abnormal (NO in step S1414), the current time is updated (step S1416), and the process moves to step S1417.

In addition, in the RTC acquisition process of this embodiment, after updating the previous time (step S1413), it is determined whether the RTC is abnormal (step S1414), but instead of this, the previous time is updated. Control may be performed such that it is determined whether the RTC is abnormal or not, and if the RTC is not abnormal, the previous time is updated and the current time is not maintained.

In step S1417, the host control circuit 2100 determines whether the current time is a designated time (for example, the time at which the RTC effect is executed). If the current time is the specified time (YES in step S1417), the process moves to step S1418, and if the current time is not the specified time (NO in step S1417), the process moves to step S1420.

In step S1418, host control circuit 2100 determines whether the previous time and current time do not match. If the RTC is abnormal, the previous time and current time do not match (YES in step S1418). If the previous time and current time do not match (YES in step S1418), the RTC performance execution flag is set to 1 (step S1419). That is, if there is an RTC abnormality, the RTC effect will be executed when the current time reaches the designated time. After performing the process of step S1419, the host control circuit 2100 ends the RTC acquisition process. On the other hand, if the previous time and the current time do not match (NO in step S1418), the process moves to step S1420.

The host control circuit 2100 sets the RTC effect execution flag to 0 in step S1420. After performing the process in step S1420, the host control circuit 2100 ends the RTC acquisition process.

In this way, in this embodiment, even if there is an RTC abnormality, by executing the RTC effect when the current time reaches the specified time, it is possible to avoid a situation where the RTC effect is not executed. .

[10-7. Composition playback control]
Next, composition playback control will be explained with reference to FIGS. 76 and 77.

A composition is scene data that is a combination of material data for configuring an image (movie) displayed on a liquid crystal display device used as the display device 16, for example, and generally consists of a plurality of layers. Layers include animations, vector graphics, still images, lights, and more.

FIG. 76 is a flowchart illustrating an example of animation control main processing executed by the display control circuit 2300. This animation control main process is executed based on the input of the control signal of the drawing request output in the animation construction process (see step S1211 in FIG. 61) executed by the host control circuit 2100. As shown in FIG. 76, the display control circuit 2300 first clears the composition playback information (step S1431). Then, the display control circuit 2300 executes composition playback control processing (step S1432). This composition playback control process will be described later. Thereafter, the display control circuit 2300 executes the top-level direct drawing function (step S1433), and ends the animation control main processing.

FIG. 77 is a flowchart illustrating an example of composition playback control processing executed by display control circuit 2300. As shown in FIG. 77, the display control circuit 2300 first determines whether the determined number of priorities is less than the upper limit (or less than the upper limit) of the number of priorities (step S1441). If the determined number of priorities is less than the upper limit (or less than the upper limit) of the number of priorities (YES in step S1441), the process moves to step S1442. The number of priorities is the number of layers of a composition to be played simultaneously, and the upper limit of the number of priorities is predetermined based on the composition to be played. Therefore, as long as the processing by the host control circuit 2100 is normal, the determined number of priorities will not exceed the upper limit of the number of priorities. Therefore, if the determined number of priorities exceeds the upper limit of the number of priorities (NO in step S1441), display control circuit 2300 ends the composition playback control process.

In step S1442, the display control circuit 2300 determines whether the determined number of displays is less than (or less than) the number of usable displays, that is, the determined number of displays is the number of usable (for example, installed) displays on the system. It is determined whether the number is less than (or less than) the number (step S1442). If the determined number of displays is less than (or less than) the number of usable displays (YES in step S1442), the process moves to step S1443.

In step S1443, display control circuit 2300 determines whether the used display number is not 0, that is, whether there is a usable display number. If the used display number is not 0 (YES in step S1443), that is, if there is a usable display number, the display control circuit 2300 moves to step S1444. On the other hand, if the used display number is 0 (NO in step S1443), that is, if there is no usable display number, the display control circuit 2300 moves to step S1459.

By the way, the pachinko gaming machine 1 of this embodiment includes two frame buffers as frame buffers in which compositions are registered. These two frame buffers are used by switching the function of one frame buffer from a drawing function to a display function and switching the function of the other frame buffer from a display function to a drawing function by a bank flip. Hereinafter, in this specification, a frame buffer having a display function will be simply referred to as a "frame buffer", and a frame buffer having a drawing function will be referred to as a "rendering result output destination buffer".

In step S1444, the display control circuit 2300 determines whether a composition is registered in the drawing result output destination buffer. In the determination process of step S1444, it is determined whether all compositions are registered (that is, whether there are any unregistered compositions). If all compositions are registered in the rendering result output destination buffer (YES in step S1444), display control circuit 2300 sets a rendering target (step S1445). Setting a drawing target is a process of setting a display to which drawing is to be performed. If no composition is registered in the drawing result output destination buffer (NO in step S1444), that is, if there is an unregistered composition, the display control circuit 2300 moves to step S1450.

In step S1446, the display control circuit 2300 sets the drawing result output destination buffer to the frame buffer. That is, the process in step S1446 is a process in which the rendering result output destination buffer is switched to the frame buffer by bank flip. At this time, the composition registered in the drawing result output destination buffer switched from the frame buffer is cleared. After that, the display control circuit 2300 determines whether or not there is a pause flag in the composition registered in the frame buffer switched from the drawing output destination buffer by the bank flip in step S1446 (step S1447). The pause flag is a flag for a debug function that temporarily stops the image, and if this pause flag exists (YES in step S1447), the display control circuit 2300 uses the drawing output destination buffer that was switched from the frame buffer by the bank flip in step S1446. The composition playback information is registered (step S1448) and the composition is played back (step S1449). On the other hand, if there is no pause flag (NO in step S1447), the process moves to step S1459. The composition playback information includes, for example, the size of the frame buffer, the size of the composition, the coordinates of the four vertices of the image to be played, composition registration information, the loop composition to be played, the composition length, and the start frame setting. , loop playback flag, etc. Furthermore, registration of reproduction information of a composition means collecting reproduction information of a composition, and reproduction of a composition means registering reproduction information of a collected composition. When playback information for a composition is registered, previous playback information is cleared.

In step S1450, the display control circuit 2300 determines whether the number of frames reproduced in the rendering result output destination buffer is greater than or equal to the upper limit (that is, whether the number of reproduced frames exceeds the number of frames held by the composition). Discern. If the number of frames reproduced in the drawing result output destination buffer is not equal to or greater than the upper limit (NO in step S1450), the display control circuit 2300 moves to step S1457 and registers composition playback information in the drawing result output destination buffer (step S1457) and the composition is played back (step S1458).

If the display control circuit 2300 determines in step S1450 that the number of frames reproduced in the drawing result output destination buffer is greater than or equal to the upper limit (YES in step S1450), the process moves to step S1451.

In step S1451, the display control circuit 2300 determines whether the playback mode of the composition registered in the frame buffer is loop playback. If the playback mode of the composition registered in the frame buffer is loop playback (YES in step S1451), the display control circuit 2300 performs playback from the beginning during loop playback (step S1452), and then moves to step S1457. . If the playback mode of the composition registered in the frame buffer is not loop playback (NO in step S1451), the display control circuit 2300 moves to step S1453.

In step S1453, the display control circuit 2300 determines whether the playback mode of the composition registered in the frame buffer is continuous frame display. If the playback mode of the composition registered in the frame buffer is frame continuous display (YES in step S1453), the display control circuit 2300 plays the last frame during frame continuous display (step S1454), and then in step S1457 Move to. If the playback mode of the composition registered in the frame buffer is not frame continuous display (NO in step S1453), the display control circuit 2300 moves to step S1455.

In step S1455, display control circuit 2300 determines whether the playback mode of the composition registered in the frame buffer is shot playback. If the playback mode is shot playback (YES in step S1455), display control circuit 2300 clears the composition during shot playback (step S1456), and then moves to step S1459. If the playback mode of the composition registered in the frame buffer is not shot playback (NO in step S1455), the display control circuit 2300 moves to step S1457.

Note that the composition playback information registration in step S1457 is, in principle, a process performed when no composition is registered in the drawing result output destination buffer (if determined NO in step S1444). However, as described above, even if there is a pause flag in the frame buffer switched from the drawing output destination buffer by the bank flip in step S1446 (YES in step S1447), the display control circuit 2300 controls the frame buffer by the bank flip in step S1446. Composition playback information is registered in the drawing output destination buffer that has been switched from the buffer (step S1448), and the composition is played back (step S1449). In this way, if the frame buffer switched from the drawing output destination buffer by the bank flip in step S1446 has a pause flag (YES in step S1447), composition playback information is immediately registered in the drawing output destination buffer ( Since the composition is played back (step S1449) at the same time as step S1448), it becomes possible to perform quick processing.

Display control circuit 2300 adds 1 to the determined number of displays in step S1459, and returns to step S1442.

Note that if it is determined in step S1442 that the determined number of displays exceeds the upper limit of the number of usable displays (NO in step S1442), the display control circuit 2300 executes a direct drawing function if there is data to be directly drawn. (Step S1460). Thereafter, the display control circuit 2300 adds 1 to the determined priority number (step S1461), and returns to step S1441.

In this way, in the composition playback control of this embodiment, playback information for a new composition is not registered in principle when a composition is registered in the rendering output destination buffer. However, only when a specific condition is met (YES in step S1447, that is, when the composition registered in the drawing output destination buffer has a pose flag), no composition is registered. It becomes possible to perform time processing (composition playback information registration). In other words, while a composition is registered in the drawing output destination buffer, it is possible to register the composition again at any time, so depending on the contents of the re-(newly) registered composition, , it becomes possible to overwrite the performance, skip the performance, and stop the performance.

Further, the process of step S1441 (process of determining whether the determined number of priorities is less than the upper limit (or lower than the upper limit) of the number of priorities (process of determining whether the determined number of displays is less than (or less than) the number of available displays) The processing for determining whether or not the However, it is possible to share the information and reduce the processing load.

[10-8. Sound amplifier check processing]
Next, the sound amplifier check process shown in FIG. 62 will be explained with reference to FIGS. 78 to 80. In this sound amplifier check process, it is determined whether the digital audio power amplifier 2620 (hereinafter referred to as "sound amplifier") is in an abnormal state (for example, an overcurrent abnormality, a high temperature abnormality, a DC detection abnormality in which the audio signal does not change, etc.) and confirmation of sound amplifier setting information. FIG. 78 is a flowchart illustrating an example of sound amplifier check processing. FIG. 79 is a flowchart showing an example of normal amplifier check processing. FIG. 80 is a flowchart showing an example of deep bass amplifier check processing.

The pachinko game machine 1 of this embodiment includes, as a sound amplifier, a normal amplifier that amplifies normal audio data and a deep bass amplifier that amplifies deep bass audio data.

As shown in FIG. 78, the host control circuit 2100 performs normal amplifier check processing (step S1471) and heavy bass amplifier check processing (step S1472).

As shown in FIG. 79, in the normal amplifier check process, the host control circuit 2100 first determines whether settings have been made from a binary file (step S1481). If a binary file exists at initialization, settings are performed from the binary file. Note that the initialization process is executed not only when the power is turned on, but also when a problem is discovered during an amplifier check and the settings are made again. Further, in this embodiment, the settings are performed from the binary file, but the invention is not limited to this, and any storage area that is different from the read settings, such as a binary file, may be used.

When the host control circuit 2100 determines that the settings have been made from the binary file (YES in step S1481), the host control circuit 2100 performs processing to determine whether or not the register that is the reference for the register value to be checked is normal (step S1482). , the process moves to step S1483. In the determination process of step S1482, the values of the registers are checked in address order, so it is determined whether the value of the register to start checking exists and whether the value is normal.

In step S1483, the host control circuit 2100 performs a process of sorting the received data from the binary file. Thereafter, the host control circuit 2100 compares the value in the RAM of the register with the received data (step S1484), and performs a process of determining whether the value of the normal amplifier is normal (step S1485). After performing the determination process in step S1485, the host control circuit 2100 ends the normal amplifier check process.

On the other hand, if the settings have not been made from the binary file in step S1481 (NO in step S1481), the host control circuit 2100 performs processing to compare the default value and the set value (step S1486), and performs normal amplifier check processing. end. After completing the normal amplifier check process, the host control circuit 2100 performs a heavy bass amplifier check process.

As shown in FIG. 80, in the deep bass amplifier check process, the host control circuit 2100 first determines whether settings have been made from a binary file (step S1491).

When the host control circuit 2100 determines that the settings have been made from the binary file (YES in step S1491), it performs processing to determine whether the register to be checked is normal (step S1492), and then moves to step S1493. .

In step S1493, the host control circuit 2100 clears registers 0x17-0x25 with appropriate values (binary file information) in consideration of the case where the values cannot be read due to a hardware failure.

In step S1494, the host control circuit 2100 performs a process of sorting the received data from the binary file. Thereafter, the host control circuit 2100 compares the RAM value of the register with the received data (step S1495), and performs a RAM address update process (step S1496). After performing the update process in step S1496, the host control circuit 2100 ends the heavy bass amplifier check process.

On the other hand, if the settings have not been made from the binary file in step S1491 (NO in step S1491), the host control circuit 2100 performs a process of comparing the default value and the set value (step S1497), and checks the deep bass amplifier. Finish the process.

As described above, in this embodiment, the host control circuit 2100 performs the sound amplifier check process in the 1 msec interrupt process. By the way, such sound amplifier check processing can also be performed in the main loop. However, when the sound amplifier check process is performed in the main loop, the time required for the sound amplifier check process may overwhelm other processes. Therefore, by performing the sound amplifier check process in the interrupt process as in this embodiment, it becomes possible to perform the sound amplifier check process without burdening other processes in the main loop.

Further, the sound amplifier check process shown in the timer interrupt process (see FIG. 62) includes the normal amplifier/deep bass amplifier (batch) check process (step S1497) in the 1 msec interrupt process, as shown in FIG. 81, for example. ). This normal amplifier/deep bass amplifier (batch) check process (step S1497) is a process that performs the normal amplifier check process (see FIG. 79) and the heavy bass amplifier check process (see FIG. 80) all at once.

However, if the sound amplifier check process is performed during the 1 msec interrupt process, there may be a case where the sound amplifier check process cannot be executed in its entirety. Therefore, a more preferable embodiment of the sound amplifier check process will be described with reference to FIGS. 82 to 84. FIG. 82 is a flowchart showing an example of a more preferable form of sound amplifier check processing. FIG. 83 is a flowchart showing an example of a more preferable form of the normal amplifier/deep bass amplifier check process. FIG. 84 shows an example of a more preferable form of the normal amplifier/deep bass amplifier check process, and is a flowchart continued from FIG. 83.

In a more preferred embodiment of the sound amplifier check process, as shown in FIG. 82, the host control circuit 2100 performs a normal amplifier/deep bass amplifier (split) check process (step S1498). The details of this normal amplifier/deep bass amplifier (split) check process will be described later, but each check process for the normal amplifier and each check process for the heavy bass amplifier is divided, and the range can be achieved within 1 msec of interrupt processing. Check processing is performed within the frame, and subsequent processing is performed in subsequent frames. In other words, among all the check processing for normal amplifiers and all the check processing for deep bass amplifiers, only a part of the check processing is performed in one interrupt processing, but all checks are performed over multiple interrupt processing. This is what I did. By doing so, in the interrupt processing, it becomes possible to execute all of the normal amplifier check processing and the heavy bass amplifier check processing without ending them midway.

As shown in FIG. 83, in the normal amplifier/deep bass amplifier (split) check process, the host control circuit 2100 first determines whether settings have been made from a binary file (step S1501).

When the host control circuit 2100 determines that the settings have been made from the binary file (YES in step S1501), the host control circuit 2100 determines whether the check status is 0 (step S1502). If the check status is 0 (YES in step S1502), the host control circuit 2100 performs a process of determining whether the register value checked by the normal amplifier is normal (step S1503). After performing the process in step S1503, the host control circuit 2100 sets the check status to 1 (step S1504), and ends the normal amplifier/deep bass amplifier (split) check process. Note that when the host control circuit 2100 determines that the check status is not 0 in step S1502 (NO in step S1502), the process moves to step S1505. Note that the process in step S1503 may be performed by further dividing the process for each register to determine whether each register value among the plurality of registers is normal.

The host control circuit 2100 determines whether the check status is 1 in step S1505. If the check status is 1 (YES in step S1505), the host control circuit 2100 performs a process of sorting the received data from the binary file (step S1506). After that, the host control circuit 2100 compares the value in the RAM of the register of the normal amplifier with the received data (step S1507), and determines whether processing for the number of divisions of the normal amplifier has been executed (step S1508). ). If the processing for the number of divisions of the normal amplifier has been executed (YES in step S1508), the host control circuit 2100 sets the check status to 2 (step S1509), and sets the check status to 2 (step S1509). ) Ends the check process. On the other hand, if the processing for the number of divisions of the normal amplifier has not been executed (NO in step S1508), the host control circuit 2100 performs the normal amplifier/deep bass amplifier (division) check processing without updating the check status. end. That is, since the check status is not updated and is maintained at 1, the host control circuit 2100 performs the process when the check status is 1 again in the next and subsequent frames. Note that if the host control circuit 2100 determines that the check status is not 1 in step S1505 (NO in step S1505), the process moves to step S1510. Note that in the process of step S1508, the process of comparing the RAM value of each register among the plurality of registers with the received data may be performed by further dividing the process for each register.

Host control circuit 2100 determines whether the check status is 2 in step S1510. If the check status is 2 (YES in step S1510), the host control circuit 2100 performs a process of determining whether the value of the normal amplifier is normal (step S1511). Thereafter, the host control circuit 2100 determines whether processing for the number of divisions of the normal amplifier has been executed (step S1512). If the processing for the number of divisions of the normal amplifier has been executed (YES in step S1512), the host control circuit 2100 sets the check status to 3 (step S1513), and sets the check status to 3 (step S1513). ) Ends the check process. On the other hand, if the processing for the number of divisions of the normal amplifier has not been executed (NO in step S1512), the host control circuit 2100 performs the normal amplifier/deep bass amplifier (division) check processing without updating the check status. end. That is, since the check status is not updated and is maintained at 2, the host control circuit 2100 performs the process when the check status is 2 again in the next and subsequent frames. Note that if the host control circuit 2100 determines that the check status is not 2 in step S1510 (NO in step S1510), the process moves to step S1514 (see FIG. 84).

Referring to FIG. 84, host control circuit 2100 determines whether the check status is 3 in step S1514. If the check status is 3 (YES in step S1514), the host control circuit 2100 performs a process of determining whether the register value checked by the deep bass amplifier is normal (step S1515). Thereafter, the host control circuit 2100 determines whether processing for the number of divided deep bass amplifiers has been executed (step S1516). If the processing for the number of divisions of the deep bass amplifier has been executed (YES in step S1516), the host control circuit 2100 sets the check status to 4 (step S1517), and the normal amplifier/deep bass amplifier ( division) check processing ends. On the other hand, if the processing for the number of divisions of the deep bass amplifier has not been executed (NO in step S1516), the host control circuit 2100 checks the normal amplifier/deep bass amplifier (split) without updating the check status. Finish the process. That is, since the check status is not updated and is maintained at 3, the host control circuit 2100 performs the process when the check status is 3 again in the next and subsequent frames. Note that if the host control circuit 2100 determines that the check status is not 3 in step S1514 (NO in step S1514), the process moves to step S1518.

Host control circuit 2100 determines whether the check status is 4 in step S1518. If the check status is 4 (YES in step S1518), the host control circuit 2100 clears the value of the register of the deep bass amplifier with an appropriate value (step S1519). Thereafter, the host control circuit 2100 sets the check status to 5 (step S1520), and ends the normal amplifier/deep bass amplifier (split) check process. Note that when the host control circuit 2100 determines that the check status is not 4 in step S1518 (NO in step S1518), the process moves to step S1521.

The host control circuit 2100 determines whether the check status is 5 in step S1521. If the check status is 5 (YES in step S1521), the host control circuit 2100 performs a process of sorting the received data from the binary file (step S1522). Thereafter, the host control circuit 2100 compares the value of the RAM in the register of the deep bass amplifier with the received data (step S1523), and updates the RAM address (step S1524). Thereafter, the host control circuit 2100 determines whether processing for the number of divided deep bass amplifiers has been executed (step S1525). If the processing for the number of divisions of the deep bass amplifier has been executed (YES in step S1525), the host control circuit 2100 determines whether the update of the RAM address has been completed (step S1526), and checks the check status. It is set to 0 (step S1527), and the normal amplifier/deep bass amplifier (split) check process is ended. If the processing for the number of divisions of the deep bass amplifier has not been executed in step S1525 (NO in step S1525), and if it is determined in step S1526 that the update of the RAM address has not been completed (NO in step S1526) , the host control circuit 2100 ends the normal amplifier/deep bass amplifier (split) check process without updating the check status. That is, since the check status is not updated and is maintained at 5, the host control circuit 2100 performs the process when the check status is 5 again in the next and subsequent frames. Note that when the host control circuit 2100 determines that the check status is not 5 in step S1521 (NO in step S1521), it ends the normal amplifier/deep bass amplifier (split) check process.

In this way, in a more preferred embodiment of the sound amplifier check process, each check process for the normal amplifier and each check process for the deep bass amplifier are divided, and can be performed within 1 msec of interrupt processing (that is, within 1 frame). Check processing is performed within the range, and continued processing is performed in the next and subsequent frames. In this way, part of the normal amplifier check process and the heavy bass amplifier check process are performed over multiple frames within one frame, so it is not possible to execute all of the check process for each amplifier over multiple frames. It becomes possible.

Note that when the check status is 4, the host control circuit 2100 determines whether or not the processing for the number of divisions has been executed (for example, if the check status is 3, the processing in step S1516 is equivalent). do not have. This is because the processing in step S1519, which is performed when the check status is 4, can be performed in a short time that does not affect the 1 msec interrupt processing. In other words, the process performed when the check status is 4 (step S1519) is the same as the process performed when the check status is 0 (step S1503), and the process performed when the check status is 1 (step S1506). and step S1507), the process performed when the check status is 2 (step S1511), the process performed when the check status is 3 (step S1515), the process performed when the check status is 5 (step This is because the time required for processing is shorter than in steps S1522 to S1524) and does not affect the 1 msec interrupt processing. In this way, in the pachinko gaming machine 1 of the present embodiment, it is determined whether or not the processing for the number of divisions has been executed, taking into account the time required for processing (whether or not it affects the 1 msec interrupt processing). I am deciding whether or not. However, even if the processing does not affect the 1 msec interrupt processing (for example, processing such as step S1519 performed when the check status is 4), it may be difficult to determine whether or not the processing for the number of divisions has been executed. A determination may also be made.

Note that the processes in steps S1503, S1511, and S1515 may be performed by further dividing each register to determine whether each register value among a plurality of registers is normal. In this case, the progress of the further divided determinations may be managed by the second check status. That is, the check status (first check status) related to the processing of the major classification shown in FIGS. 83 and 84, and the check status (second check status) related to the processing of the minor classification that is further divided into the processing of the major classification. This allows the progress of processing to be managed. Similarly, in each process of steps S1506 to S507 and steps S1522 to S523, the process of comparing the RAM value of each register among the plurality of registers with the received data is further divided and performed for each register. It's okay. In this case, the progress of the further divided processing may be managed using the second check status. That is, the check status (first check status) related to the processing of the major classification shown in FIGS. 83 and 84, and the check status (second check status) related to the processing of the minor classification that is further divided into the processing of the major classification. This allows the progress of processing to be managed. For example, even if a power outage occurs during processing or judgment of small classification, the progress of processing or judgment of small classification is checked by the first check status and the second check status after the power is restored, Control may be performed to restart each process or each determination.

In addition, various settings can be made for the check status, such as 0 when the power is turned on, and when the power is cut off during processing, the check status starts from the check status at the time of the previous power cut after the power is restored. Of course, if a power outage occurs, the power is turned on, or backup clear (RAM clear) processing is performed, the check status is set to 0 after the power is restored, and all processing and judgments are performed again ( Alternatively, as part of the initialization process, all the processes and determinations or some of the processes and determinations may be performed again.

[10-9. Sound request control processing (when there are multiple sound requests for the same channel)]
Next, regarding the sound request control process shown in FIG. 61, the sound request control process when there are multiple sound requests (also referred to as SAC requests) for the same channel will be described with reference to FIG. 85. FIG. 85 is a flowchart illustrating an example of sound request control processing when there are multiple sound requests for the same channel.

In the pachinko gaming machine 1 of this embodiment, when multiple SAC requests are made to the same playback channel in the same frame of the main loop performed at a cycle of 33.3 msec, a mute command of 2 msec is given between the SAC requests. It is registered with the . Thereby, it is possible to prevent the game sound output based on the SAC request from being overlapped by other game sounds, and it is possible to output highly accurate game sound. However, in this case, although there is an advantage that the game sound will not be overwritten, there is a risk that the processing will take time. Therefore, in the pachinko gaming machine 1 of the present embodiment, when specifying (registering) multiple SAC numbers for the same virtual track in the same frame of the main loop, an interval is left between the SAC requests of the first SAC requests, and the SAC numbers of the later arrivals are There is a case where a request is made and a case where a later-arriving SAC request is made without any interval between the first-arriving SAC number. More specifically, this will be explained below.

As shown in FIG. 85, in the sound request control process (when there are multiple sound requests for the same channel), the host control circuit 2100 first confirms the SAC number and playback channel (step S1541), After that, the process moves to step S1542.

In step S1542, host control circuit 2100 determines whether there are multiple SAC requests for the same playback channel. For example, since the SAC numbers are different for SHOT playback and LOOP playback, multiple SAC numbers may be specified for the same playback channel without any interval. If there are multiple SAC requests for the same playback channel (YES in step S1542), the host control circuit 2100 moves to step S1543. On the other hand, if there are no multiple SAC requests for the same playback channel (NO in step S1542), the sound request control process ends. Note that in this embodiment, one virtual track corresponds to one playback channel, so the determination process in step S1542 is synonymous with determining whether or not there is a SAC request for the same virtual track. It is. That is, a "track" is an interface for decoding and reproducing a "phrase", and a "reproduction channel" is a concept for reproducing a "phrase". In other words, when you specify a "playback channel" and request playback of a "phrase," the phrase is assigned to the corresponding "track" and played back. Furthermore, a "virtual track" is an "interface for controlling phrase playback." Note that the virtual track has 128 channels, and can be automatically divided into 32 phrase playback channels, but this embodiment does not use this function, so "virtual track" = "playback channel".

In step S1543, the host control circuit 2100 determines whether or not it is a chain playback of SHOT playback and LOOP playback. In the case of chain playback of SHOT playback and LOOP playback (YES in step S1543), the host control circuit 2100 executes a SAC request for LOOP playback one frame later (after 33.3 msec) (step S1544), and performs sound request control. Finish the process. In the case of chain playback of SHOT playback and LOOP playback, executing the SAC request for LOOP playback with a one-frame delay prevents the sound of SHOT playback from being overwritten and prevents the sound of SHOT playback from becoming difficult to hear. becomes possible. On the other hand, if the chain reproduction of SHOT reproduction and LOOP reproduction is not performed (NO in step S1543), the host control circuit 2100 moves to step S1545.

In step S1545, the host control circuit 2100 determines whether the inter-SAC mute command is a mute setting for all playback channels. For example, when the variable display of special symbols or decorative symbols ends, a mute command is uniformly set between SACs for all playback channels. Then, if the inter-SAC mute command is a mute setting for all playback channels (YES in step S1545), the host control circuit 2100 sends the SAC data corresponding to the first-arrived SAC request so that mute is executed. The SAC data corresponding to the later arriving SAC request is set without overwriting the mute command (step S1546), and the sound request control process ends. On the other hand, if the inter-SAC mute command does not set mute for all playback channels (NO in step S1545), the mute command for each playback channel is set to correspond to the later arriving SAC request so that prompt processing can be performed. It is overwritten and set with SAC data (step S1547), and the sound request control process ends.

As described above, in the pachinko gaming machine 1 of the present embodiment, when multiple SAC requests are made to the same playback channel in the same frame of the main loop, when the multiple SAC requests are chain playbacks of SHOT playback and LOOP playback, , the SAC number of LOOP playback is delayed by one frame (for example, 33.3 msec) so that the sound of LOOP playback does not overlap with the sound of SHOT playback. SHOT reproduction is, for example, reproduction of a phrase once, and LOOP reproduction is, for example, reproduction of a phrase LOOP (reproduction multiple times).

In addition, if the mute command between SACs is to mute all playback channels, the mute command is sent to the SAC data corresponding to the SAC number without overwriting the later arriving SAC data so that the mute is executed. register. Thereby, for example, when the variable display of the special symbol ends, it is possible to secure a period of time until the variable display of the next special symbol starts. Furthermore, if the mute command between SACs does not set mute for all playback channels, the mute command for each playback channel is overwritten with SAC data corresponding to a later arriving SAC request to prevent mute from being executed. In this way, by muting or not muting depending on the situation, it is possible to take advantage of the game sound effect of muting while ensuring the speed of processing (quickness due to overwriting the muting). ing.

[10-10. Sound request control processing (when volume adjustment is performed)]
Next, regarding the sound request control process shown in FIG. 61, variations of the sound request control process when volume adjustment is performed will be described. In this specification, as variations of the sound request control process when volume adjustment is performed, five variations of the first to fifth embodiments will be described with reference to FIGS. 86 to 90, respectively. FIG. 86 is a flowchart showing a first example of sound request control processing when volume adjustment is performed. FIG. 87 is a flowchart showing a second example of sound request control processing when volume adjustment is performed. FIG. 88 is a flowchart showing a third example of sound request control processing when volume adjustment is performed. FIG. 89 is a flowchart showing a fourth example of sound request control processing when volume adjustment is performed. FIG. 90 is a flowchart showing a fifth example of sound request control processing when volume adjustment is performed.

(First example)
As shown in FIG. 86, in the first embodiment of the sound request control process (when volume adjustment is performed), the host control circuit 2100 first performs input processing of audio data specified by the SAC number ( Step S1551). After that, the process moves to step S1552. Note that the SAC number is registered for each channel by the host control circuit 2100.

In step S1552, the host control circuit 2100 specifies the output destination speaker based on the audio data specified by the SAC number, and proceeds to step S1553. In this first embodiment, the audio data specified by the SAC number includes information about which speaker the audio data is output from. Speakers include, for example, shared speakers that are used for general purposes (used to output normal sounds that are sounds other than specific sounds), and dedicated speakers that are used to output specific sounds (error sounds, warning sounds, etc.). It has a speaker (for example, a deep bass speaker). Note that the host control circuit 2100 sets which of a plurality of speakers is to be used as a dedicated speaker in various initialization processes (for example, see various initialization processes (step S1201) in FIG. 61).

In step S1553, the host control circuit 2100 determines whether volume control is performed by a hardware switch. If the volume is controlled by a hardware switch (YES in step S1553), the volume is controlled by a hardware switch (see reference numeral 2810 in FIG. 13) (step S1554), and the process moves to step S1556. On the other hand, if the volume is not controlled by a hardware switch (NO in step S1553), user volume control (see reference numeral 2820 in FIG. 13) is performed (step S1555), and the process moves to step S1556.

In step S1556, the host control circuit 2100 performs debug volume control during debugging (see reference numeral 2830 in FIG. 13), and then proceeds to step S1557.

In step S1557, the host control circuit 2100 determines whether volume control is for a specific sound. The specific sound corresponds to a sound that is not affected by volume adjustment, such as an error sound. In addition, the audio data commanded by the SAC number includes information that the output destination of normal sound is a shared speaker, and information that the output destination of specific sound is a dedicated speaker. There is.

If it is determined in step S1558 that the volume control is not for a specific sound (NO in step S1557), the host control circuit 2100 performs volume control (see reference numeral 2840 in FIG. 13) for the normal sound set in the channel (step S1558). ), the process moves to step S1560. In the volume control in step S1558, control is performed to change the volume to a level corresponding to the volume adjustment.

On the other hand, if it is determined in step S1557 that the volume control is for a specific sound (YES in step S1557), the host control circuit 2100 performs volume control (reference numeral 2850 in FIG. 13) for the specific sound set in the channel ( Step S1559), the process moves to step S1560. The volume control in step S1559 is a control in which a constant volume is output without being affected by the volume adjustment, regardless of whether or not the volume adjustment is performed (i.e., even if a volume change operation is performed, Control is performed to output a constant volume before and after the control is performed.

In step S1560, the host control circuit 2100 determines whether volume control has been performed for the number of channels (in this embodiment, 32 channels from 1CH to 32CH).

If volume settings have been made for the number of channels in step S1560 (YES in step S1560), the volume control incorporated in the audio data specified by the SAC number is performed (step S1561), and the sound request control process ends. do.

If the volume control for the number of channels has not been performed in step S1560 (NO in step S1560), the host control circuit 2100 returns to step S1557 until the volume control for the number of channels has been performed (YES in step S1560). ), the processes from step S1557 to step S1560 are performed. Although not shown in FIG. 86, considering that the SAC number is specified for each channel, it is possible to perform volume control for the number of channels in the process of step S1561 as well. good.

(Second example)
As shown in FIG. 87, in the second embodiment of the sound request control process (when volume adjustment is performed), the host control circuit 2100 first performs input processing of audio data specified by the SAC number ( Step S1571). After that, the process moves to step S1572. Note that the SAC number is registered for each channel by the host control circuit 2100.

In addition, in this second embodiment, for example, a shared channel used for general purposes (used for outputting normal sounds that are sounds other than specific sounds) and a shared channel for specific sounds (error sounds, warning sounds, etc.) A dedicated channel is provided for output. Note that the host control circuit 2100 selects dedicated channels (CH31, CH32) used for outputting specific sounds among the plurality of channels (CH1 to CH32), and a shared channel (CH1) used for sounds other than specific sounds. -CH30) are set in various initialization processes (for example, see various initialization processes (step S1201) in FIG. 61).

In step S1572, host control circuit 2100 determines whether volume control is performed by a hardware switch. If the volume is controlled by a hardware switch (YES in step S1572), the volume is controlled by a hardware switch (see reference numeral 2810 in FIG. 13) (step S1573), and the process moves to step S1575. On the other hand, if the volume is not controlled by a hardware switch (NO in step S1572), user volume control (see reference numeral 2820 in FIG. 13) is performed (step S1574), and the process moves to step S1575.

In step S1576, the host control circuit 2100 performs debug volume control during debugging (see reference numeral 2830 in FIG. 13), and then proceeds to step S1576.

In step S1576, host control circuit 2100 determines whether volume control is for a specific sound. Also in the second embodiment, the specific sound corresponds to a sound that is not affected by volume adjustment, such as an error sound.

If it is determined in step S1576 that the volume control is not for the specific sound (NO in step S1576), the host control circuit 2100 performs volume control (see reference numeral 2840 in FIG. 13) for the normal sound set in the channel (step S1577). ), the process moves to step S1578. In the volume control in step S1577, control is performed to change the volume to a level corresponding to the volume adjustment.

On the other hand, if it is determined in step S1576 that the volume control is for a specific sound (YES in step S1576), the host control circuit 2100 performs volume control (reference numeral 2850 in FIG. 13) for the specific sound set in the channel ( Step S1579), the process moves to step S1582. The volume control in step S1579 is a control that outputs a constant volume without being affected by the volume adjustment, regardless of whether or not the volume adjustment is performed (i.e., even if a volume change operation is performed, Control is performed to output a constant volume before and after the control is performed.

In step S1578, host control circuit 2100 determines whether or not reproduction is being performed on a reproduction channel that is not affected by volume adjustment. If the playback is on a playback channel (for example, CH31, CH32) that is not affected by volume adjustment (YES in step S1578), a constant volume is specified (step S1580). If the playback is on a playback channel (for example, CH1 to CH30) that undergoes volume adjustment (NO in step S1578), the volume is set according to the user volume (step S1581). When the process of step S1580 ends or the process of step S1581 ends, the host control circuit 2100 moves to step S1582.

In step S1582, the host control circuit 2100 determines whether volume control has been performed for the number of channels (in this embodiment, 32 channels from 1CH to 32CH).

If volume settings have been made for the number of channels in step S1632 (YES in step S1582), the volume control incorporated in the audio data specified by the SAC number is performed (step S1583), and the sound request control process ends. do.

If the volume control for the number of channels has not been performed in step S1582 (NO in step S1582), the host control circuit 2100 returns to step S1576 and continues until the volume control for the number of channels has been performed (YES in step S1582). ), the processes from step S1576 to step S1582 are performed. Although not shown in FIG. 87, it is preferable to perform volume control for the number of channels in the process of step S1583 as well.

(Third example)
As shown in FIG. 88, in the third embodiment of the sound request control process (when volume adjustment is performed), the host control circuit 2100 first performs input processing of audio data specified by the SAC number ( Step S1591). After that, the process moves to step S1592.

In step S1592, host control circuit 2100 determines whether volume control is performed by a hardware switch. If the volume is controlled by the hardware switch (YES in step S1592), the volume is controlled by the hardware switch (see reference numeral 2810 in FIG. 13) (step S1593), and the process moves to step S1595. On the other hand, if the volume is not controlled by a hardware switch (NO in step S1592), user volume control (see reference numeral 2820 in FIG. 13) is performed (step S1594), and the process moves to step S1595.

In step S1595, the host control circuit 2100 performs debug volume control during debugging (see reference numeral 2830 in FIG. 13), and then proceeds to step S1596.

In step S1596, host control circuit 2100 determines whether volume control is for a specific sound. Also in the third embodiment, the specific sound corresponds to a sound that is not affected by volume adjustment, such as an error sound.

If it is determined in step S1596 that the volume control is not for a specific sound (NO in step S1596), the host control circuit 2100 performs volume control (see reference numeral 2840 in FIG. 13) for the normal sound set in the channel (step S1597). ), the process moves to step S1599. In the volume control in step S1597, control is performed to change the sound volume in accordance with the volume adjustment.

On the other hand, if it is determined in step S1596 that the volume control is for a specific sound (YES in step S1596), the host control circuit 2100 performs volume control (reference numeral 2850 in FIG. 13) for the specific sound set in the channel ( Step S1598), the process moves to step S1599. The volume control in step S1598 is a control that outputs a constant volume without being affected by the volume adjustment, regardless of whether or not the volume adjustment is performed (i.e., even if a volume change operation is performed, Control is performed to output a constant volume before and after the control is performed.

In step S1599, host control circuit 2100 determines whether the data currently in the reproduction channel (data being reproduced) is data that is not affected by volume adjustment. If the data in the playback channel is data that is not affected by volume adjustment (YES in step S1599), a constant volume is specified for the playback channel next time (step S1600). If the data in the playback channel is subject to volume adjustment (NO in step S1599), next time the playback channel is set to a volume corresponding to the volume adjustment (step S1601). When the process of step S1600 or the process of step S1601 ends, the host control circuit 2100 moves to step S1602.

In step S1602, the host control circuit 2100 determines whether volume control has been performed for the number of channels (in this embodiment, 32 channels from 1CH to 32CH).

If the volume settings for the number of channels have been performed in step S1602 (YES in step S1602), the volume control incorporated in the audio data specified by the SAC number is performed (step S1603), and the sound request control process ends. do.

If the volume control for the number of channels has not been performed in step S1602 (NO in step S1602), the host control circuit 2100 returns to step S1599 and continues until the volume control for the number of channels has been performed (YES in step S1602). ), the processes from step S1599 to step S1602 are performed. Although not shown in FIG. 88, it is preferable to perform volume control for the number of channels in the process of step S1603 as well.

In this third embodiment, in step S1599, it is determined whether the data currently in the reproduction channel (data being reproduced) is data that is not affected by volume adjustment, and the determination result in step S1599 is If YES, a constant volume is set for the next playback channel (step S1600), and if the determination result in step S1599 is NO, the next playback channel is set to a volume corresponding to the volume adjustment. Alternatively, a modified example described below may be used. That is, in this modified example, as the processing in the next step after step S1597 and step S1598, the audio data to be set this time and the audio data that is already being played on the playback channel to which the audio data is set are subject to volume adjustment. After performing the process of checking whether the data is unaffected, the process of determining whether the volume adjustment settings of the current audio data and the previous volume adjustment settings of the audio data are the same. I do. If the volume adjustment setting for the current audio data is the same as the previous volume adjustment setting for the audio data, a process is performed to determine whether the data is unaffected by the volume adjustment. If the current audio data volume adjustment settings are not the same as the previous audio data volume adjustment settings, the current audio data volume adjustment settings will not be affected by the volume adjustment. The process moves on to determining whether or not it is data. The process moves on to determining whether the data is unaffected by volume adjustment. If the data is not affected by volume adjustment, processing is performed to set a constant volume on the playback channel, and if the data is affected by volume adjustment, processing is performed to set a constant volume on the playback channel according to the volume adjustment. Performs processing to set the volume. After that, it is preferable to proceed to a process of determining whether or not the number of channels has been set as many as the number of channels, as in step S1602. In this modification, the only process that differs from the third embodiment is the process described above, and the other processes are the processes of the third embodiment (the processes of steps S1592 to S1598 shown in FIG. 88, the process of step S1602, and the process of step S1603).

(Fourth example)
As shown in FIG. 89, in the fourth embodiment of the sound request control process (when volume adjustment is performed), host control circuit 2100 first determines whether the SAC number is a SAC number affected by volume adjustment. This is confirmed (step S1611). After that, the process moves to step S1612.

In step S1612, the host control circuit 2100 updates the flag indicating whether or not the SAC number is affected by volume adjustment, and inputs the audio data specified by the SAC number (step S1613). Specifically, if the SAC number is affected by volume adjustment, the flag is set to ON (if the SAC number is not affected by volume adjustment, the flag is set to OFF).

In step S1614, the host control circuit 2100 determines whether volume control is performed by a hardware switch. If the volume is controlled by a hardware switch (YES in step S1614), the volume is controlled by a hardware switch (see reference numeral 2810 in FIG. 13) (step S1615), and the process moves to step S1617. On the other hand, if the volume is not controlled by a hardware switch (NO in step S1614), user volume control (see reference numeral 2820 in FIG. 13) is performed (step S1616), and the process moves to step S1617.

In step S1617, the host control circuit 2100 performs debug volume control during debugging (see reference numeral 2830 in FIG. 13), and then proceeds to step S1618.

In step S1618, host control circuit 2100 determines whether volume control is for a specific sound. In the fourth embodiment as well, the specific sound corresponds to a sound that is not affected by volume adjustment, such as an error sound.

If it is determined in step S1618 that the volume control is not for a specific sound (NO in step S1618), the host control circuit 2100 performs volume control (see reference numeral 2840 in FIG. 13) for the normal sound set in the channel (step S1619). ), the process moves to step S1620. In the volume control in step S1619, control is performed to change the sound volume in accordance with the volume adjustment.

On the other hand, if it is determined in step S1618 that the volume control is for a specific sound (YES in step S1618), the host control circuit 2100 performs volume control (reference numeral 2850 in FIG. 13) for the specific sound set in the channel ( Step S1622), the process moves to step S1624. The volume control in step S1622 is a control that outputs a constant volume without being affected by the volume adjustment, regardless of whether or not the volume adjustment is performed (i.e., even if a volume change operation is performed, Control is performed to output a constant volume before and after the control is performed.

In step S1620, host control circuit 2100 determines whether or not playback is performed on a playback channel that is not affected by volume adjustment. That is, it is determined in step S1612 whether the flag is set to ON. If the playback is on a playback channel that is not affected by volume adjustment (YES in step S1620), a constant volume is specified for the playback channel (step S1621), and the process moves to step S1624. If the playback is not on a playback channel that is not affected by the volume adjustment (NO in step S1620), a volume corresponding to the volume adjustment is set for the playback channel (step S1623), and the process moves to step S1624.

In step S1624, the host control circuit 2100 determines whether volume control has been performed for the number of channels (in this embodiment, 32 channels from 1CH to 32CH).

If volume settings have been made for the number of channels in step S1624 (YES in step S1624), the volume control incorporated in the audio data specified by the SAC number is performed (step S1625), and the sound request control process ends. do.

If the volume control for the number of channels is not performed in step S1624 (NO in step S1624), the host control circuit 2100 returns to step S1618 until the volume control for the number of channels is performed (YES in step S1624). ), the processing of steps S1618 to S1624 is performed. Although not shown in FIG. 89, it is preferable to perform volume control for the number of channels in the process of step S1625 as well.

(Fifth example)
As shown in FIG. 90, in the fifth embodiment of the sound request control process (when volume adjustment is performed), the host control circuit 2100 first performs input processing of audio data specified by the SAC number ( Step S1631). After that, the process moves to step S1632.

The host control circuit 2100 checks whether the audio data is audio data for which each channel is subject to volume adjustment (step S1633). Specifically, if the audio data specified by the SAC number is audio data that is affected by volume adjustment, the flag is set to ON (the audio data specified by the SAC number is not affected by volume adjustment). If it is audio data, the flag is OFF).

In step S1633, the host control circuit 2100 determines whether volume control is performed by a hardware switch. If the volume is controlled by the hardware switch (YES in step S1633), the volume is controlled by the hardware switch (see reference numeral 2810 in FIG. 13) (step S1634), and the process moves to step S1636. On the other hand, if the volume is not controlled by a hardware switch (NO in step S1633), user volume control (see reference numeral 2820 in FIG. 13) is performed (step S1635), and the process moves to step S1636.

In step S1636, the host control circuit 2100 performs debug volume control during debugging (see reference numeral 2830 in FIG. 13), and then proceeds to step S1637.

In step S1637, the host control circuit 2100 determines whether volume control is for a specific sound. In the fifth embodiment as well, the specific sound corresponds to a sound that is not affected by volume adjustment, such as an error sound.

If it is determined in step S1637 that the volume control is not for a specific sound (NO in step S1637), the host control circuit 2100 performs volume control (see reference numeral 2840 in FIG. 13) for the normal sound set in the channel (step S1638). ), the process moves to step S1639. In the volume control in step S1638, control is performed to change the sound volume in accordance with the volume adjustment.

On the other hand, if it is determined in step S1637 that the volume control is for a specific sound (YES in step S1637), the host control circuit 2100 performs volume control (reference numeral 2850 in FIG. 13) for the specific sound set in the channel ( Step S1640), the process moves to step S1643. The volume control in step S1640 is a control in which a constant volume is output without being affected by the volume adjustment, regardless of whether or not the volume adjustment is performed (i.e., even if a volume change operation is performed, (a constant volume is output before and after) is performed.

In step S1639, host control circuit 2100 determines whether the channel is unaffected by volume adjustment. That is, it is determined in step S1632 whether the flag is set to ON. If the channel is not affected by volume adjustment (YES in step S1639), a constant volume is set for the playback channel (step S1641). If the channel is affected by the volume adjustment (NO in step S1639), the volume corresponding to the volume adjustment is set for the playback channel (step S1642). When the process in step S1641 is completed or the process in step S1642 is completed, the host control circuit 2100 moves to step S1643.

In step S1643, the host control circuit 2100 determines whether volume control has been performed for the number of channels (in this embodiment, 32 channels from 1CH to 32CH).

If volume settings have been made for the number of channels in step S1643 (YES in step S1643), the volume control incorporated in the audio data specified by the SAC number is performed (step S1644), and the sound request control process ends. do.

If the volume control for the number of channels has not been performed in step S1643 (NO in step S1643), the host control circuit 2100 returns to step S1637 until the volume control for the number of channels has been performed (YES in step S1643). ), the processes of steps S1637 to S1643 are performed. Although not shown in FIG. 90, it is preferable to perform volume control for the number of channels in the process of step S1644 as well.

According to the sound request control processing (first to fifth embodiments) when the volume adjustment is performed as described above, when the volume adjustment is performed, the volume of the normal sound is output according to the volume adjustment. At the same time, for example, it is possible to easily perform audio control such as outputting a constant volume from the speaker even if the volume is adjusted for important specific sounds such as error sounds.

[10-11. LED brightness adjustment processing]
Next, the brightness adjustment of the LED will be explained with reference to FIGS. 61 and 91. FIG. 91 is an attenuation table showing an example of brightness attenuation values for each color (red, green, blue) according to the strong, medium, and weak light emission intensities of the LEDs. This attenuation table is stored in the sub-main ROM 2050 (see FIG. 10, for example).

The pachinko gaming machine 1 of this embodiment is configured such that the brightness of the LED can be adjusted in three levels by, for example, an operation by a player or the like. Specifically, when a brightness adjustment operation is performed on the brightness setting screen displayed on the liquid crystal display device used as the display device 16, the host control circuit 2100 performs the attenuation table switching process shown in FIG. 91. For example, when an operation is performed to change the brightness from high to medium among the three levels of brightness, the host control circuit 2100 performs a process of switching the reference table from high to medium in the attenuation table of FIG.

Note that the LED whose brightness can be adjusted by the player's operation may be, for example, an LED provided on the glass door 13 (see FIG. 2, for example), or may be, for example, a backlight of a liquid crystal display device used as the display device 16. It may be. Note that the brightness adjustment of the LED is not limited to three stages, but may be configured to be adjustable in more stages, for example.

The output value of the LED is expressed by the following equation (1).
LED output value = brightness value based on LED data x (100 - brightness attenuation value) / 100...Equation (1)
The output value of the LED in the above equation (1) can also be set for each LED reproduction channel. Note that the parameter that is changed by the player's operation is the brightness attenuation value. For example, if the brightness attenuation value is 0, the brightness is the strongest, and if the brightness attenuation value is 100, the brightness is the weakest and the light is turned off. Further, calculation of the output value of the LED is performed inside the sequencer 2260b (see FIG. 11).

In addition, to create an LED data table that defines LED data and playback patterns, etc., create a BLD file (LED animation) using tools such as ActiveLED (UE) and LED Maker (UE), and add information to the created BLD file. It is created by converting it using an LED list (Excel macro) (UE).

By the way, in the case of a three-primary full-color LED, if the brightness attenuation values for red, green, and blue are uniformly the same, the white balance may be distorted, and for example, white may become yellow. For example, when reducing the brightness of an LED, it is necessary to make the brightness attenuation value of blue the largest among red, green, and blue, and it is preferable to make the brightness attenuation value of red the smallest.

Therefore, in the pachinko gaming machine 1 of the present embodiment, even if the brightness of the LED is changed by the player's operation, for example, by setting the brightness attenuation value for each of the 1024 ports, the white It is designed to maintain balance as much as possible.

Specifically, when the brightness of the LED is adjusted to high, medium, or low by a player's operation, the audio/LED control circuit 2200 refers to the attenuation table in FIG. The brightness of the LED is controlled based on brightness attenuation values set for each of green and blue. Note that since the attenuation table is prepared for each of, for example, 1024 ports (for each LED), an attenuation value can be set for each port.

For example, when the brightness of the LED is set to high by a player's operation, the sequencer 2260b of the audio/LED control circuit 2200 sets a red brightness attenuation value of 0, a green brightness attenuation value of 5, and a blue brightness attenuation value of 25. is substituted into the above equation (1) to calculate the output value of the LED. Similarly, when the brightness of the LED is set to medium by a player's operation, the sequencer 2260b of the audio/LED control circuit 2200 controls a red brightness attenuation value of 50, a green brightness attenuation value of 53, and a blue brightness attenuation value. 63 into the above equation (1), and when the brightness of the LED is set to low by the player's operation, the brightness attenuation value for red is 80, the brightness attenuation value for green is 81, and the brightness attenuation value for blue is 85. Substitute it into the above equation (1) to calculate the output value of the LED. Then, the audio/LED control circuit 2200 controls the light emission of the LED based on the output value of the LED calculated in this manner.

In this way, the audio/LED control circuit 2200 calculates the output value of the LED based on the brightness attenuation values set corresponding to red, green, and blue, and calculates the output value of the LED based on the calculated output value of the LED. By controlling the light emission of the LED, it is possible to maintain the white balance as much as possible, even if the brightness of the LED is changed by, for example, an operation by a player or the like.

[10-12. Accessory solenoid control processing]
Next, the accessory solenoid control process will be described with reference to FIGS. 61, 62, and 92. FIG. 92 is a block diagram showing an example of a connection state between an LED port, an LED, and a solenoid.

In the pachinko game machine 1 of this embodiment, for example, the movements of the movable bodies (accessories) provided in the game area are diversified, and control of the movable bodies is accordingly complicated. Therefore, for simple movements among the wide variety of movements of a movable body, we can reduce the control load on the movable body by operating the parts that make up the accessory using a solenoid, or by providing a locking mechanism on the accessory. We are trying to When a motor driver that operates an accessory receives a request for motor operation (accessories request), it sequentially outputs the contents of motor operation data. The output of the motor driver and the end of motor operation are determined by a 1 msec timer interrupt process, as shown in FIG. 62. In the timer interrupt processing, output determination and termination determination (that is, determination of start and end) of the accessory motor are performed, and synchronous control of a plurality of motors is also performed.

Furthermore, as shown in FIG. 92, the audio/LED control circuit 2200 of the pachinko gaming machine 1 of this embodiment controls the frame-side LED and The light emission of the LEDs on the board side (for example, the LEDs disposed on the game board unit 17 and the backlight of the liquid crystal display device used as the display device 16) is controlled via an LED driver. Of the LED ports (Port0 to Port23) controlled by the LED driver, the above-mentioned solenoid is connected to Port6, and the LEDs are connected to the other ports.

The audio/LED control circuit 2200 receives a command from the host control circuit 2100 and causes the LEDs connected to each port of the frame side LED and the panel side LED to emit light via an LED driver. By connecting a solenoid to port 6, the solenoid can also be activated via the LED driver. As a result, even if the number of solenoids increases due to the diversification of the movements of accessories, it is possible to maintain the diversity of the movements of the accessories and to suppress the control load for operating the accessories. .

By the way, when operating the solenoid described above through the LED driver as shown in FIG. 92, it is necessary to synchronously control the motor that operates the accessory and the operation of the solenoid. Note that the operation of the accessory, including the synchronous control of a plurality of motors, is performed by interrupt processing of 1 msec.

Therefore, in the pachinko game machine 1 of this embodiment, a control code is added to the accessory sequence table, and when it is desired to synchronously control the solenoid and the plurality of motors that operate the accessory, a value larger than 0 is set in the control code. I'm trying to set it up. Then, in the main loop processing, the host control circuit 2100 acquires the control code of the accessory being played on the accessory device (see step S1204 in FIG. 61), and if the acquired control code has a value greater than 0. In this case, the LED port (for example, Port 6 to which the above-mentioned solenoid is connected) corresponding to the control code is controlled (see step S1205 in FIG. 61). This makes it possible to perform synchronous control of the solenoid and a plurality of motors that operate the accessories.

Note that the reason why the control of the LED port corresponding to the control code is executed in the main loop is to avoid affecting the normal LED control executed by 1 msec interrupt processing.

In addition, in the pachinko gaming machine 1 of the present embodiment, solenoids are connected to some of the LED ports (Port0 to Port23), so the brightness of the LEDs described above can be adjusted by the player's operation, for example. Then, the voltage to the solenoid will also be reset, but since the solenoid operates only on and off, the effect on the solenoid is considered to be small. Moreover, when performing a synchronization effect that synchronizes the light emission of the LED and the operation of the solenoid, such a synchronization effect can be easily performed.

[10-13. Data load processing]
In the pachinko game machine 1 of this embodiment, a data load process is performed as one of various initialization processes (see step S1201 in FIG. 61) executed when the power is turned on. Also, data loading processing may be performed during the game. These data load processes are data transfer from ROM to RAM or buffer (for example, data transfer from sub-main ROM 2050 to SRAM 2100b, data transfer from CGROM 2060 to built-in VRAM 2370 (for example, see FIG. 10 for both)), i.e. This is a process (data load process) of loading data stored in a ROM into a RAM or a buffer.

The data load process described above takes time to load when a large amount of data is transferred, and there is a risk that the watchdog will be reset and the data load process will end. When the watchdog is reset, it is difficult to determine whether the reason for the reset is simply because the amount of data is large and takes time, or because an error occurred during data loading. Furthermore, if the data loading process ends, the host control circuit 2100 cannot determine whether the loading is complete or has failed, and continues to wait for the loading to complete, resulting in a state in which automatic recovery is not possible. There is a risk that

Therefore, in this embodiment, if the time required for the data load process exceeds a predetermined upper limit value, the data load process is terminated as an error and the data is reloaded. The data load process will be described below with reference to FIG. 93. FIG. 93 is a flowchart showing an example of a data load process executed by the host control circuit 2100 as one of various initialization processes.

As shown in FIG. 93, the host control circuit 2100 first sets the upper limit of the transfer time (step S1651). Transfer time is the time required to load data from ROM to RAM. The upper limit of the transfer time varies depending on the amount of data to be transferred, but in this embodiment, it is determined by the following equation (2).
Upper limit of transfer time = (amount of data transferred per unit time) x (estimated transfer time + α)...Formula (2)
The amount of data to be transferred per unit time and the approximate transfer time in Equation (2) above may be set in advance based on the amount of data to be transferred, or may be set in advance based on the amount of data to be transferred, for example, in the host control circuit 2100. It may be calculated by Note that α is a time to allow some margin for data loading.

When the process in step S1651 ends, the host control circuit 2100 moves to step S1652 and starts loading data from the ROM to the RAM.

After starting the data load (step S1652), the host control circuit 2100 determines whether the data load has been completed (step S1653). If the data loading has not been completed (NO in step S1653), the host control circuit 2100 moves to step S1654. On the other hand, if data loading has been completed (YES in step S1653), host control circuit 2100 ends the data loading process.

In step S1654, host control circuit 2100 determines whether the data transfer time does not exceed the upper limit. If the data transfer time exceeds the upper limit (YES in step S1654), the watchdog timer is cleared at regular intervals (step S1655). On the other hand, if the data transfer time exceeds the upper limit (NO in step S1654), host control circuit 2100 determines that an error has occurred and executes error processing. The error process executed here is a process of resetting the load data by watchdog reset without clearing the watchdog timer (step S1656) and reloading the data. Thereafter, the host control circuit 2100 returns to step S1654. That is, if the data transfer time exceeds the upper limit (NO in step S1654), the data will be reloaded as an error process.

In this way, when performing a data load process, the host control circuit 2100 continues to clear the watchdog timer at fixed intervals while waiting for the load to complete, so that the watchdog reset does not occur during normal loading. I have to. However, when the data load process exceeds a predetermined upper limit, the host control circuit 2100 resets the load data and reloads it. As a result, even if the data loading process takes time, it will be automatically restored by reloading.

[10-14. Sub-random number processing]
Next, sub-random number processing executed in the main loop by the host control circuit 2100 will be described.

The sub-random number processing includes a random number initialization process that is executed as one of various initialization processes (see step S1201 in FIG. 61) when the power is turned on, and a random number regular update process that is executed periodically. It also includes a random number acquisition process that is executed when a random number is used. The sub-random number processing is different from the lottery of special symbols by the main CPU 101 (for example, see FIG. 9), which is involved in the ball output, and is a process for random numbers that do not affect the ball output and are used, for example, to determine the performance mode. However, the sub-random number processing described below may be applied to the random number processing executed by the main CPU 101. These sub-random number processes described above will be explained with reference to FIGS. 94 to 97. FIG. 94 is a flowchart illustrating an example of a random number initialization process executed by the host control circuit 2100 as one of various initialization processes. FIG. 95 is a flowchart illustrating an example of random number periodic update processing. FIG. 96 shows (a) a flowchart illustrating an example of random number 1 acquisition processing, (b) a flowchart illustrating an example of random number 2 acquisition processing, (c) a flowchart illustrating an example of random number 3 acquisition processing, and (d) random number 4 acquisition processing. It is a flowchart which shows an example. FIG. 97 is a flowchart illustrating an example of random number acquisition processing executed when random numbers are used.

In the pachinko game machine 1 of this embodiment, four random numbers are used (random number 1 to random number 4), and the initialization process for these four random numbers is performed by clearing the game data RAM and executed at the same time.

As shown in FIG. 94, in the random number initialization process, the host control circuit 2100 first obtains the RTC time (minutes/seconds) (step S1671), and then enters a loop for the number of random numbers.

In the loop for the number of random numbers, the host control circuit 2100 first creates a random number SEED (step S1672). Random number SEED creation in the random number initialization process is executed based on the following equation (3).
SEED (random numbers 1 to 4) = (RTC time (seconds) + (RTC time (minutes) x 60) + random number number (random numbers 1 to 4)) x initial prime number...Equation (3)

After creating the random number SEED in step S1672, the host control circuit 2100 stores the random number SEED created in step S1672 in the random number backup, that is, the SRAM 2100b (for example, see FIG. 10) (step S1673). The random number SEED backed up here is the random number SEED created this time, but the information backed up up to the previous time may be deleted or may be continued to be stored.

After the host control circuit 2100 executes the processing in steps S1672 and S1673 for the number of random numbers (in this embodiment, four random numbers 1 to 4), it exits the loop for the number of random numbers and ends the random number initialization process.

In this way, the minutes and seconds of the RTC time are used in the random number initialization process. Therefore, the random number SEED at the time of initialization is related to the time when the power is turned on, down to the minute and second level.

Next, the random number periodic update process will be described with reference to FIG. The random number regular update process is a process that periodically updates random numbers 1 to 4 even if none of them are used while waiting for the bank flip to end as shown in FIG.

As shown in FIG. 95, in the random number periodic update process, the host control circuit 2100 performs random number 1 acquisition processing (step S1681), random number 2 acquisition processing (step S1682), random number 3 acquisition processing (step S1683), and random number 4 acquisition processing. The processing (step S1684) is performed in this order. Note that the random number periodic update process is always executed while waiting for the bank flip to end. Further, even if the bank flip completion wait does not occur due to a processing failure in any of the main loops, the host control circuit 2100 performs the random number periodic update process once in one frame.

As shown in FIG. 96(a), in the random number 1 acquisition process, random number 1 is updated (step S1685), that is, after random number 1 is acquired, random number 1 is updated. Thereafter, the obtained random number 1 is stored in the random number 1 backup, that is, the SRAM 2100b (see FIG. 10, for example) (step S1686). Similarly, as shown in FIG. 96(b), the random number 2 acquisition process updates the random number 2 (step S1687) and backs up the random number 2 (step S1688). Similarly, as shown in FIG. 96(c), the random number 3 acquisition process updates the random number 3 (step S1689) and backs up the random number 3 (step S1690). Similarly, as shown in FIG. 96(d), the random number 4 acquisition process updates the random number 4 (step S1691) and backs up the random number 4 (step S1692). Note that the random numbers backed up in step S1686, step S1688, step S1690, and step S1692 are the random numbers obtained this time, but information backed up previously may be deleted or may be continued to be stored. .

Note that each of the random numbers 1 to 4 is obtained from random numbers generated within the range of 0 to 32767, but the range of the generated random numbers is not limited to this.

As shown in FIG. 97, in the random number acquisition process executed when a random number is used, the host control circuit 2100 first performs the random number 3 acquisition process (step S1693). This random number 3 acquisition process is a process for acquiring a random number to be used for determining the random number to be used among random number 1, random number 2, and random number 4. After executing the random number 3 acquisition process in step S1693, the host control circuit 2100 moves to step S1694.

In step S1694, the host control circuit 2100 determines whether the remainder number when the random number obtained in the random number 3 obtaining process in step S1693 is divided by 4 (hereinafter simply referred to as "remainder number") is 0 or 1. Determine whether If the remainder is 0 or 1 (YES in step S1694), random number 1 acquisition processing is performed (step S1695). On the other hand, if the remainder is neither 0 nor 1 (NO in step S1694), the process moves to step S1696.

Host control circuit 2100 determines whether the remainder is 2 in step S1696. If the remainder is 2 (YES in step S1696), random number 2 acquisition processing is performed (step S1697). On the other hand, if the remainder is not 2 (NO in step S1696), the process moves to step S1698.

Host control circuit 2100 determines whether the remainder is 3 in step S1698. If the remainder is 3 (YES in step S1698), random number 4 acquisition processing is performed (step S1699). On the other hand, if the remainder number is not 3 (NO in step S1698), this means that there is no remainder number between 0 and 3, so the process is restarted from step S1693.

Note that the random number 1 acquisition process (step S1695), the random number 2 acquisition process (step S1697), the random number 3 acquisition process (step S1693), and the random number 4 acquisition process (step S1699) are as shown in FIG. .

In this way, in the random number acquisition process that is executed when random numbers are used, the random numbers selected from random number 1, random number 2, and random number 4 are updated, but the random numbers that were not selected are not updated. Not done.

In addition, in the pachinko game machine 1 of this embodiment, random number initialization processing is performed when the power is turned on, and when random numbers are used, random number acquisition processing is performed for the selected random number, and waits for the end of the bank flip or waits for the end of the bank flip. Random number periodic update processing is performed even when no waiting occurs.

Note that the calculation formula when updating the random number is as shown in the following formula (4).
Current updated value = (previous updated value x prime number of each random number) + 1...Equation (4)
Here, the return value of the random number acquisition process is a value of 0 to 32767 that is right shifted from 32 bits to 16 bits. That is, the current updated value calculated based on the above equation (4) is expressed in 32 bits, and this 32-bit current updated value is right-shifted from 32 bits to 16 bits and returned. Then, the 16th bit is masked, and the value shown in the 1st to 15th bits (any one of 0 to 32767) is determined as the current updated value.

By performing the above-described sub-random number processing, the obtained random numbers can be made random, and the occurrence of bias in the obtained random numbers can be suppressed. In particular, since the time at which the power is turned on affects the random number SEED at the time of initialization down to the minute and second level, it is possible to change the initial value each time.

[10-14-1. Modified example of sub-random number processing]
Although the sub-random number processing in this embodiment has been described above, the sub-random number processing (modified example) described below may be performed in place of or in combination with the above-described sub-random number processing. Further, the sub-random number processing (modified example) described below may be applied to the random number processing executed by the main CPU 101. A modification of this sub-random number processing will be described with reference to FIGS. 98 and 99. Note that FIG. 98 is a sub-control main process (overall flow) executed by the host control circuit 2100 for explaining a modification of the sub-random number process. However, FIG. 98 only shows processes necessary for explanation, and other processes are omitted. FIG. 99 is a flowchart illustrating an example of reception interrupt processing executed by host control circuit 2100.

The host control circuit 2100 first performs a random number initialization process (step S1701), which is performed as one of various initialization processes (see step S1201 in FIG. 61). In this random number initialization process, a random number seed of, for example, a power of 2 and a current random number seed number are prepared, and a predetermined initial value is set in the stack pointer.

After performing the random number initialization process in step S1701, the host control circuit 2100 enters the main loop, performs subdevice input processing (step S1702), and then performs various request control processes (step S1703). In this various request control processing (step S1703), the request is output to various devices based on the request created in step S1705, which will be described later, one frame before.

After performing subdevice input processing (step S1702) and various request control processing (step S1703), the host control circuit 2100 performs random number table creation processing (step S1704). In the random number table creation process in step S1704, a new random number table is created by updating the random numbers registered in the random number table having a size that is a power of 2 at the drawing timing. To obtain the random number registered in the random number table, a random number seed determined based on the current random number seed number among the random number seeds of a power of 2 is used, for example. For example, if 23 (8) random number seeds a to h are prepared, and the current random number seed number is 4, the random number seed d is used.

In step S1704, the host control circuit 2100 can create a random number table having a size of, for example, 25 (32), and 32 random numbers are registered in this random number table. When the random number is registered in the random number table, the host control circuit 2100 updates the value of the random number seed. The random number seed is updated by multiplying the previous update value by a prime number and then adding 1, as in equation (4) above. Note that the size of the random number table may be any power of 2 (numbers) in this modified example, and 25 (32) is used, but any size that is a power of 2 (numbers) may be used. .

As shown in FIG. 99, the random number seed used to create the random number table in step S1704 is based on the value of the CPU counter by the CPU processor of the host control circuit 2100, for example, when receiving a serial command (step S1801). (Step S1802). In the random number seed update process of step S1802, the random number seed used to create the random number table is updated by incrementing the random number seed number and setting the incremented random number seed number as the current random number seed number.

Returning to FIG. 98, after performing the random number table creation process in step S1704, the host control circuit 2100 enters a packet reception loop.

In the packet reception loop, the host control circuit 2100 performs animation construction processing (step S1705) to create a request for animation for video production, and performs random number acquisition processing when random numbers are used (step S1706). Note that the request created in step S1705 is output in the next frame after waiting in a buffer.

In the random number acquisition process of step S1706, the host control circuit 2100 acquires a random number from the random number table created in step S1704. The random numbers obtained here are used for a lottery related to the performance (for example, a lottery for determining an animation for a moving image performance) executed by the host control circuit 2100. When the host control circuit 2100 obtains the random number from the random number table in step S1706, it updates (increments) the reference position of the random number table. Note that the reference position of the random number table is only performed when a random number is acquired from the random number table, and is not performed in the random number table creation process of step S1704.

The host control circuit 2100 repeatedly performs the processing of steps S1705 and S1706 for each received packet. After the host control circuit 2100 performs steps S1705 and S1706 for each packet received, the host control circuit 2100 exits the packet reception loop.

After exiting the packet reception loop, the host control circuit 2100 performs animation update processing (step S1707), and then waits for bank flip/bank flip completion (step S1708).

The host control circuit 2100 repeatedly performs the processing from step S1702 to step S1708 in the main loop with a period of 33.3 msec.

According to the modification of the sub-random number processing described above, even if there are multiple opportunities to obtain random numbers within the packet reception loop, the same random number table that has already been created is simply used to change the reference position and obtain the random numbers. Therefore, it is possible to reduce the control load on the host control circuit 2100 while imparting irregularity to the obtained random numbers.

[10-15. Other expansion examples]
The present invention can be applied to the pachinko game machine 1 of this embodiment to all types of game machines in which a game is played using game media and a benefit is awarded based on the result of the game. That is, not only is the game played by ejecting or inserting game media through the physical actions of the player, and the game media are paid out based on the result of the game, but the main control circuit 100 itself It may also be possible to electromagnetically manage game media owned by a player, and to enable games played by circulating enclosed game balls or games played without medals. Further, the device that electromagnetically manages the game media owned by the player may be a game media management device that is attached to (connected to) the main control circuit 100 and manages the game media.

When managed by a gaming media management device connected to the main control circuit 100, the gaming media management device is a device that has a ROM and RWM (or RAM) and is installed in the gaming machine, It is connected to a two-way communication function via a media handling device and a predetermined interface, and provides the gaming media necessary for the gaming media lending operation (i.e., when the player performs the gaming media insertion operation). operation) or the payout operation of the game media when a prize is won (the role is established) related to the payout of the game media (i.e., payout of the game media to the player and win the necessary game media) It may be possible to perform an operation of electromagnetically recording a game medium used for a game. In addition, the game media management device not only manages the actual number of game media, but also displays the number of game media held on the front of the pachinko gaming machine 1 based on the management result of the number of game media. A game media number display device (not shown) may be provided, and the number of game media displayed on this owned game media number display device may be managed. In other words, the game media management device may be capable of recording and displaying the total number of game media that can be used by a player in a game using an electromagnetic method.

In addition, in this case, the game media management device has the ability to allow the player to freely transmit a signal indicating the number of recorded game media to the external game media handling device, and In addition to being operated directly by a person, the number of recorded game media cannot be reduced, and an external connection terminal board (not shown) is provided between the player and an external game media handling device. In some cases, it is desirable to have the ability to allow a player to transmit a signal indicating the number of recorded game media except through the external connection terminal board.

In addition to the above, the gaming machine is equipped with a lending operation means, a return (payment) operation means, and an external connection terminal board that can be operated by the player, and the gaming media handling device has an input slot for valuables such as banknotes, and a recording medium. (For example, an IC card) insertion slot, a non-contact communication antenna for depositing electronic money etc. from a mobile terminal, various operation means such as lending operation means, return operation means, external connection terminal board on the side of the gaming media handling device. (both not shown).

The flow of the game at that time is, for example, when the player deposits valuable value into the gaming media handling device using one of the methods, and subtracts a predetermined number of valuable values based on the operation of one of the lending operation means described above. Then, the amount of game media corresponding to the value subtracted from the game media handling device to the game media management device is increased. The player then plays the game and repeats the above operations if more game media are required. After that, as a result of the game, a predetermined number of game media are acquired, and when the game is finished, the number of game media is transmitted from the game media management device to the game media handling device by operating one of the return operation means, and the game The medium handling device ejects the recording medium on which the number of game media is recorded. When the game media management device transmits the number of game media, it clears the number of game media stored in itself. The player takes the ejected recording medium to a prize counter or the like to exchange it for prizes, or moves the game machine to play a game based on the game medium recorded on another machine.

In the above example, all game media are sent to the game media handling device, but the game machine or game media handling device only transmits the number of game media desired by the player, and the game media owned by the player is transmitted. It is also possible to divide and process. Furthermore, instead of just ejecting the recording medium, cash or cash equivalent may be ejected, or it may be stored in a mobile terminal or the like. Further, the game media handling device may be configured to be able to insert a member recording medium of a gaming parlor, and to store the membership recording medium in the member recording medium so that it can be played again at a later date.

Further, in the gaming machine or the gaming media handling device, by operating a predetermined operation means (not shown), a locking operation for locking the data communication of gaming media or valuable value can be performed on the gaming media handling device or the gaming media management device. Good too. In this case, information that only the player can know, such as a one-time password, may be set, or the player may be recorded using an imaging means provided in the game medium handling device.

In addition, although the above describes the case where the game media management device is applied to a pachinko game machine, the game media management device can also be applied to a pachislot machine, a slot machine that uses game balls, and an enclosed game machine. A player's gaming media can also be managed.

In this way, by providing the above-mentioned game media management device, the number of parts inside the game machine can be reduced compared to the case where game media are physically used in the game, and the cost and manufacturing cost of the game machine can be reduced. Not only can players be prevented from coming into direct contact with gaming media, the gaming environment can be improved, noise can be reduced, and the power consumption of gaming machines can also be reduced by reducing the number of parts. It also happens. In addition, it is possible to prevent fraudulent acts through the game media and the game media input and payout ports. That is, it is possible to provide a gaming machine that can improve various environments surrounding the gaming machine.

In addition, communication cables are used to transmit data regarding increases and decreases in gaming media due to consumption, lending, and payout of gaming media to enclosed gaming machines that are configured to allow gaming without the gaming media being ejected to the outside. When the present invention is applied to a gaming system having a gaming media management device connected to the gaming media management device so as to be able to transmit and receive optical signals via the gaming media management device, the gaming system may be configured as follows.

Below, an outline of the enclosed gaming machine will be explained. In the enclosed game machine, the firing device is located above the game area and fires game balls as game media from above into the game area. When the player operates the handle, the ball feed solenoid is driven by the payout control circuit, and the ball feed pestle pushes out the waiting game ball toward the launch pad. This moves the game ball to the launch pad. Further, a subtraction sensor is provided on the path from the standby position to the launch pad, and detects the game ball moving to the launch pad. When a game ball is detected by the subtraction sensor, the number of balls held is subtracted by 1. Since the game ball is thus configured to be launched from above as a game medium into the game area, so-called return balls (foul balls) can be avoided in the enclosed game machine. The game balls ejected from the game area after rolling in the game area are polished by a ball polishing device. The game balls polished by the ball polishing device are transported upward by the lifting device and guided to the firing device. The game balls are not discharged to the outside of the enclosed game machine, but are configured so that a certain number (for example, 50) of game balls circulate through a series of paths in the game machine.

In an enclosed type game machine, the game balls are not discharged to the outside of the game machine, so an upper tray or a lower tray for temporarily holding the game balls is not provided. In an enclosed game machine, the game balls are not discharged to the outside, so the game balls are not actually in the hands of the player, and the number of game balls does not actually increase or decrease as a result of playing a game. In an enclosed game machine, a player starts playing after acquiring balls lent from a game media management device. Here, obtaining a ball means that the player obtains game media in terms of data management. Then, by firing the game balls from the firing device, the balls held are consumed, and the number of balls held decreases. In addition, when the game balls pass through each winning hole provided in the gaming area, the number of balls is paid out in accordance with the conditions set according to the winning hole, and the number of balls held increases. Furthermore, the number of balls held increases by lending from the game media management device. Note that "consumption, lending, and payout of game media" indicates that the balls held are consumed, loaned, and paid out. Further, "increase/decrease in game media" indicates an increase/decrease in the number of balls held due to consumption, lending, and payout. Furthermore, "data regarding increases and decreases in game media due to consumption, lending, and payout of game media" is data regarding the decrease in the number of balls held due to game balls being fired and the increase in the number of balls held due to lending and payout.

The enclosed gaming machine has a payout control circuit and a touch panel type liquid crystal display device. The payout control circuit is connected to various sensors that detect when the game ball passes through each winning hole. The payout control circuit manages the number of balls held. For example, when a game ball passes through each winning hole, the number of game balls paid out due to this is added to the number of balls held. Furthermore, when a game ball is fired, the number of balls held is subtracted. The payout control circuit transmits data regarding the number of balls held to the game media management device by the player's operation. Further, the above liquid crystal display device is located at the top of the gaming machine, and accepts requests for converting the gaming value managed by the gaming media management device into balls held (renting balls) and counting balls held (returning). Then, these requests are transmitted to the payout control circuit via the game media management device, and the payout control circuit is instructed to transmit data regarding the current number of balls held to the game media management device. Here, "gaming value" refers to money/banknotes, prepaid media, tokens, electronic money, tickets, etc., which can be converted into balls by the gaming media management device. In this embodiment, the game media management device is a so-called CR unit, and is configured to be able to accept banknotes, prepaid media, and the like. Further, the counted balls can be used for exchanging prizes, etc. at a game hall where the game system is installed.

Furthermore, the enclosed gaming machine has a backup power source. As a result, even if the power is turned off at night, the data immediately before the power is turned off can be retained. Further, by using this backup power source, for example, the door opening sensor may continue to detect the opening of the door frame. This can also prevent fraudulent acts at night. In this case, information such as the number of times the door frame has been opened may be stored. Furthermore, when the power is turned on, information such as the number of times the door frame has been opened may be output to a liquid crystal display device or the like of the gaming machine.

The gaming media management device has a gaming machine connection board. The game media management device is configured to transmit and receive data (transmission signals) to and from the game machine via the game machine connection board. The transmitted and received data includes the unique ID of the CPU provided in the main control circuit, the unique ID of the CPU provided in the payout control circuit, the gaming machine manufacturer code stored in the gaming machine, the security chip manufacturer code, and the gaming machine manufacturer code stored in the gaming machine. This is information such as the model code of the machine. Then, when the transmission source transmits a transmission signal with one of the gaming machine and the gaming media management device as the transmission source and the other as the transmission destination, the transmission destination that received the transmission signal receives the same signal as the transmission signal. A confirmation signal is transmitted to the transmission source, and the transmission source compares the transmission signal and the confirmation signal to determine whether or not they are the same.

In this way, by comparing the confirmation signal sent from the destination with the transmission signal at the transmission source and determining whether they are the same, the signal transmitted from the transmission source can be prevented from being tampered with. You can confirm that the message is being sent to the sender. Thereby, fraudulent acts such as tampering with transmission/reception signals between the gaming machine and the gaming media management device can be suppressed.

Further, in the gaming system, the transmission source has a modulation section that modulates a signal, and the transmission source transmits the signal modulated by the modulation section as the transmission signal, and the transmission destination transmits the signal modulated by the modulation section. It is also possible to include a demodulation section that performs demodulation.

As a result, even if the transmission and reception signals between the gaming machine and the gaming media management device were read, it would be difficult to decipher the signals, and the transmission and reception signals between the gaming machine and the gaming media management device would be difficult to decipher. Fraudulent acts such as falsification can be suppressed.

In addition, in the gaming system, when the transmission destination receives the transmission signal from the transmission source, the transmission destination sends an approval signal, which is a signal indicating that the transmission signal has been received, separately from the confirmation signal. It may also be sent to the sender.

By comparing the transmitted signal and the confirmation signal, it is possible to not only confirm that a legitimate signal has been transmitted and received, but also to confirm that a legitimate signal has been transmitted and received based on the authorization signal. Therefore, it is possible to further strengthen the suppression of fraudulent acts.

[10-16. Processing related to the movement of accessories in the accessory group]
The processing related to the operation of the accessory in the accessory group 1000 (the accessory that constitutes the accessory group 1000 (including the actuating member that constitutes the accessory) will be described with reference to FIGS. 100 to 107. Note that the accessories mentioned here are movable accessories that can be operated by driving various power sources such as motors and solenoids, and do not include decorative accessories that are not movable. Note that the accessory is driven based on the control signal and data (for example, excitation data described below) output from the host control circuit 2100, but the excitation data includes the number of steps (for example, when the power source is a stepping motor). The data is not limited to specific data as long as it has a unit representing the magnitude of power, such as excitation time or excitation time.

The processing related to the operation of the accessories in the accessory group 1000 can be broadly divided into accessory initial operation processing performed by the host control circuit 2100 when the power is turned on, and sub-control main processing (or sub-control main processing) performed by the host control circuit 2100. There is an accessory control process that is performed within the various request control processes in the process. Below, the accessory initial movement process and the accessory control process will be explained in order.

[10-16-1. Accessories initial movement processing]
First, with reference to FIG. 100, the accessory initial operation process performed by the host control circuit 2100 as one of various initialization processes (for example, see step S1201 in FIG. 61) will be described. FIG. 100 is a flowchart showing an example of the accessory initial operation process executed by the host control circuit 2100 in this embodiment.

First, the host control circuit 2100 sets the number of times the motor used to operate the accessory, that is, the initial position recovery counter, to "0" (step S1901).

After the process of step S1901, the host control circuit 2100 determines whether or not the accessory of the accessory group 1000 is at the initial position (step S1902). In the process of step S1902, the host control circuit 2100 detects whether or not the accessory detection sensor group 1002 detects the presence of the accessory at the initial position (more specifically, the accessory detection sensor group 1002 detects whether or not the accessory is at the initial position. The determination is made based on the detection state of the accessory detection sensor provided corresponding to the accessory to be determined.

When the host control circuit 2100 determines that the accessory is not in the initial position (NO in step S1902), the host control circuit 2100 determines whether the number of operations is equal to or greater than a specified number (for example, 10 times), that is, if the value of the initial position recovery counter is "10". ” or more (step S1904).

If the host control circuit 2100 determines that the number of operations is less than a prescribed number (for example, 10 times) (NO in step S1904), it performs an initial position movement operation (step S1906). This initial position movement operation is an operation of driving the motor to move the accessory to the initial position.

After processing in step S1906, the host control circuit 2100 adds "1" to the number of motor operations, that is, the value of the initial position recovery counter (step S1907), and moves to step S1902. Therefore, as long as it is determined that the accessory is not at the initial position (NO in step S1902) until the number of times the motor operates reaches a predetermined number (for example, 10 times), the host control circuit 2100 performs the operations in step S1902, step S1904, and step The initial position movement processing in steps S1906 and S1907 is repeated.

If the host control circuit 2100 determines in step S1904 that the number of operations is equal to or greater than the specified number (for example, 10 times) (YES in step S1904), the host control circuit 2100 ends the initial position movement process and sets the transition to the error motor operation stop state. Processing is performed (step S1905). When the state is shifted to the error motor operation stop state, the operations of all accessories are stopped, and the host control circuit 2100 ends the accessory initial operation process and returns the process to the sub-control main processing (see, for example, FIG. 61).

On the other hand, if it is determined in step S1902 that the accessory is in the initial position (YES in step S1902), the host control circuit 2100 moves to step S1901 and determines whether or not the accessory is in the initial position for the next accessory. It is determined (step S1902). Then, when the host control circuit 2100 determines that all the motors for operating the accessory to be used are at the initial position (YES in step S1902), the host control circuit 2100 performs power-on processing (step S1903), and performs accessory initial operation processing. is finished, and the process returns to the sub-control main process (see, for example, FIG. 61).

Note that the power-on processing in step S1903 is a process of moving the accessory to the maximum range of motion and then moving it to the initial position in order to check the operation of the accessory. In the power-on processing in step S1903, after moving the accessory objects to their maximum range of motion, the movement of moving them to the initial position may be performed on all the accessory objects at the same time, or one or more accessory objects may be moved in sequence. You can also do this.

In the power-on process in step S1903 above, that is, the process of moving the accessory to the initial position after moving it to its maximum range of motion, it is sufficient to be able to confirm the movement of the accessory, so If there is an accessory that moves (for example, an accessory that moves from the initial position to the first stage and then from the first stage to the second stage), to check the operation of the accessory, move it from the initial position to the first stage. Control may be performed to perform a first operation check in which the robot moves up to the initial position, and a second operation check in which the robot moves from the initial position to the first stage and then to the second stage.

Also, for example, a first accessory that is driven in stages (for example, a first accessory that moves from an initial position to a first stage, and then moves from the first stage to a second stage), and a first accessory that moves from an initial position to a second stage. If there is a second accessory that is driven to a predetermined position, a first operation check in which the first accessory moves from the initial position to the first stage is performed to check the operation of the accessory, and then A third operation check is performed in which the second accessory moves from the initial position to a predetermined position, and then a second operation check is performed in which the first accessory moves from the first stage to the second stage. It's okay. In this case, by performing the third operation check between the first operation check and the second operation check, it becomes possible to efficiently check the operation of the plurality of accessories.

In this way, in the accessory initial operation process, the host control circuit 2100 determines whether or not the accessory is in the initial position when the power is turned on, using the accessory detection sensor group 1002 (more specifically, among the accessory detection sensor group 1002). (step S1902), and if all the accessories are in the initial position, when the power is turned on, Processing (step S1903) is performed. If there is an accessory that is not at the initial position (NO in step S1902), the initial position movement process (steps S1902, S1904, S1906, and S1907) is repeated a predetermined number of times (for example, 10 times). If the initial position movement processing (steps S1902, S1904, S1906, and S1907) is performed a specified number of times (for example, 10 times) and there is no accessory at the initial position (YES in step S1904), the host control circuit 2100 detects an error. A transition setting process to a motor operation stop state is performed (step S1905). As a result, when the power is turned on, it is possible to check whether the motor for operating the accessory is operating normally or not, and to move the accessory to the initial position if the accessory is not at the initial position. Can be done. In addition, if the accessory happens to be not at the initial position due to a minor trouble (error), the motor error operation can be avoided, and if the accessory continues to be unable to return to the initial position, , it is possible to suppress the occurrence of serious errors by shifting the motor to the motor error operation stop state.

[10-16-2. Accessories control processing]
Next, with reference to FIG. 101, the accessory control process performed in step S210 in the sub-control circuit main process (see FIG. 52) will be described. FIG. 100 is a flowchart showing an example of accessory control processing executed by the host control circuit 2100 in this embodiment.

First, the host control circuit 2100 determines whether the current operating status is in a command reception standby operation in which a command from the main control circuit 100 can be received (that is, whether the command reception standby flag is ON or not). (Step S1911).

If the host control circuit 2100 determines that the current operating status is not in the standby operation for receiving a command from the main control circuit 100 (that is, the command reception standby flag is OFF) (NO in step S1911), the host control circuit 2100 performs accessory control. The process is ended and the process is moved to the sub-control circuit main process (see FIG. 52).

If the host control circuit 2100 determines that the current operating status is in a state of waiting for reception of a command from the main control circuit 100 (YES in step S1911), the host control circuit 2100 determines whether a command related to production has been received from the main control circuit 100. (Step S1912). The commands related to production that are subject to judgment in this process are, for example, special symbol fluctuation start commands, special symbol fluctuation stop commands, demo commands, fluctuation confirmation commands, and hit-related commands related to jackpots. When received by the control circuit 2100, each accessory in the accessory group 1000 is driven.

If the host control circuit 2100 determines that it has not received a command regarding the performance from the main control circuit 100 (NO in step S1912), it ends the accessory control process and transfers the process to the sub-control circuit main process (see FIG. 52). Move to.

On the other hand, when the host control circuit 2100 determines that a command related to presentation has been received from the main control circuit 100 (YES in step S1912), the host control circuit 2100 performs processing when receiving a presentation command (step S1913). In this production command reception process, as shown in FIG. 102, which will be described later, in response to the production related command received from the main control circuit 100, the fluctuation start command reception process (step S19133), the initial position restoration accessory process, etc. The following processes are performed: operation processing (step S19134), processing of accessories when receiving a demo command (step S19136), processing of accessories when receiving a fluctuation confirmation command (step S19138), and processing of accessories when receiving a winning command (step S19139). be exposed. Details of each of these processes will be described later.

In addition, although this embodiment describes an example in which each process of step S19133, step S19136, step S19138, and step S19139 is performed in the accessory control process, the present invention is not limited to this, and commands related to production Each of these processes may be performed as an interrupt process when the command is received, or each of these processes may be performed immediately after the command analysis process described above (see step S204 in FIG. 52).

After executing the production command reception process (step S1913), the host control circuit 2100 determines whether acceptance of accessory requests is set (step S1914).

If the host control circuit 2100 determines that acceptance permission for accessory requests is not set (NO in step S1914), the host control circuit 2100 ends the accessory control processing and moves the processing to the sub-control circuit main processing (see FIG. 52). .

On the other hand, if it is determined that permission to accept accessory requests is set (YES in step S1914), the host control circuit 2100 acquires the accessory request stored in the accessory request buffer in the animation construction process of FIG. Processing is performed (step S1915).

In addition, in the present embodiment, in the process of step S1915, the host control circuit 2100 starts by generating a request for performance control in order to synchronize the performance operation by each accessory in the accessory group 1000 with the performance operation by the display device 16. After two frames have elapsed, the above-mentioned accessory request acquisition process is executed.

Next, the host control circuit 2100 transmits excitation data to the motor driver via the I2C controller 2610 based on the acquired accessory request (step S1916), and then sets the command reception standby flag to ON (step S1917). ). Next, the host control circuit 2100 determines whether a communication error signal has been received from the I2C controller 2610 (step S1918). In this process, the host control circuit 2100 may determine whether a communication error between the I2C controller 2610 and the motor controller 2700 or an error in the I2C controller 2610 has been detected (obtained or input).

If the host control circuit 2100 determines that a communication error signal has been received from the I2C controller 2610 (YES in step S1918), it sets a communication controller error (step S1921). After the process in step S1921, the host control circuit 2100 ends the accessory control process and moves the process to the sub-control circuit main process (see FIG. 52).

On the other hand, if it is determined that the communication error signal has not been received from the I2C controller 261 (NO in step S1918), the host control circuit 2100 determines whether the address of each motor driver can be accessed (step S1919).

If the host control circuit 2100 determines that the address of each motor driver cannot be accessed (NO in step S1919), it sets a connection error (step S1922). After the process of step S1922, the host control circuit 2100 ends the accessory control process and moves the process to the sub-control circuit main process (see FIG. 52).

If the host control circuit 2100 determines that the address of each motor driver can be accessed (YES in step S1919), it determines whether the operation of each accessory (each motor) has ended normally (step S1920).

If the host control circuit 2100 determines that the operation of each accessory (each motor) has ended normally (YES in step S1920), the host control circuit 2100 ends the accessory control process and transfers the process to the sub-control circuit main process (see FIG. 52). ). On the other hand, if it is determined that the operation of each accessory (each motor) has not ended normally (NO in step S1920), the host control circuit 2100 sets a data error (step S1923). After the process of step S1923, the host control circuit 2100 ends the accessory control process and moves the process to the sub control circuit main process (see FIG. 52).

[10-16-3. Processing when receiving production commands]
Next, with reference to FIG. 102, the process performed at step S1913 in the accessory control process (see FIG. 101) when receiving a performance command will be described. FIG. 102 is a flowchart illustrating an example of processing when receiving a production command. This process is executed by the host control circuit 2100 based on reception of the production-related command transmitted from the main control circuit 100.

First, in step S19131, host control circuit 2100 sets the command reception standby flag to OFF. Then, the host control circuit 2100 executes each process according to the effect-related command received in step S1912. Specifically, if the command received in step S1912 is a fluctuation start command (YES in step S19132), the processing for receiving a fluctuation start command (step S19133) is executed. Thereafter, the host control circuit 2100 executes the initial position restoration accessory operation process (step S19134), and ends the process when receiving the production command.

In addition, if the command received in step S1912 is a demo command (NO in step S19132 and YES in step S19135), a role material process (step S19136) is executed when a demonstration command is received, and when a production command is received, Finish the process.

Further, if the command received in step S1912 is a fluctuation confirmation command (NO in both steps S19132 and S19135, and YES in step S19137), execute the processing for receiving the fluctuation start command (step S19138). Then, the process when receiving a production command is ended.

Furthermore, if the command received in step S1912 is neither a change confirmation command, a demo command, nor a change confirmation command (NO in steps S19132, S19135, and S19137), it is determined that a winning command has been received. , executes the accessory process (step S19139) when receiving the winning command, and ends the process when receiving the effect command. Note that if the command received in step S1912 is neither a change confirmation command, a demo command, nor a change confirmation command, instead of determining that a winning command has been received, the command received in step S1912 is determined to be a winning command. Based on the determination that the winning command is received, the accessory process (step S19139) may be executed.

The above-mentioned accessory processing when receiving the fluctuation start command (step S19133), initial position restoration accessory operation processing (step S19134), accessory processing when receiving the demo command (step S19136), accessory processing when receiving the fluctuation start command (step S19138) ) and the accessory processing when receiving a winning command (step S19139) will be described below.

[10-16-4. Accessory processing when receiving fluctuation start command]
Next, with reference to FIG. 103, a description will be given of the accessory processing upon reception of the special symbol fluctuation start command performed in step S19133 during the production system command reception processing (see FIG. 102). FIG. 103 is a flowchart showing an example of accessory processing when receiving a special symbol variation start command. This process is executed by the host control circuit 2100 based on receiving the special symbol fluctuation start command transmitted from the main control circuit 100.

First, the host control circuit 2100 determines whether all the accessories (including the actuating members forming the accessories) of the accessory group 1000 are at the initial position (step S19141). In the process of step S19141, the host control circuit 2100 makes a determination based on the detection state of the accessory object detection sensor group 1002 that detects that each accessory object is present at the initial position.

If the host control circuit 2100 determines that all accessory objects are in the initial position (YES in step S19141), it sets permission to accept accessory requests (step S19142). When permission to accept an accessory request is set, the control state of each accessory in the accessory group 1000 shifts from a command reception standby state to an accessory request acceptance permission state.

Next, the host control circuit 2100 sets the initial position recovery counter to "0" (step S19143). After the processing in step S19143, the host control circuit 2100 ends the accessory processing upon reception of the fluctuation start command.

On the other hand, in step S19141, if the host control circuit 2100 determines that there is an accessory that is not in the initial position, that is, one or more accessory objects are not in the initial position (NO in step S19141), the host control circuit 2100 sets the initial position recovery counter to " 1'' is executed (step S19144).

After executing the process in step S19144, the host control circuit 2100 determines whether the initial position recovery counter is equal to or greater than a predetermined number of times (for example, 10 times) (step S19145).

If the host control circuit 2100 determines that the initial position recovery counter is equal to or greater than the specified number of times (YES in step S19145), it performs a transition setting process to the error motor operation stop state (step S19146). When the state is shifted to the error motor operation stop state, the operations of all accessories are stopped. After the processing in step S19146, the host control circuit 2100 ends the accessory processing upon reception of the fluctuation start command.

If the host control circuit 2100 determines that the initial position recovery counter is not equal to or greater than the specified number of times (NO in step S19145), it sets the transition to the initial position recovery operation state (step S19147). In the initial position restoration operation state, an initial position restoration operation process to be described later is executed.

In this way, in the accessory processing upon receiving the fluctuation start command, the host control circuit 2100 uses the accessory detection sensor group 1002 to detect whether all the accessory objects are in the initial position when receiving the special symbol fluctuation start command. (Step S19141) If there is an accessory that is not in the initial position, settings are made to disallow (prohibit) reception of accessory requests and to shift to the initial position recovery operation state (Step S19147). Then, when the number of consecutive accessory processing operations upon receiving the fluctuation start command in which it is determined in step S19141 that one or more accessory objects are not in the initial position reaches a predetermined number (for example, 10 times), the host control circuit 2100 Motor error operation is set to stop. In other words, even if there is an accessory that is not in the initial position when the special symbol starts changing, the special symbol will continue to change a specified number of times (for example, 10 times) under the situation that there is an accessory that is not in the initial position. Until this point, a setting is made to shift to the initial position recovery operation state, and when a specified number of times is reached, a setting is made to shift to the error motor operation stop state. Therefore, if there is an accessory that happens to not return to its initial position due to a minor trouble (error), the accessory that cannot return to its initial position can be If the error continues, it is possible to suppress the occurrence of a serious error by shifting the motor error operation to a stopped state.

[10-16-5. Initial position restoration accessory action processing]
Next, with reference to FIG. 104, the initial position restoration accessory motion process performed in step S19134 during the production-related command reception process (see FIG. 102) will be described. FIG. 104 is a flowchart illustrating an example of the initial position restoration accessory motion process. This process is executed by the host control circuit 2100 based on the setting of transition to the initial position recovery operation state in step S19147 of the function processing upon receipt of the fluctuation start command (see FIG. 103).

First, the host control circuit 2100 determines whether the state is in the initial position recovery operation state, that is, whether the transition to the initial position recovery operation state has been set in step S19147 of the accessory processing upon receiving the fluctuation start command (see FIG. 103). It is determined whether or not (step S19151).

If it is not in the initial position restoration operation state (NO in step S19151), the host control circuit 2100 ends the initial position restoration accessory operation process.

When the host control circuit 2100 determines that the initial position restoration operation state is in progress (YES in step S19151), the host control circuit 2100 determines whether or not the accessory is at the initial position using the accessory detection sensor group 1002 (more specifically, the accessory detection sensor group 1002 Among them, the accessory object detection sensor provided corresponding to the accessory object to be determined as to whether or not it is in the initial position detects it, and it is determined whether or not the accessory object is in the initial position (step S19152).

When the host control circuit 2100 determines that the accessory is not at the initial position (YES in step S19152), it executes the initial position movement process (step S19153). This initial position movement operation process is a process in which the motor is driven to return the accessory to the initial position.

The processes in step S19152 and step S19153 are performed for the number of motors that drive the accessory.

On the other hand, if the host control circuit 2100 determines that the accessory is at the initial position (NO in step S19152), the host control circuit 2100 performs processing to determine whether the next accessory is at the initial position without performing the process of step S19153. The process moves to (step S19152).

After the host control circuit 2100 performs the process of step S19152 and/or step S19153 for the number of motors that drive the accessory, the host control circuit 2100 ends the initial position restoration accessory operation process.

[10-16-6. Functional processing when receiving demo command]
Next, with reference to FIG. 105, a description will be given of the accessory processing when receiving a demo command, which is performed in step S19136 in the processing when receiving a production command (see FIG. 102). FIG. 105 is a flowchart illustrating an example of accessory processing when receiving a demo command. This process is executed by the host control circuit 2100 based on receiving the demo command transmitted from the main control circuit 100.

First, the host control circuit 2100 determines whether there is a motor error, that is, whether an error due to a malfunction of the motor for driving the accessory has been detected (step S19161). In this process, the host control circuit 2100 detects, for example, various errors (communication controller error, connection error, data error) set in the process after step S1918 in the accessory control process (see FIG. 101). Determine whether or not there is one.

If the host control circuit 2100 determines that there is no motor error, that is, no error due to a malfunction of the motor for driving the accessory has been detected (the motor is normal) (YES in step S19161), the host control circuit 2100 excites the accessory. A release process is performed (step S19162). In this process, host control circuit 2100 stops outputting excitation data to all motor drivers.

Next, the host control circuit 2100 determines whether all the accessories are at the initial position (step S19163).

When determining that all the accessories are in the initial position (YES in step S19163), the host control circuit 2100 sets permission to accept the accessory request (step S19164). On the other hand, if it is determined that one or more accessory objects are not in the initial position (NO in step S19163), the host control circuit 2100 ends the accessory processing upon reception of the demo command.

On the other hand, in step S19161, if the host control circuit 2100 determines that there is a motor error, that is, an error due to a malfunction of the motor for driving the accessory has been detected (NO in step S19161), the host control circuit 2100 does not accept the accessory request. Permission is set (step S19165).

Next, the host control circuit 2100 stops all motors (step S19166), performs a motor driver reset process (step S19167) after the process in step S19166, and ends the accessory process when receiving the demo command.

In this way, in the accessory processing upon reception of the demo command, the host control circuit 2100 performs an error check of the motor driver for driving the accessory (step S19161), and if an error is detected, the accessory request is processed. reception is prohibited (step S19165), and the motor driver is reset (step S19167). If no error is detected, after performing a release process (step S19162) to release all the excitation of the accessories, the accessory detection sensor group 1002 checks whether all the accessories are in the initial position. It is detected (step S19163), and if all the accessories are in the initial position, the acceptance of the accessory request is permitted.

[10-16-7. Processing of accessories when receiving a change confirmation command]
Next, with reference to FIG. 106, a description will be given of the accessory processing when receiving the special symbol fluctuation confirmation command, which is performed in step S19138 during the processing when receiving the performance command (see FIG. 102). FIG. 106 is a flowchart showing an example of accessory processing when receiving a special symbol change confirmation command. This process is executed by the host control circuit 2100 based on receiving the special symbol fluctuation confirmation command transmitted from the main control circuit 100.

First, the host control circuit 2100 determines whether there is a motor error, that is, whether an error due to a malfunction of the motor for driving the accessory has been detected (step S19171). In this process, the host control circuit 2100, like step S19161 (see FIG. 105), performs various errors (communication controller error, Determine whether a connection error, data error, etc. have occurred.

When the host control circuit 2100 determines that there is no motor error, that is, no error due to a malfunction of the motor for driving the accessory has been detected (the motor is normal) (YES in step S19171), it calculates the number of consecutive errors. The continuous error counter shown in the table is set to "0" (step S19172).

Next, the host control circuit 2100 determines whether all the accessories are at their initial positions (step S19173).

When determining that all the accessories are in the initial position (YES in step S19173), the host control circuit 2100 sets permission to accept the accessory request (step S19174). On the other hand, if it is determined that one or more accessory objects are not in the initial position (NO in step S19173), the host control circuit 2100 ends the accessory processing upon reception of the change confirmation command.

On the other hand, in step S19171, if the host control circuit 2100 determines that there is a motor error, that is, an error due to a malfunction in the motor for driving the accessory has been detected (NO in step S19171), the host control circuit 2100 performs control to stop all motors. (Step S19175).

After the process in step S19175, the host control circuit 2100 performs a motor driver reset process (step S19176), and adds 1 to the number of continuous errors, that is, adds "1" to the value of the continuous error counter (step S19177).

After the processing in step S19177, the host control circuit 2100 determines whether the value of the continuous error counter is equal to or greater than a specified number of times (for example, 10 times) (step S19178).

If the value of the continuous error counter is equal to or greater than the specified number of times (for example, 10 times) (YES in step S19178), the host control circuit 2100 performs a transition setting process to the error motor operation stop state (step S19179). When the state is shifted to the error motor operation stop state, the operations of all accessories are stopped. After the processing in step S19179, the host control circuit 2100 ends the accessory processing upon reception of the change confirmation command.

On the other hand, if the value of the continuous error counter is less than the specified number of times (for example, 10 times) (NO in step S19178), the host control circuit 2100 performs a transition setting process to a state in which acceptance of accessory requests is not permitted (step S19180). .

Note that the number of consecutive errors, that is, the value of the continuous error counter indicates the number of times that the accessory processing is performed continuously when receiving the fluctuation confirmation command, which is determined to be a motor error (NO in step S19171).

In this way, in the accessory processing upon reception of the fluctuation confirmation command, the host control circuit 2100 performs an error check on the motor driver for driving the accessory (step S19171), and if an error is detected, the motor driver A reset process is performed (step S19176), and reception of accessory requests is prohibited (step S19180). Then, when the number of times the accessory processing is performed when receiving the fluctuation confirmation command that is determined to indicate a motor error (NO in step S19161) consecutively reaches a predetermined number (for example, 10 times), the host control circuit 2100 returns the error motor to a stopped state. A transition setting process is performed (step S19179), and the operations of all the accessories are stopped. Further, when it is determined that there is no motor error (YES in step S19171), the host control circuit 2100 uses the accessory detection sensor group 1002 to detect whether or not all the accessories are in the initial position (step S19173), and If the accessory is in the initial position, acceptance of the accessory request is permitted (step S19174). Therefore, if a minor trouble (error) happens to be determined to be a motor error, the service request will be disallowed and the motor error will continue to occur, avoiding a transition to the motor error operation stop state. In such a case, it is possible to suppress the occurrence of a serious error by shifting the motor to an error operation stop state.

Note that the initial position recovery operation transition setting in step S19147 (see FIG. 103) described above corresponds to the first recovery process of the present invention, and the motor driver reset process of step S19176 (see FIG. 106) corresponds to the second recovery process of the present invention. Corresponds to recovery processing. However, the first recovery process may be various operations other than the initial position recovery operation transition setting, such as a recovery operation such as canceling a motor error or moving an accessory from a standby position to a drive position. Similarly, regarding the second recovery process, in addition to the motor driver reset process, the process in the sub-control circuit 200 may be executed again, parameters regarding motor operation may be set again, and the same process as the first recovery process may be performed. Various processes such as control may be performed.

Further, the process of step S19144 described above corresponds to the first counting means of the present invention, and the process of step S19177 described above corresponds to the second counting means of the present invention. Strictly speaking, both the first counting means and the second counting means do not count the number of games played. However, the first restoration process described above can be performed each time a fluctuation start command is received, and the second restoration process described above can be performed each time a fluctuation confirmation command is received. Therefore, as mentioned above, strictly speaking, the first counting means and the second counting means do not count the number of games played, but they actually count the number of games played (variable number of times). can.

Furthermore, if the initial position recovery counter is reset only when the power is turned off, the first counting means does not need to be the number of consecutive games (fluctuating number of times); It can be expressed as "the number of times the game was played without an accessory at the initial position before the game was cut off". In addition, if the initial position recovery counter is reset, for example, when the accessory exists in the initial position, the number of consecutive fluctuations in which the accessory does not exist in the initial position and the first counting means It is possible that the counted number will be the same value. In addition, since the above-mentioned second counting means is the number of consecutive motor errors, it may actually be the same value as the number of consecutive games (number of fluctuations) in which a motor error has occurred. , If the power is turned off between the start of the fluctuation of the special symbol and the end of the fluctuation, and then the power is restored, the counted value by the first counting means and the counted value by the second counting means are reset while the special symbol is fluctuating. be done. Therefore, in such a case, when the sub-control circuit 200 receives the variation confirmation command indicating the end of the variation of the special symbol, the counted value by the first counting means is changed to 0, and the counted value by the second counting means is changed to 1. Therefore, there is a possibility that a difference will occur between the count value by the first counting means and the count value by the second counting means. Thinking in this way, the count counted by the first counting means and the second counting means can be expressed as the number of games played, and the first counting means is simply the number of games that have started to vary the special symbols. It can also be expressed that the second counting means is the same as the number at which the variation of the special symbol has ended. However, the counted value by the first counting means and the counted value by the second counting means are not reset simply by turning the power ON/OFF. ) or other operation means related to settings (setting key 328 or setting switch 332) while operating the power supply (power-on operation or power-off operation), or when the setting confirmation process or/and setting It may also be reset only when a change process is performed.

In addition, regarding the number of games (number of variations), it may be defined that one game (one symbol variation) is performed at the start of the variable display of the special symbols (first special symbol, second special symbol). , it may be defined that one game is played at the end of the variable display of the special symbol (when the result of the special lottery is derived), or it may be defined that one game is played after the variable display of the special symbol starts. The entire game up to the end of the variable display may be defined as one game.

[10-16-8. Processing of accessories when receiving hit commands]
Next, with reference to FIG. 107, a description will be given of the accessory processing when receiving a winning command, which is performed in step S19139 during the processing when receiving an effect command (see FIG. 102). FIG. 107 is a flowchart illustrating an example of accessory processing when a winning command is received. This process is executed by the host control circuit 2100 based on receiving the hit-related command transmitted from the main control circuit 100. The winning commands include, for example, a transition command to a jackpot game state (jackpot game start command), a round game start command, a command between round games (for example, interval time, etc.), a jackpot game state end command, etc.

First, the host control circuit 2100 determines whether all the accessories are at their initial positions (step S19181).

When determining that all accessory objects are in the initial position (YES in step S19181), host control circuit 2100 sets acceptance of accessory requests (step S19182). On the other hand, if it is determined that one or more accessory objects are not in the initial position (NO in step S19181), the host control circuit 2100 ends the accessory processing when winning commands are received.

In this way, in the accessory processing when winning commands are received, the host control circuit 2100 uses the accessory detection sensor group 1002 to detect whether all the accessories are in the initial position (step S19181), and when all the accessories are in the initial position. If it is in the initial position, the reception of the accessory request is permitted (step S19182), and if it is determined that one or more accessory is not in the initial position, the winning system is executed without allowing the reception of the accessory request. The accessory processing is terminated when a command is received.

In addition, throughout the entire processing related to the movements of the accessories in the accessory group, there is a determination in step S1904 (see FIG. 100) whether the number of actions is equal to or greater than a predetermined number of times (for example, 10 times), and step S19145 (see FIG. 100). Determine whether the initial position recovery counter in step S1968 (see FIG. 103) is greater than or equal to a specified number of times (for example, 10 times), and whether the value of the continuous error counter in step S1968 (see FIG. 105) is greater than or equal to the specified number of times (for example, 10 times). Although the prescribed number of times is the same (10 times) in both cases in determining whether or not the process is performed, it goes without saying that the prescribed number of times may be different for each process.

In addition, if the error continues in the accessory initial movement process (see Figure 101), the accessory process when the fluctuation start command is received (see Figure 103), and the accessory processing when the fluctuation confirmation command is received (see Figure 106), the motor Although it has been explained that the occurrence of serious errors can be suppressed by shifting to the error operation stop state, the following errors can be exemplified as serious errors.

For example, a predetermined accessory (including an actuating member constituting the accessory) is provided so that it can be moved from a specific position (for example, an initial position) to a prescribed position (for example, a maximum range of motion). The predetermined accessory is operated by, for example, a motor. When a predetermined accessory exists at a specific position, the predetermined accessory is locked by a locking member (for example, a solenoid). In a normal state (for example, when not energized), the locking member is located at a locking position in which a predetermined accessory is locked, and when the locking member is in a normal state, it is operated to an unlock position to unlock the predetermined accessory. The locking member is energized, for example, by the host control circuit 2100 via the I2C controller 2610 and the motor controller 2700 (see FIG. 10). Then, the host control circuit 2100 energizes the locking member when the predetermined accessory operates from a specific position to a prescribed position, and the host control circuit 2100 energizes the locking member when the predetermined accessory operates from the specific position to the prescribed position. The structure is such that the energization to the locking member is terminated after the energization is started. That is, the locking member is in the lock position when the predetermined accessory returns to a specific position after moving toward a predetermined position, and is configured to be locked when the predetermined accessory is pushed into the specific position. . In such a configuration, if a motor error occurs (for example, an error in which a command to drive the motor cannot be sent to the motor driver due to a communication error), the motor cannot be driven. On the other hand, although the locking member is energized, the predetermined accessory does not start operating toward the predetermined position. Therefore, the lock member continues to be energized (the lock member continues to stay in the unlocked position), and there is a risk that the lock member may be disconnected due to overcurrent. Therefore, when such an error occurs, the error motor operation is not set to stop until the error reaches a specified number of times, but if such an error continues to occur for the specified number of times, the error motor operation is stopped. By setting the transition to , the motor will not go to the motor error operation stop state even if a minor error occurs, but if the error occurs continuously for a specified number of times, the motor will go to the motor error operation stop state. It is possible to suppress the occurrence of serious errors such as the lock member breaking due to overcurrent.

Further, in this embodiment, when a production command is received from the main control circuit 100 (YES in step S1912), a production command reception process (step S1913) is executed in accordance with the received production command, and then, Processing (step S1914) for determining whether or not permission to transfer accessory requests is set is being executed, but the present invention is not limited to this. Between step S1913 and step S1914, a command reception standby operation is in progress. A process for determining whether or not the command is received (hereinafter, this process will be referred to as "command reception standby operation determination process (not shown)") may be executed. The processing method in this case may be any of the following first to third processing methods.

The first processing method is control to shift from the status of command reception standby operation to any one of accessory request acceptance permission, error motor operation stop, initial position recovery operation, and accessory request reception disallowance. This is the processing method by the host control circuit 2100 in this case, and the processing is executed in the following steps.
(A) Determine whether or not the command reception standby operation is in progress (corresponding to the process in step S1911).
(B) If the command reception standby operation is in progress (corresponding to YES in step S1911), determine whether any one of the fluctuation start command, demo command, fluctuation confirmation command, and winning command has been received. do.
(C) When a performance command is received from the main control circuit 100 (corresponding to YES in step S1912), depending on the received command, processing of accessories when receiving a variation start command, processing of accessories when receiving a demo command, and confirmation of variation Executes accessory processing when command is received or accessory processing when winning command is received, and from the command reception waiting status, permission to accept accessory requests, stop error motor operation, initial position recovery operation, and disallow acceptance of accessory requests. After transitioning to one of these statuses, command reception standby operation determination processing (not shown) is executed. In addition, when all the accessories are restored to their initial positions as a result of performing the initial position restoration accessory object operation process, control is performed during command reception standby operation.
(D) If it is determined in the command reception standby operation determination process (not shown) that the command reception standby operation is in progress, by executing the process of step S1912 with all the accessories in their initial positions, other commands can be executed. It is also possible to determine whether the next fluctuation start command has been received, or if it is based on the currently received fluctuation start command, during one fluctuation (with one fluctuation start command), for example. The process of step S1912 may be executed ten times.
(E) If NO is determined in the process of step S1914 (the process to determine whether or not permission to transfer accessory requests is set) executed after the command reception standby operation determination process (not shown), the error motor If the motor is in a stopped state, the motor will be stopped until the power is turned off. In addition, if the accessory is not allowed to be accepted, the accessory will not be activated, but when a fluctuation start command etc. is received, it will be determined whether all the accessories are in the initial position and the accessory request will be accepted. It may also be controlled to be in a permitted state.

The second processing method is a command reception standby operation in which no production-related commands (variation start commands, demo commands, variation confirmation commands, winning-related commands) are received as commands sent from the main control circuit 100. This is a processing method in which the processing is performed in the following steps.
(A) Determine whether or not the command reception standby operation is in progress (corresponding to the process in step S1911).
(B) If the command reception standby operation is in progress (corresponding to YES in step S1911), determine whether any one of the fluctuation start command, demo command, fluctuation confirmation command, and winning command has been received. do.
(C) When a performance command is received from the main control circuit 100 (corresponding to YES in step S1912), the status shifts from the command reception standby status to the command reception non-wait operation status.
(D) In accordance with the received effect-related command, execute the accessory processing when receiving the fluctuation start command, the accessory processing when receiving the demo command, the accessory processing when receiving the fluctuation confirmation command, or the accessory processing when receiving the winning command.
(E) If none of the processing of accessories when receiving the fluctuation start command, processing of the processing of accessories when receiving the demo command, processing of the processing of accessories when receiving the fluctuation confirmation command, and processing of the processing of the processing when winning commands are received, the command is received. Return to waiting status. Command Since the status is shifted to a status other than waiting for reception, NO is determined in the command reception waiting operation determination process (not shown).

The third processing method is based on the premise that a plurality of types of commands are received as production commands, and for example, depending on the type of the received command, processing of accessories when receiving a fluctuation start command, processing of accessories when receiving a demo command, etc. This is a processing method that loops the accessory processing when receiving the fluctuation confirmation command and the accessory processing when receiving the winning command. If you loop the function processing when receiving a fluctuation start command, the function processing when receiving a demo command, the function processing when receiving a fluctuation confirmation command, and the function processing when receiving a winning command, the command reception waiting operation will be resolved. If so, the above-described looping process may be performed when YES is determined in the command reception standby operation determination process (not shown).

[10-17. Hall menu task processing]
Next, processing related to the hall menu task will be explained with reference to FIGS. 108 to 111. The hall menu task is a task that controls the hall menu. The hole menu task is performed by the host control circuit 2100 at a predetermined period, which is every 33 msec in this embodiment.

FIG. 108 is a flowchart illustrating an example of a hole menu task executed by host control circuit 2100.

As shown in FIG. 108, the host control circuit 2100 first determines whether the setting change process or the setting confirmation process is in progress (step S301). Specifically, host control circuit 2100 determines whether or not it has received a setting operation command (setting change start command, setting confirmation start command) transmitted from main CPU 101 when the power is turned on.

When the host control circuit 2100 determines that the setting change process or the setting confirmation process is in progress, that is, that a setting operation command has been received (YES in step S301), the host control circuit 2100 executes the hall menu display process in step S302. This hall menu display process (step S302) is a process in which a hall menu screen, which will be described later, is displayed in the display area of the display device 16 by the display control circuit 2300. Note that the hall menu screen is also displayed in the display area of the display device 16 when the process of step S312 described below is executed, but the hall menu screen displayed in step S302 and the hall menu displayed in step S312 are There are some differences from the screen, which will be discussed later.

The image (screen) displayed in the display area of the display device 16 when the hall menu display process in step S302 is executed will be described with reference to FIGS. 109 to 111. FIG. 109 is a diagram showing an example of when the hall menu screen is displayed in the display area of the display device 16 when the hall menu display process of step S302 is executed. 110 and 111 are diagrams showing examples of hall menu screens displayed in the display area of the display device 16 when the hall menu display process of step S302 is executed.

As shown in FIGS. 109 to 111, when the hall menu display process (step S302) is executed, a hall menu screen is displayed in the display area of the display device 16. As shown in FIGS. 110 and 111, the hall menu screen includes a hall menu item display area 1610 on the left side of the screen, an operation explanation area 1620 at the bottom of the screen at approximately the center in the horizontal direction, and a preview located at approximately the center of the screen. A display area 1630.

Hall menu item display area 1610 displays each item of the hall menu. For convenience, only the time setting, prize ball information, setting history/setting confirmation history, error information history, monitoring history, and warning display setting are shown as hall menu items in FIGS. 109 to 111, but these items In addition, items such as notification settings, power saving settings (power saving mode), maintenance, accessory operation confirmation, liquid crystal brightness setting, liquid crystal confirmation, volume adjustment setting, etc. may be displayed. However, since step S302 is a process during the setting change process or setting confirmation process, it is not possible to end the display of the hall menu screen and return to the game screen. Therefore, among the items on the hall menu, there is no item for ending the hall menu.

In the operation explanation area 1620, images corresponding to the operation button group 66 (see FIG. 3), that is, images corresponding to the main button 662 and the upper, lower, left, and right select buttons 664a to 664d are displayed. Note that, on the hall menu screen, the activated operation buttons and the deactivated operation buttons of the operation button group 66 are displayed so as to be distinguishable. For example, in FIGS. 109 to 111, enabled operation buttons are displayed in white (main button 662 and up/down select buttons 664a, 664b are enabled), and disabled operation buttons are displayed in white. It is displayed in black (the left and right select buttons 664c and 664d are disabled).

By operating the enabled select buttons (upper and lower select buttons 664a and 664b), the operator can select any one of the multiple hall menu items. In FIGS. 109 and 110, the hole menu items surrounded by solid lines are the selected hole menu items. For example, FIG. 109 shows that "time setting" surrounded by a solid line is selected. Further, FIG. 111 shows that "setting change/confirmation history" surrounded by a solid line is selected.

In the pachinko gaming machine 1 of this embodiment, the host control circuit 2100 highlights the selected item. However, the display is not necessarily limited to highlighted display as long as the selected item is easily understood by the operator. Note that the screen on which the time setting item is selected (see FIGS. 109 and 110) is the initial screen of the hall menu screen.

The preview display area 1630 displays a preview screen for the item selected from among the multiple hall menu items. For example, when the "Time setting" item is selected, the time setting screen is previewed (see Figures 109 and 110), and when the "Setting change/confirmation history" item is selected, the time setting screen is displayed as a preview. A preview of the change/confirmation history screen is displayed (see FIG. 111). However, it is preferable that the setting values not be displayed on the preview screen of the setting change/confirmation history screen. Note that no operations can be performed within the above preview screen. For example, when the time setting screen is displayed as a preview, it is not possible to set the time on the previewed time setting screen, and the time setting displayed as a hall menu item is selected and confirmed. You can perform operations to set the time on the time setting screen displayed by .

Furthermore, the host control circuit 2100 displays "Settings are being changed" or "Settings are being changed" in the display area of the display device 16 along with the hall menu screen, for example, in a very small area at the bottom right so as not to interfere with operations on the hall menu screen. "Verifying" will be displayed. At the same time, the host control circuit 2100 controls the speaker 24 to output a sound such as "settings are being changed" or "settings are being confirmed" via the sound/LED control circuit 2200 (see FIG. 10). Further, the host control circuit 2100 executes control to turn on all the LEDs 25 (see FIG. 1, for example) in white via the audio/LED control circuit 2200 (see FIG. 10). In this way, the operator is able to understand whether the settings are being changed or the settings are being confirmed without interfering with the operation on the hall menu screen.

Next, returning to FIG. 108, the host control circuit 2100 executes hall menu processing in step S303. Details of this hall menu processing (step S303) will be described later.

After executing the hall menu process (step S303), the host control circuit 2100 determines whether the setting change process or setting confirmation process has ended, that is, sends a command (initialization command) indicating that the setting change process has ended or It is determined whether a command indicating that the setting confirmation process has ended (power failure recovery command) has been received from the main CPU 101 (step S304). If the host control circuit 2100 has not received either the initialization command or the power failure recovery command (NO in step S304), the host control circuit 2100 continues to execute the hall menu process in step S303.

Further, when transmitting an initialization command, the main CPU 101 also transmits changed setting value information to the host control circuit 2100 at the same timing as the command.

Note that the changed setting value information does not necessarily have to be sent at the same timing as the initialization command, and may be sent at different timings as long as it can be associated with the setting change process.

Furthermore, when transmitting a power failure recovery command, the main CPU 101 does not need to transmit the setting value information to the host control circuit 2100 because the setting value has not been changed; You may also send it to

In step S304, when the setting change process or setting confirmation process is completed, that is, when the host control circuit 2100 receives an initialization command or a power failure recovery command from the main CPU 101 (YES in step S304), the host control circuit 2100 changes the settings stored in the sub-work RAM 2100a. It is determined whether the number of histories is greater than or equal to a predetermined number N (step S305). This is done by appropriately determining whether to overwrite data or write data to an empty area, depending on the number of histories stored in the sub-work RAM 2100a, to record history while preserving as much history data as possible. This is designed to prevent a situation in which recording is not possible when desired. Note that the predetermined number N can be set as appropriate depending on the capacity that can be stored in the sub-work RAM 2100a, and is set to 500, for example, in this embodiment.

If the number of histories of history information stored in the sub-work RAM 2100a is equal to or greater than the predetermined number N (YES in step S305), the process moves to step S306, and an overwriting process of history information (step S306) is executed. In the overwriting process of history information in step S306, among the histories stored in the sub-work RAM 2100a, the history information is overwritten in order from the earliest stored history (oldest history information). Note that the above-mentioned history information also includes history information on the error motor operation stop state, history information on the initial position recovery operation transition setting, and history information on the denial of acceptance of accessory requests. The history information of the error motor operation stop state includes the date and time information when the error motor operation stop state was set (step S19146 in FIG. 103, step S19179 in FIG. 106), and the information on the date and time when the error motor operation stop state was canceled (FIGS. 108 and 114). The information includes the date and time information of step S311). The history information of the initial position recovery operation transition setting is the date and time information when the initial position movement operation (step S1906 in FIG. 100) or the initial position recovery operation transition setting (step S19147 in FIG. 103) was performed. The history information of the denial of permission to accept the accessory request is information such as the date and time when the accessory request was rejected (step S19165 in FIG. 105, step S19180 in FIG. 106). However, strictly speaking, the cancellation of the error motor operation stop state is performed in step S311, which will be described later. However, since the process of step S311 is always performed when the state is controlled to the setting change state or the setting confirmation state, the date and time information when the error motor operation stop state is released is the date and time information when the state is controlled to the setting change state or the setting confirmation state. It is a good idea to have it overwritten.

Further, in the above, the history information of the error motor operation stop state, the history information of the initial position recovery operation transition setting, and the history information of the refusal to accept accessory requests are stored in the sub-work RAM 2100a in step S306 or step S307. However, when "error information history" is selected in the hall menu process of step S302 (YES in step S3008 of FIG. 115), the error information history screen displayed on the display device 16 (see FIG. 116) is reflected. From this point of view, between step S301 and step S302, the history information of the error motor operation stop state, the history information of the initial position recovery operation transition setting, and the history information of the refusal to accept the accessory request are stored in the subwork RAM 2100a. It is preferable to perform a process that causes

In addition, as mentioned above, by making it possible to view the history information of the initial position recovery operation transition setting and the history information of the refusal to accept accessory requests, it is possible to prevent serious errors such as error motor operation stoppage. The gaming machine manager can grasp in advance the possibility of a serious error such as an error motor stopping, and can appropriately manage the pachinko gaming machine 1.

In addition, in the history information overwriting process of step S306, by overwriting the history information already stored in the subwork RAM 2100a with new history information, the history information stored in the subwork RAM 2100a is eventually changed. However, this is not limited to this. For example, when an initialization command or a power failure recovery command is received, if storing new history information in the subwork RAM 2100a may exceed a predetermined upper limit, at least the history information stored in the subwork RAM 2100a The history information may be stored after partially erasing it. In addition, even if no initialization command or power failure recovery command has been received, if there is a risk that the upper limit will be exceeded if more history information is stored in the subwork RAM 2100a, the setting history information stored in the subwork RAM 2100a At least a portion may be erased.

If the number of histories stored in the sub-work RAM 2100a is less than the predetermined number N (NO in step S305), the host control circuit 2100 moves to step S307 and records the history information in the free area of the sub-work RAM 2100a. Recording processing (step S307) is executed. Note that the history information recorded in step S307 also includes history information regarding the error motor operation stop state.

Note that in this specification, the history information overwriting process in step S306 and the history information recording process in step S307 may be collectively referred to as history recording process.

Note that history information refers to time information measured by the RTC 209 when an initialization command or power failure recovery command is received from the main CPU 101, operation type information (information indicating that a setting change process has been executed, or setting confirmation). information indicating that the process has been executed), setting value information, etc. Specifically, when an initialization command is received, information on the time when the initialization command was received, information that the setting change process was executed, and setting value information after the setting change sent from the main CPU 101. Information that associates these with each other is history information. In addition, when a power failure recovery command is received, the time information when the power failure recovery command was received, the information that the setting confirmation process was executed, and the current setting value information sent from the main CPU 101 are correlated. The information added is historical information. When a power failure recovery command is received, it is not essential to include the current setting value information sent from the main CPU 101 in the history information, but in order to execute the setting determination process described above, the history information Preferably, current setting value information is included in the history information. In addition, the browsing history is also included in the above history information, and if the setting change/confirmation history is viewed in the hall menu process (step S303), the browsing history is overwritten as history information in step S306, or Alternatively, in step S307, the browsing history is recorded as history information in the free area of the sub-work RAM 2100a.

Note that under normal conditions, when the power is turned on, the main CPU 101 will immediately send some kind of command (for example, a power failure recovery command, a setting operation command, etc.) after the host control circuit 2100 starts up. However, when the host control circuit 2100 does not receive a command from the main CPU 101 even after a predetermined period of time (for example, 30 seconds) has passed since the start, the host control circuit 2100 determines that there is an abnormality and puts the sub control circuit 200 in a game stop state. Each aspect of the display output, audio output, and LED 25 when the game is stopped on the sub-control circuit 200 side will be described later.

Furthermore, it is preferable that the time information, which is one of the history information stored in the sub-work RAM 2100a, not only store date and time information, but also information up to the hour and minute, or information up to the hour, minute, and second.

After the host control circuit 2100 executes the process of step S306 or step S307, the process moves to step S308.

The host control circuit 2100 determines whether the settings have been changed in step S308, that is, whether or not the initialization command has been received in step S304 (step S308). Note that when the setting operation command received in step S301 is a setting change start command, a power failure recovery command is not received in step S304, and when the setting operation command received in step S301 is a setting confirmation start command. does not receive the initialization command in step S304. In addition, in the process of step S308, since it is sufficient that the host control circuit 2100 can determine that a setting change has been made, for example, instead of determining whether the command received in step S304 is an initialization command, It may be determined that the setting change process has been performed upon receiving the setting value information.

If the host control circuit 2100 determines that a setting change has been made (YES in step S308), it performs a setting change initialization process (step S309), and proceeds to step S310.

In step S310, the host control circuit 2100 determines whether or not the error motor is in a stopped state (step S310). That is, if the processes of step S1905 (see FIG. 100), step S19146 (see FIG. 103), and step S19179 (see FIG. 106) have been performed, it is determined that the error motor operation is stopped.

When the host control circuit 2100 determines that the error motor operation is stopped (YES in step S310), the host control circuit 2100 cancels the error motor operation stop state (step S311). When the error motor operation stop state is released, all accessories can be operated.

On the other hand, if the error motor operation is not in the stopped state (NO in step S310), it is determined whether the accessory request is not permitted (step S322), and if the accessory request is not permitted (YES in step S322). ), the access point request disallowance is canceled, the initial position recovery counter is reset, and the number of consecutive errors is reset (step S323), and the process moves to step S312. If the accessory request is not approved (NO in step S322), the process moves to step S312 without performing the process of step S322.

Although the cancellation of the error motor operation stop state (step S311) is performed regardless of whether the setting change process or the setting confirmation process is performed, the present invention is not limited to this. It may be canceled when the change process is performed, but not canceled when the setting confirmation process is performed.

Further, as described above, when the setting change process is performed, the backup clear process is also performed, but the cancellation of the error motor operation stop state (step S311) is executed when the setting change process is performed, while the It is preferable to prevent the backup clearing process from being executed when a backup clearing process that does not involve a change process (for example, the backup clearing process executed when the determination is NO in step S22 in FIG. 33) is performed. Since performances using a group of accessories are an important element in increasing game interest, if a game is played on a gaming machine in which the accessories cannot operate normally, the interest will inevitably decrease. For this reason, important decisions such as whether or not to operate a gaming machine whose accessory has become inoperable should be made by authorized personnel at the hall, and to prevent unauthorized persons from canceling the error motor operation stop state. I have to. However, when a serious error such as an error motor operation stop state has not been reached, such as canceling the disallowance of accessory requests, resetting the initial position recovery counter, and resetting the number of consecutive errors (step S323), it is not convenient. From this point of view, it is preferable that the process be executed not only when a setting change process is performed, but also when a backup clear process that does not involve a setting change process is performed.

The host control circuit 2100 executes hall menu redisplay processing in step S312. At this time, the hole menu screen that is redisplayed is different from the hole menu screen that is displayed while changing or confirming the settings (the hole menu screen that is displayed in step S302), and the hole menu screen that is redisplayed is different from the hole menu screen that is displayed while changing the settings or confirming the settings. This is a screen that is displayed when execution is possible (or during the game return process in step S30), and for example, as shown in FIG. 112, one of the items in the hole menu is an item for ending the hole menu. be done. Note that FIG. 112 is a diagram showing an example of the hall menu screen displayed in the display area of the display device 16 when the hall menu redisplay process of step S312 is executed.

That is, on the hall menu screen displayed during setting change or setting confirmation (the hall menu screen displayed in step S302), although the operator cannot end the display of the hall menu screen at his/her will, the setting change process The hall menu screen that is redisplayed after the end of the hall menu screen (the hall menu screen displayed in step S312) is configured so that the operator can end the display of the hall menu screen at his or her will. Note that the hall menu screen displayed in step S302 (for example, see FIG. 110) and the hall menu screen displayed in step S312 (see FIG. 112) can be operated by selecting and determining one of each item. These functional aspects (for example, the ability to view the setting change/confirmation history screen) are common.

Further, when the host control circuit 2100 determines that a setting change has been made in step S308 (YES in step S308), in the hall menu redisplay process of step S312, the host control circuit 2100 displays an image in the display area of the display device 16 along with the hall menu screen. Then, in order not to interfere with the operation on the hall menu screen, for example, the text "Settings have been changed" is displayed in a very small area at the bottom right. Similarly, when the screen for the selected hole menu item (for example, the settings change/confirmation history screen) is displayed, a message such as "Settings have changed" is displayed in the very small area at the bottom right so as not to interfere with operations on the screen. ” will be displayed. At the same time, the host control circuit 2100 controls the audio/LED control circuit 2200 (see FIG. 10) to output a sound such as "Settings have been changed. RAM has been initialized" from the speaker 24. do. This allows the operator to know that the settings have been changed (and that the backup clear process has been executed) without interfering with operations on the hall menu screen or the screen of the selected hall menu item. becomes. Furthermore, the host control circuit 2100 executes control to cause all of the LEDs 25 (see FIG. 1, for example) to light up in red via the audio/LED control circuit 2200 (see FIG. 10).

On the other hand, when it is determined in step S308 that the setting confirmation has been performed (NO in step S308), that is, when the command received in step S304 is a power failure recovery command indicating the end of the setting confirmation process, the host control circuit 2100 The game screen return process of step S317 is executed without executing the processes of steps S309 to S316. Therefore, when the setting confirmation process ends, the hall menu redisplay process (step S312) is not executed. Furthermore, no characters are displayed in the display area of the display device 16 to indicate that the setting confirmation has been completed. Furthermore, no sound is output indicating that the setting confirmation has been completed. However, the host control circuit 2100 executes control to cause all of the LEDs 25 (for example, see FIG. 1) to turn on in red via the audio/LED control circuit 2200 (see FIG. 10).

By the way, when the process of step S302 is executed and when the process of step S312 is executed, the hall menu screen is displayed in the display area of the display device 16, but the process of step S302 is not executed. At this time, the game cannot be played because the settings are being checked or changed, whereas the game can be played when the process of step S312 is executed. However, as described above, the manner in which characters are displayed in the display area of the display device 16 differs between when the process of step S302 is executed and when the process of step S312 is executed (not displayed when setting confirmation is completed). , the manner of sound output from the speaker 24 and the manner of light emission from the LED 25 are significantly different. Therefore, even if the hall menu screen or the selected hall menu item screen is displayed in the display area of the display device 16, operations on the hall menu screen or the selected hall menu item screen (for example, changing the hall menu item screen) To easily understand from the appearance whether the pachinko game machine 1 is in a state in which it is possible to execute a game or in a state in which it is not possible to execute a game without interfering with operations for selecting, page updating, etc. It is now possible.

After executing the process in step S312, the host control circuit 2100 moves to step S313 and executes the hall menu process. The hall menu process in step S313 is basically the same process as step S303, but the process when YES in step S3072 in FIG. 118, which will be described later, is different, which will be described later.

In step S314, host control circuit 2100 determines whether "end hall menu" has been selected on the redisplayed hall menu screen. If it is determined that "end hall menu" has been selected (YES in step S314), the host control circuit 2100 performs a game screen return display process (step S317). In this game screen return display process, the host control circuit 2100 displays, in the display area of the display device 16, an effect image to be displayed when playing a game, and a display when the pachinko game machine 1 (for example, the firing handle 32) is operated for a predetermined period of time. Displays the initial image that would be displayed if the Then, after executing the game screen return process in step S317, the host control circuit 2100 moves to step S318.

On the other hand, if it is determined in step S314 that "end hall menu" is not selected (NO in step S314), the host control circuit 2100 determines whether a predetermined time (for example, 30 seconds) has not elapsed ( Step S315). Although not shown in FIG. 108, when the setting change process or setting confirmation process is completed (YES in step S304), when the hall menu redisplay process (step S312) is executed, the hall menu process (step S313) In step S315, time measurement is started based on some operation performed by the operator, such as when any hall menu item is selected, and the process in step S315 determines whether the measured time has elapsed for a predetermined period of time. If the operator does not perform any operation for a predetermined period of time or longer, the host control circuit 2100 determines YES in step S315.

When the host control circuit 2100 determines that a predetermined period of time (for example, 30 seconds) has elapsed without any operation (YES in step S315), it ends the display of the re-displayed hall menu screen and displays the game screen return in step S317. Execute processing.

Further, if a predetermined period of time (for example, 30 seconds) has not elapsed without any operation (NO in step S315), the host control circuit 2100 determines whether a command to generate a production control object has been received (step S316). The commands that generate the production control object are commands that can be received when the game is executed, and include, for example, a symbol fluctuation start command, a symbol fluctuation confirmation (fluctuation stop) command, a jackpot game execution start command, and a jackpot game execution command. These commands include a command indicating the number of rounds in a game, a round interval command in a jackpot game, a jackpot game end command, an initialization command, a power failure recovery command, and the like. When the host control circuit 2100 determines in step S316 that one of the commands for generating these performance control objects has been received, it ends the display of the re-displayed hall menu screen and returns to the game screen in step S317. Execute return display processing. As a result, a game screen that matches the progress of the game by the main CPU 101 is displayed in the display area of the display device 16. For example, even though the game by the main CPU 101 is in progress, an image unrelated to the game is displayed. It is possible to prevent the progress of the game from being hindered, such as when the game is played. On the other hand, if it is determined that the command to generate the production control object has not been received (NO in step S316), the process returns to step S313.

After executing the game screen return display process (step S317), the host control circuit 2100 moves to step S318 and executes the hall menu display prohibition process. This hall menu display prohibition process is a process that prohibits the hall menu screen from being displayed again in the display area of the display device 16. That is, when the hall menu display prohibition process (step S318) is executed, the hall menu screen will not be displayed even if the setting key 328 is turned ON again, and the setting change process or setting confirmation process is executed by turning the power OFF. The hall menu display process (step S302) cannot be executed unless the hall menu display process (step S302) is performed.

In this way, the hall menu screen is basically a screen that is displayed in the display area of the display device 16 during execution of the setting change process or the setting confirmation process. However, when the setting change process is executed, even if the setting change process ends, the operator must not select the "end hall menu" item on the hall menu screen (NO in step S314), or Under certain conditions, such as the operation time not passing for a predetermined time (NO in step S315) and the command to generate the production control object not being received (NO in step S316), the processes of steps S313 to S316 are repeatedly executed. The hall menu screen will continue to be displayed. Therefore, if the operator performs any operation on the hall menu screen or the screen of the selected hall menu item (for example, the setting change/confirmation history screen), the display of the hall menu screen or the screen of the selected hall menu item will change. It will continue to be displayed without ending. As a result, even if the setting change process or the setting confirmation process is completed, the operator can have some time to operate the home menu screen or the screen of the selected hall menu item. Moreover, even if the operator forgets to select "End Hall Menu", if there is no operation for a predetermined period of time (for example, 30 seconds), the display of the Hall Menu screen or the screen of the selected Hall Menu item will end and the game will end. Since the screen return process (step S317) is executed, unauthorized persons (for example, hall staff who are not gaming machine managers or players) can easily view confidential information such as setting change history, setting confirmation history, viewing history, etc. This makes it possible to ensure security.

In addition, in this embodiment, when it is determined in step S316 that a command to generate a performance control object has been received, the game screen return process (step S317) and the hall menu display prohibition process (step S318) are performed. The game screen is not necessarily limited to this, but may be displayed on the game screen based on, for example, receiving a specific command that becomes receivable once execution of the game has started, such as receiving a command indicating that the firing handle 32 has been operated. A return process (step S317) and a hall menu display prohibition process (step S318) may be performed.

Here, the manner of notification when an error occurs, including backup clear processing that does not involve setting change processing, will be described with reference to FIG. 113. FIG. 113 is an example of a screen in which error details are displayed in the display area of the display device 16, including (a) a screen indicating that backup clear processing without setting change processing has been executed, and (b) starting port abnormality. (c) A screen indicating that a winning error has occurred and that backup clear processing without setting change processing has been executed; (c) Both the backup clear processing without setting change processing has been executed and the abnormal starting opening winning error. FIG. 4 is a diagram showing a screen after a notification period (for example, 30 seconds) indicating that backup clear processing has been executed in a state in which a backup clear process has occurred.

As shown in FIG. 113, when multiple errors occur, the host control circuit 2100 displays all the error details that have occurred in the display area of the display device 16, and also controls the audio/LED control in the order of the errors with the highest priority. Audio is output from the speaker 24 via the circuit 2200 (see FIG. 10), and light emission control of the LED 25 is executed via the audio/LED control circuit 2200 (see FIG. 10).

When the backup clear process that does not involve setting change process is executed, if no other error has occurred, the host control circuit 2100 clears the display area of the display device 16 as shown in FIG. 113(a). It controls so that characters such as "RAM has been cleared" are displayed in the display, and also controls so that a sound such as "RAM has been cleared" is output from the speaker 24, and furthermore, the sound/LED control circuit 2200 (See FIG. 10) to control the LED 25 (for example, see FIG. 1) to fully light up in red. Note that the text "RAM has been cleared" is displayed using a larger area than the above-mentioned extremely small area (see FIG. 112) in which the text "Settings have been changed" is displayed.

That is, in this embodiment, when performing the setting change process, the backup clear process is always executed (see FIG. 34), and in the hall menu redisplay process of step S312, which is executed after the setting change process is completed, as described above, " Although the message "Settings have been changed" is displayed in the display area of the display device 16, the message "Settings have been changed. RAM has been initialized" is not displayed indicating that the backup clear process has been executed. The only sound output from the speaker 24 is, ``I'm sorry.''. On the other hand, when the backup clear process is executed without the setting change process, the host control circuit 2100 uses an area larger than the above-mentioned extremely small area (see FIG. 112) within the display area of the display device 16. control so that characters such as ``RAM has been cleared'' are displayed, and a voice such as ``RAM has been cleared'' is output from the speaker 24 (see FIG. 113(a)). Here, the main purpose of backup clear processing that involves setting change processing is to change the setting value (not backup clear processing), whereas the main purpose of backup clear processing that does not involve setting change processing is backup clear processing. It is thought that. Therefore, when the backup clear process accompanied by the setting change process is executed, the execution of the backup clear process is discreetly announced in a manner that does not interfere with the operation of the hall menu screen that is redisplayed. On the other hand, when backup clear processing that does not involve setting change processing is executed, the fact that backup clear processing has been executed is notified in a more conspicuous manner than when backup clear processing that involves setting change processing is executed. This makes it possible to prevent the backup clearing process from being executed illegally.

In addition, after the backup clear process is executed, if another error occurs, for example, a starting port abnormal winning error, as shown in FIG. 113(b), it is assumed that a starting port abnormal winning error has occurred. , and that the backup clear process has been executed are displayed as characters in the display area of the display device 16. At this time, the fact that the backup clear process has been executed has a higher priority than the abnormal start-up winning error, so the text indicating that the backup clear process has been executed is displayed at the top regardless of the order in which it occurred. . Further, a sound notifying that the backup clearing process with a high priority has been executed is outputted from the speaker 24, and the LED 25 emits light in a manner indicating that the backup clearing process has been executed.

In addition, when the notification period (for example, 30 seconds) that the backup clear process has been executed has elapsed in a state where both the backup clear process and the starting port abnormal prize winning error have occurred, the backup clear process The characters indicating that the error has been executed are deleted from the display area of the display device 16, and if no other error occurs, only the characters indicating the abnormal starting opening winning error are displayed in the display area of the display device 16. In addition, the sound output from the speaker 24 changes from the sound notifying that the backup clear process has been executed to the sound notifying that a starting port abnormal prize winning error has occurred, and the lighting mode of the LED 25 also changes. The mode changes from the mode indicating that the process has been executed to the mode indicating that a starting port abnormal prize winning error has occurred. In this way, it is possible to easily understand the details of the error that has occurred.

Note that in the above, when it is determined that the setting change process or the setting confirmation process is in progress, that is, when it is determined that a setting operation command has been received (YES in step S301), the hall menu display process (step S302) is executed. Although this has been described, it is preferable to also execute the backup clear process that does not involve the setting change process. Backup clear processing without setting change processing is performed when both the backup clear switch 330 is pressed and the power switch 35 is turned on without turning on the setting key 328 while the power is not turned on. It is executed (see FIG. 33). When the backup clear process is executed, the main CPU 101 sends an initialization command to the host control circuit 2100, so the host control circuit 2100, which has received the initialization command without receiving the setting operation command, performs the setting change process. It can be determined that the backup clear process has been executed, and the hall menu display process (step S302) and the hall menu process (step S303) can be executed.

[10-17-1. Other examples of hole menu tasks]
By the way, the main CPU 101 of the pachinko game machine of this embodiment determines whether the work area of the main RAM 103 is normal or not in the game permission process (step S17) of the power-on process (see FIG. 31). (See step S1730 in FIG. 32). For example, when the set value data is not within the specified range (in the present embodiment, within the range of "0" to "5"), it is determined that the work area of the main RAM 103 is not normal ( If NO in step S1730), the game permission flag is turned OFF (see step S1760), so that the game cannot be played. However, for example, if the main control board 30 is illegally replaced, there is a high possibility that the RAM 103 work area check process (step S1720) will not be executed. Further, in the case where the set value is changed due to input of an unauthorized signal, there is a possibility that the set value data is within the range of "0" to "5". Therefore, similar to the above-mentioned setting determination process that is executed during the execution of the game, there are cases where the work area check process is not executed in step S1720, or the setting value is Setting determination processing (step The processing in step S319 and step S320) may also be executed. FIG. 114 shows the hole menu task in this case. FIG. 114 is another example of the hall menu task executed by the host control circuit 2100, and is a flowchart when the host control circuit 2100 executes a setting determination process for determining the suitability of setting value information. Other examples of hole menu tasks will be described below. However, a description of processes common to those in FIG. 108 will be omitted, and only the setting determination process will be described.

First, the main CPU 101 transmits the setting value information stored in the main RAM 103 as the current setting value used to proceed with the game, even when transmitting a power failure recovery command indicating that the setting confirmation process has ended. It is transmitted to the host control circuit 2100.

On the other hand, the host control circuit 2100 that has received the power failure recovery command determines that the settings have not been changed (NO in step S308), and moves to step S319. In this step S319, the host control circuit 2100 executes a setting value check process. This setting value checking process (step S319) includes current setting value information (setting value information sent from the main CPU 101 before the power outage and stored in the sub-work RAM 2100a) and setting value information sent from the main CPU 101. This is a process for confirming (setting value information transmitted from the main CPU 101 after a power outage). Note that when it is determined in step S308 that the settings have not been changed (NO in step S308), the processes in steps S309 to S316 are not executed.

After checking the current setting value information and the setting value information transmitted from the main CPU 101 in the setting value checking process (step S319), the host control circuit 2100 performs a setting value judgment process, that is, whether the setting value is appropriate or not. is determined (step S320). At this time, if the current setting value information and the setting value information transmitted from the main CPU 101 match, it is determined that the setting value information is appropriate (YES in step S320), and the process moves to step S317. The processing after step S317 is as described above.

On the other hand, if the current setting value information and the setting value information transmitted from the main CPU 101 do not match, it is determined that the setting value information is inappropriate (NO in step S320), and the process moves to step S321, where the host control circuit 2100 sets the setting value Execute abnormality processing.

The above set value abnormality process is a process of displaying an image in the display area of the display device 16 to notify that the set value is abnormal. In this setting value abnormality processing (step S321), instead of or in addition to the process of displaying an image notifying that the setting value is abnormal, a sound is output to notify that the setting value is abnormal. Processing may also be executed.

In this way, when the command sent from the main CPU 101 is a power failure recovery command indicating the end of the setting confirmation process, the host control circuit 2100 executes the setting determination process (the process of step S319 and step S320), When it is determined that the setting value is not appropriate (NO in step S320), by executing the setting value abnormality process (step S321), it becomes possible to notify the gaming machine manager that the setting value is inappropriate.

Note that although the above-mentioned setting determination process (processing in steps S319 and S320) is executed when the setting confirmation process is completed, the setting change process is executed without executing either the setting change process or the setting confirmation process. If a backup process is executed that does not involve a backup operation (pressing the backup clear switch 330 and turning on the power switch 35 without turning on the setting key 328 when the power is not turned on), or simply turning on the power It is also preferable to carry out this procedure even when only inputting . Unless a setting change process is executed, the host control circuit 2100 changes the setting value information by determining whether the setting value information received before the power outage matches the setting value information received after the power outage. This is because it is possible to determine the suitability of the

[10-18. Hall menu processing]
Next, with reference to FIG. 115, the hole menu processing (step S303) in the hole menu task (see FIGS. 108 and 114) will be described. FIG. 115 is a flowchart illustrating an example of hall menu processing executed by host control circuit 2100.

First, the host control circuit 2100 selects a hall menu item to check various information/settings or change various settings based on the operator's operation of the select button 664 and/or main button 662. Hall menu selection processing is performed (step S3001). In the hole menu selection process shown in FIG. 115, the hole menu items include time setting, prize ball information, setting history/setting confirmation history, error information history, monitoring history, warning display setting, notification setting, power saving mode, maintenance, Although the case of accessory operation confirmation, liquid crystal brightness setting, and volume adjustment setting will be described, the hall menu items are not limited to these as described above.

Next, the host control circuit 2100 determines whether the hall menu selected in step S3001 is "time setting" (step S3002). If it is determined in step S3002 that the selected hall menu is "time setting" (YES in step S3002), the host control circuit 2100 performs time setting processing (step S3003). In this time setting process, the host control circuit 2100 displays a time setting screen (not shown) in the display area of the display device 16, allowing the operator to check and change the set time. .

If the host control circuit 2100 determines that the hole menu selected in step S3001 is not "time setting" (NO in step S3002), the host control circuit 2100 determines whether the hole menu selected in step S3001 is "prize ball information". It is determined (step S3004). If the host control circuit 2100 determines that the selected hole menu is "prize ball information" (YES in step S3004), it performs prize ball information processing (step S3005). In this prize ball information processing, the host control circuit 2100 displays a prize ball information screen (not shown) in the display area of the display device 16, and allows the operator to confirm the prize ball information. Prize ball information includes, for example, information on the number of prize balls paid out today, information on the difference between the number of prize balls paid out today and the number of game balls fired, and the number of prize balls paid out each day in the past few days. information, difference information (daily) between the number of prize balls paid out and the number of prize balls fired in the past few days.

If the host control circuit 2100 determines that the hole menu selected in step S3001 is not "prize ball information" (NO in step S3004), the host control circuit 2100 determines whether the hole menu selected in step S3001 is "setting change/confirmation history". (Step S3006). If the host control circuit 2100 determines that the selected hall menu is "setting change/confirmation history" (YES in step S3006), it performs setting change/confirmation history processing (step S3007). In this setting change/confirmation history process, the host control circuit 2100 displays a setting change/confirmation history screen to be described later (for example, see FIG. 119 to be described later) in the display area of the display device 16, so that the operator can change the settings. It is possible to check confirmation history, change history, and viewing history.

Further, when the host control circuit 2100 detects that the main button 662 is operated while the select button 664 is operated and "setting change/confirmation history" is selected, the host control circuit 2100 displays a message in the display area of the display device 16. A settings change/confirmation history screen (for example, see Figure 119 described later) is displayed, and the operator can display the settings (setting values) change history, settings (setting values) confirmation history, viewing history, and confirmed settings (setting values). ) and the changed settings (setting values). Note that details of the setting change/confirmation history process will be described later with reference to FIGS. 117 and 118.

If the host control circuit 2100 determines that the hall menu selected in step S3001 is not "setting change/confirmation history" (NO in step S3006), the host control circuit 2100 determines whether the hall menu selected in step S3001 is "error information history". (Step S3008). If the host control circuit 2100 determines that the selected hole menu is "error information history" (YES in step S3008), it performs error information history processing (step S3009). In this error information history process, the host control circuit 2100 displays an error information history screen (for example, see FIG. 116) in the display area of the display device 16, and allows the operator to check and change the error information history. shall be.

The error history displayed in the error information history process is, for example, information stored in the sub-work RAM 2100a as an error history when the host control circuit 2100 determines that backup is defective. As described above, the host control circuit 2100 may determine that the backup is defective when it receives an abnormal command from the main CPU 101, or it may determine that the backup is defective when the host control circuit 2100 determines that the backup is defective. This may also be the case when a normal command cannot be received from the main CPU 101 for a predetermined period of time (for example, 30 seconds) after power supply to the main CPU 101 (see 9) is started.

As shown in FIG. 116, an error information history table is arranged approximately in the center of the error information history screen. The error information history table has an error content column in which the error code is displayed, an occurrence date and time column in which the date and time when the error code was recorded is displayed, and a release date and time column in which the date and time when the error was canceled is displayed. For example, "MOTOR ERR" is shown in the No. 2 error content on the error information history screen in FIG. This shows the date and time information when the process (see FIG. 106) was performed. Although not shown in FIG. 116, the date and time information when the cancellation process (step S311) of the error motor operation stop state was performed (strictly speaking, the date and time information when the setting change state or setting confirmation state was controlled) is the release date and time. It is shown in the column. Furthermore, the operation method for the error information history screen is displayed at the lower left of the error information history screen. For example, it is shown that the cursor (not shown) can be moved vertically and horizontally by operating the select buttons 664a to 664d (see FIG. 3), and that it can be determined by operating the main button 662. It has been shown that it is possible.

If the host control circuit 2100 determines that the hall menu selected in step S3001 is not "error information history" (NO in step S3008), the host control circuit 2100 determines whether the hall menu selected in step S3001 is "monitoring history". (Step S3010). If it is determined that the selected hall menu is "monitoring history" (YES in step S3010), host control circuit 2100 performs monitoring history processing (step S3011). In this monitoring history processing, the host control circuit 2100 displays a monitoring history processing screen (not shown) in the display area of the display device 16, allowing the operator to check the monitoring history.

If the host control circuit 2100 determines that the hall menu selected in step S3001 is not "monitoring history" (NO in step S3010), the host control circuit 2100 determines whether the hall menu selected in step S3001 is "warning display setting". (Step S3012). If it is determined that the selected hall menu is "warning display setting" (YES in step S3012), the host control circuit 2100 performs warning display setting processing (step S3013). In this warning display setting process, the host control circuit 2100 displays a warning display setting screen (not shown) in the display area of the display device 16, and allows the operator to confirm and change the warning display settings.

If the host control circuit 2100 determines that the hall menu selected in step S3001 is not "warning display setting" (NO in step S3012), the host control circuit 2100 determines whether the hall menu selected in step S3001 is "notification setting". (Step S3014). If it is determined that the selected hall menu is "notification setting" (YES in step S3014), host control circuit 2100 performs notification setting processing (step S3015). In this notification setting process, host control circuit 2100 displays a notification setting screen (not shown) in the display area of display device 16, and allows the operator to confirm and change notification settings.

If the host control circuit 2100 determines that the hall menu selected in step S3001 is not "notification setting" (NO in step S3014), the host control circuit 2100 determines whether the hall menu selected in step S3001 is in "power saving mode". (Step S3016). If it is determined that the selected hole menu is in "power saving mode" (YES in step S3016), host control circuit 2100 performs power saving mode processing (step S3017). In this power saving mode processing, the host control circuit 2100 displays a power saving mode screen (not shown) in the display area of the display device 16, and allows the operator to check and change the power saving mode settings. do.

If the host control circuit 2100 determines that the hall menu selected in step S3001 is not "power saving mode" (NO in step S3016), it determines whether the hall menu selected in step S3001 is "maintenance". (Step S3018). If it is determined that the selected hole menu is "maintenance" (YES in step S3018), host control circuit 2100 performs maintenance processing (step S3019). Details of the maintenance process will be described later with reference to FIG. 130.

If the host control circuit 2100 determines that the hall menu selected in step S3001 is not "maintenance" (NO in step S3018), the host control circuit 2100 determines whether the hall menu selected in step S3001 is "accessory operation confirmation". (Step S3020). If it is determined that the selected hole menu is "accessory object operation confirmation" (YES in step S3020), the host control circuit 2100 performs accessory object operation confirmation processing (step S3021). In this accessory operation confirmation process, the host control circuit 2100 displays an accessory operation confirmation screen (not shown) in the display area of the display device 16, allowing the operator to confirm the operation of the accessory. .

If the host control circuit 2100 determines that the hall menu selected in step S3001 is not "Accessory object operation confirmation" (NO in step S3020), the host control circuit 2100 determines whether the hall menu selected in step S3001 is "LCD brightness setting". (Step S3022). If it is determined that the selected hall menu is "liquid crystal brightness setting" (YES in step S3022), host control circuit 2100 performs liquid crystal brightness setting processing (step S3023). In this liquid crystal brightness setting process, the host control circuit 2100 displays a liquid crystal brightness setting screen (not shown) in the display area of the display device 16, and allows the operator to check and change the brightness setting of the display device 16. shall be.

If the host control circuit 2100 determines that the hall menu selected in step S3001 is not "LCD brightness setting" (NO in step S3022), the host control circuit 2100 determines whether the hall menu selected in step S3001 is "volume adjustment setting". It is determined (step S3024). If it is determined that the selected hall menu is "volume adjustment setting" (YES in step S3024), host control circuit 2100 performs volume adjustment setting processing (step S3025). In this volume adjustment setting process, the host control circuit 2100 displays a volume adjustment setting screen (not shown) on the display device 16, and allows the operator to confirm and change the volume setting of the sound output from the speaker 24. possible.

After the processing in step S3003, step S3005, step S3007, step S3009, step S3011, step S3013, step S3015, step S3017, step S3019, step S3021, step S3023, step S3025 and the hall menu selected in step S3001 is Setting" (NO in step S3024), the host control circuit 2100 ends the hall menu process and returns the process to step S304 of the hall menu task (see FIG. 108).

[10-19. Conditions of various devices when changing settings/confirming settings, etc.]
The aspects of various devices (display device 16, speaker 24, LED 25, main RAM 103, performance display monitor 334) when changing or confirming settings are as described above, but are summarized below for ease of understanding. do.

First, the time of changing settings will be explained in the order in which various operations are executed. In the power OFF state before the power is turned on, the power switch 35 is OFF. At this time, the display device 16, speaker 24, LED 25, and performance display monitor 334 are turned off. In order to start the setting change process, it is necessary to turn on the setting key 328 before turning on the power, but even if the setting key 328 is turned on, the display device 16, speaker 24 , the LED 25 and the performance display monitor 334 remain off.

Next, when both the backup clear switch 330 and the power switch 35 are turned on while the setting key 328 is turned on, the main CPU 101 controls the setting change state and sends a setting operation command (setting change start command). . The host control circuit 2100 determines that the setting change state has been controlled (the setting change state has started) based on receiving the setting operation command (setting change start command) transmitted from the main CPU 101. When the setting is changed, the game cannot be played, and the host control circuit 2100 uses the display control circuit 2300 to display the hall menu screen in the display area of the display device 16 and displays a message saying "Settings are being changed". Display characters. At the same time, the host control circuit 2100 causes the audio/LED control circuit 2200 to output a voice such as "Settings are being changed" from the speaker 24, and causes the audio/LED control circuit 2200 to turn on all of the LEDs 25 in white. Further, the main CPU 101 transmits a setting change security signal to the hall computer 700 via the external terminal board 323. Furthermore, the main CPU 101 executes a backup clear process in which the work area of the main RAM 103 is cleared. Note that the performance display monitor 334 displays set values by the main CPU 101.

Next, when the setting switch 332 is operated in the setting change state, the setting value is updated. However, at this stage, the set values have not yet been determined. The updated setting values are displayed on the performance display monitor 334. Further, in the display area of the display device 16, a hall menu screen is displayed, and the words "Settings are being changed" are continuously displayed. At the same time, a voice saying "Settings are being changed" is continuously output from the speaker 24, and the LED 25 continues to be fully lit in white. In this embodiment, even if the set value is updated, it is only stored in the register and not stored in the main RAM 103 until it is finalized. However, even if the set value is not finalized, the updated set value It may also be stored in the work area of the main RAM 103. Further, in this embodiment, the set value is updated by operating the setting switch 332, but the set value is updated by operating other operating means (for example, the backup clear switch 330). You can do it like this.

Next, when the setting key 328 is turned off, the main CPU 101 ends the setting change state and sends an initialization command. The host control circuit 2100 determines that the setting change state has ended based on receiving the initialization command sent from the main CPU 101. When the setting change state is completed, the game becomes ready to be played. However, even if the setting change state ends, the host control circuit 2100 will not display the display for at least a predetermined period (for example, 30 seconds) unless the execution of the game is started (for example, unless a command to generate a performance control object is received). The control circuit 2300 displays the hall menu screen or the screen of the selected hall menu item (for example, a setting change/confirmation history screen) in the display area of the display device 16, and also displays text such as "Settings have been changed." Displayed on the display area of the display device 16. However, it is not displayed that the backup clear process has been executed. At the same time, the host control circuit 2100 outputs a voice message such as "Settings have been changed. RAM has been initialized" from the speaker 24 using the voice/LED control circuit 2200 for at least a predetermined period (for example, 30 seconds). At the same time, the audio/LED control circuit 2200 lights up all the LEDs 25 in red. Such display in the display area of the display device 16, output from the speaker 24, and full lighting of the LED 25 in red continue as long as some operation is performed on the hall menu screen or the screen of the selected hall menu item, The no-operation period ends when a predetermined period of time continues or when the game starts. Note that the base value is displayed on the performance display monitor 334 by the main CPU 101. By the way, in the above, it is not displayed that the backup clearing process has been executed, but the host control circuit 2100 displays the message ``RAM has been cleared'' in addition to the message ``Settings have been changed.'' may also be written.

In this way, even if the settings change state is finished, the text display saying "Settings have been changed", the voice output saying "Settings have been changed. RAM has been initialized", and the LED 25 all red. By keeping the lights on for at least a predetermined period of time (for example, 30 seconds), it is possible to prevent unauthorized third parties from perpetrating unauthorized actions such as viewing the settings change/confirmation history screen, etc. Become. Further, since the light emitting manner of the LED 25 is clearly different between during the setting change state and when the setting change state is finished, it is possible to easily understand from the appearance whether or not the game is in a state where the game can be executed.

The above are the aspects of various devices (display device 16, speaker 24, LED 25, main RAM 103, performance display monitor 334) when changing settings.

Next, the time of setting confirmation will be explained in the order in which various operations are executed. In the power OFF state before the power is turned on, the power switch 35 is OFF. At this time, the display device 16, speaker 24, LED 25, and performance display monitor 334 are turned off. In order to start the setting confirmation process, it is necessary to turn on the setting key 328 before turning on the power, but even if the setting key 328 is turned on, the display device 16, speaker 24 , the LED 25 and the performance display monitor 334 remain off.

Next, when the power switch 35 is turned on while the setting key 328 is turned on (the backup clear switch 330 is not turned on), the main CPU 101 controls the setting confirmation state and issues a setting operation command (setting confirmation start command). Send. The host control circuit 2100 determines that the setting confirmation state has been controlled (the setting confirmation state has started) based on receiving the setting operation command (setting confirmation start command) transmitted from the main CPU 101. When controlled to the settings confirmation state, the game cannot be played, and the host control circuit 2100 uses the display control circuit 2300 to display the hall menu screen in the display area of the display device 16, and displays the message "Settings confirmation in progress". Display characters such as At the same time, the host control circuit 2100 causes the audio/LED control circuit 2200 to output a voice saying "Settings are being confirmed" from the speaker 24, and also causes the audio/LED control circuit 2200 to turn on all of the LEDs 25 in white. Main CPU 101 also transmits a setting confirmation security signal to hall computer 700 via external terminal board 323. Note that the performance display monitor 334 displays set values by the main CPU 101.

Next, when the setting key 328 is turned off, the main CPU 101 ends the setting confirmation state and sends a power failure recovery command. The host control circuit 2100 determines that the setting confirmation state has ended based on receiving the power failure recovery command sent from the main CPU 101. When the setting confirmation state is completed, the game becomes ready to be played. Further, the host control circuit 2100 executes a game screen return display process (step S318) based on receiving the power failure recovery command transmitted from the main CPU 101. At this time, the host control circuit 2100 does not display characters indicating that the setting confirmation has been completed, nor does it output audio indicating that the setting confirmation has been completed. However, the host control circuit 2100 lights up the LED 25 in red for a predetermined period (for example, 30 seconds), and stops lighting the LED 25 in red when the game starts. Note that the base value is displayed on the performance display monitor 334 by the main CPU 101.

In this way, even if the settings confirmation state has ended, by keeping the LED 25 fully lit in red for at least a predetermined period (for example, 30 seconds), unauthorized activities such as viewing the settings change/confirmation history screen, etc. can be prevented. This makes it possible to prevent third parties who do not have the Further, since the light emitting manner of at least the LED 25 is clearly different between during the setting change state and when the setting change state is finished, it is possible to easily understand from the appearance whether or not the game is in a state where the game can be executed.

As described above, when the host control circuit 2100 determines that there is an abnormality because no command is received from the main CPU 101 even after a predetermined period of time (for example, 30 seconds) has passed since the host control circuit 2100 was started, the host control circuit 2100 determines that the game is in a stopped state. do. When the host control circuit 2100 determines that the game is in a stopped state, the display control circuit 2300 and the audio/LED control circuit 2200 display and output the message "Please determine the setting value", and the audio/LED control circuit 2200 This causes the LED 25 (for example, see FIG. 1) to flash all white. This state is again controlled by the main CPU 101 to a setting change state, and continues until the host control circuit 2100 receives an initialization command based on the end of this setting change state.

The above are the aspects of various devices (display device 16, speaker 24, LED 25, main RAM 103, performance display monitor 334) at the time of setting confirmation.

[10-20. Setting change/confirmation history processing]
Next, the setting change/confirmation history process (step S3007) in the hall menu process (see step S303 in FIG. 108) will be explained. In the setting change/confirmation history process, the setting change/confirmation history information (described later) is displayed in the display area of the display device 16, including the history of setting changes of setting values, the history of setting value confirmations, and the viewing history of setting changes and confirmations. Displayed as "setting change history information" and "setting confirmation history information"). In the following, before explaining the setting change/confirmation history process, first, setting change, setting confirmation, and viewing will be explained.

In this embodiment, the setting change operation can be performed in the setting change process, as described above. This setting change process is started by turning on the setting key 328, pressing down the backup clear switch 330, and turning on the power switch 35 while the power is not turned on. As described above, when the setting change process is started, the setting value is displayed on the performance display monitor 334. For example, by pressing the setting switch 332, the setting value displayed on the performance display monitor 334 is increased or decreased in the range of "1" to "6", and when the desired setting value is reached, the setting key switch signal is When the setting value is turned OFF, one of the plurality of setting values used for the progress of the game is determined, and the setting change process ends.

In order to be able to display the history of setting changes, as described above, after executing the setting change process, the main CPU 101 sends an initialization command indicating that the setting change process has ended and the changed setting value information. It is transmitted to the host control circuit 2100.

On the other hand, when the host control circuit 2100 receives an initialization command indicating that the setting change process has been completed, the host control circuit 2100 includes operation type information (information indicating that the setting change process has been executed), a setting value indicating the setting value after the setting change. information and the date and time data currently measured by the RTC 209, that is, the date and time data when the initialization command was received, are stored in the subwork RAM 2100a as setting change history information. The setting change history information stored at this time corresponds to, for example, the information displayed in the "No. 3" and "No. 4" columns on the setting change/confirmation history screen displayed in FIG. 119, which will be described later. do.

Furthermore, in this embodiment, when confirming the setting values, the main CPU 101 needs to execute the setting confirmation process, as described above. This setting confirmation process is executed by turning on the setting key 328 while the power is not turned on. As described above, when the setting confirmation process is started, the setting values are displayed on the performance display monitor 334. Then, when the setting key switch signal is operated to turn OFF, the setting confirmation process ends. Note that, as mentioned above, when the setting key switch signal is operated to turn OFF and then the setting key switch signal is operated to turn ON again, the setting confirmation process may be executed again. As I said.

In addition, in order to be able to display the setting confirmation history, as described above, after executing the setting confirmation process, the main CPU 101 sends a power failure recovery command to the host control circuit 2100 as a command indicating that the setting confirmation process has ended. Send to. At this time, although the setting value has not been changed, the setting value information is also sent from the main CPU 101 to the host control circuit 2100 in order to execute the above-mentioned setting determination process (processing of steps S319 and S320, see FIG. 114). Preferably, it is sent.

On the other hand, when the host control circuit 2100 receives a power failure recovery command indicating that the setting confirmation process has been completed, the host control circuit 2100 includes operation type information (information indicating that the setting confirmation process has been executed) and the current time being clocked by the RTC 209. The date and time data, that is, the date and time data when the power failure recovery command was received, is stored in the subwork RAM 2100a as setting confirmation history information. The setting confirmation history information stored at this time corresponds to, for example, the information shown in the "No. 1" column on the setting change/confirmation history screen displayed in FIG. 119, which will be described later. In addition, as shown in the "No. 1" column on the setting change/confirmation history screen displayed in FIG. 119, setting value information is may also be displayed at the same time.

Note that the sub-work RAM 2100a according to this embodiment constitutes a memory retention storage area that can store and retain written information even in a power-off state. Therefore, even if the power to the pachinko gaming machine 1 is cut off by the operator or the power is cut off due to a power outage, etc., the memory of the setting change/confirmation history information stored in the sub-work RAM 2100a is retained. .

In this embodiment, viewing means that the main button 662 is pressed while "setting change/confirmation history" is highlighted on the hall menu screen (see FIGS. 110 and 111), and the sub-work RAM 2100a is This refers to the display of a setting change/confirmation history screen (for example, see FIG. 119 described later) that shows setting change/confirmation history information stored in the .

In order to display the browsing history (browsing history), the host control circuit 2100 executes the following process. That is, when the setting change process or the setting confirmation process is in progress (YES in step S301), the host control circuit 2100 displays a hall menu screen in the display area of the display device 16 (step S301). Then, when "setting change/confirmation history" is selected in the hall menu process (step S303) (YES in step S3006), the host control circuit 2100 highlights "setting change/confirmation history" (see FIG. 111). When the main button 662 is pressed in this state, the host control circuit 2100 reads the setting change/confirmation history information stored in the subwork RAM 2100a, and displays the setting change/confirmation history screen (for example, see FIG. 119 described later). ) is displayed in the display area of the display device 16, as well as operation type information indicating that the browsing has been performed (information indicating that the browsing has been carried out), and date and time data currently clocked by the RTC 209, that is, the browsing time (when the main button 662 was pressed) is associated with the date and time data and stored in the sub-work RAM 2100a. This is the process when the viewing history is recorded in the history recording process (steps S306 and S307) described above. That is, the viewing history is recorded in the sub-work RAM 2100a when the setting change/confirmation history screen is displayed in the display area of the display device 16, regardless of whether the setting change process or the setting confirmation process is in progress. When storing the viewing history in the sub-work RAM 2100a, the host control circuit 2100, for example, integrates the viewing history with the already stored setting change/confirmation history information and stores it in the sub-work RAM 2100a. The browsing history stored at this time corresponds to, for example, information displayed in the "No. 2" and "No. 5" columns on the setting change/confirmation history screen displayed in FIG. 119, which will be described later.

Here, the history recording processing in steps S306 and S307 is summarized as follows. First, when "setting change/confirmation history" is selected in the hall menu process (step S303) (YES in step S3006), and the command received in step S304 is an initialization command indicating the end of the setting change process. In this case, the host control circuit 2100 records both the setting change history and the viewing history. Further, in the hall menu process (step S303), "setting change/confirmation history" is selected (YES in step S3006), and the command received in step S304 is a power failure recovery command indicating the end of the setting confirmation process. At this time, the host control circuit 2100 performs both setting confirmation history and viewing history. Further, if "setting change/confirmation history" is not selected in the hall menu process (step S303) (NO in step S3006) and the command received in step S304 is an initialization command, the host control circuit 2100 Of the setting change history and browsing history, only the setting change history is performed without checking the browsing history. Further, if "setting change/confirmation history" is not selected in the hall menu process (step S303) (NO in step S3006) and the command received in step S304 is a power failure recovery command, the host control circuit 2100 performs only the setting confirmation history without checking the browsing history among the setting confirmation history and browsing history. Therefore, in the history recording process in steps S306 and S307, regardless of whether the command received in step S304 is an initialization command or a power failure recovery command, in the hall menu process (step S303) When "history" is selected (YES in step S3006), viewing recording is performed.

In addition to the settings change process or setting confirmation process, when the backup clear process that does not involve setting change process is executed as described above, the hall menu display process (step S302) or the hall menu process ( When step S303) is executed, the above-mentioned viewing record is performed, which also serves as a means of monitoring fraud by the game store clerk. In other words, in order to perform setting change processing or setting confirmation processing, a dedicated key (a key that has a cutout only at the location corresponding to the setting key 328 and is managed by the gaming machine manager) is required. For example, an ordinary store clerk who does not have a special key cannot view the data, but backup clear processing that does not involve changing settings can be viewed by a general game store clerk or unauthorized player who does not have a dedicated key. It becomes possible to do so. Therefore, by allowing the host control circuit 2100 to record viewing even when backup clear processing that does not involve setting change processing is executed, it is possible to record the viewing by the host control circuit 2100. This makes it possible to identify the person who viewed the site by comparing it with images from other sources such as cameras.

Note that in the history recording process of steps S306 and S307, regardless of whether the command received in step S304 is an initialization command indicating the end of the setting change process or a power failure recovery command indicating the end of the setting confirmation process. As described above, when "setting change/confirmation history" is selected in the hall menu process (step S303) (YES in step S3006), the viewing record is performed, but this is not necessarily the case. For example, the host control circuit 2100 selects and determines "setting change/confirmation history" in the hall menu process (step S303) (YES in step S3006), and the command received in step S304 is a power failure recovery command. performs both setting confirmation history and viewing history, but if “setting change/confirmation history” is selected in the hall menu process (step S303) (YES in step S3006), and the command received in step S304 is When the command is an initialization command, only the setting change history and the viewing history may be recorded, and the viewing history may not be recorded. This makes it possible to minimize the number of times the browsing history is recorded, and it is possible to prevent the browsing history from increasing unnecessarily and making it difficult to detect fraud. To explain this, when fraud involving setting changes is committed, it is possible to detect the possibility of fraud based on the setting change history that is not remembered by the gaming machine manager, but it is possible to detect the possibility of fraud by checking the setting confirmation history. As for the associated fraud, it is difficult to detect the possibility of fraud just by checking the settings confirmation history. Therefore, when a setting change is made, the browsing history is not recorded regardless of whether it was viewed, but when the setting is confirmed, the browsing history is recorded if the setting is viewed (at least setting value information is viewed). It was designed to be recorded. This is because it is thought that those who commit fraud mainly view the information after confirming the settings, rather than viewing the information after changing the settings. In other words, if there is no browsing history and only the setting confirmation history during the same time period, there is a low possibility of fraud, but if the number of times both the setting confirmation history and the browsing history are large, there is a possibility of fraud. . Note that regardless of whether the command received in step S304 is an initialization command or a power failure recovery command, if "setting change/confirmation history" is selected in the hall menu process (step S303) (step (YES in S3006), both the setting change history or setting confirmation history and viewing history are recorded, and the setting confirmation process is executed when displaying the setting change/confirmation history screen in the display area of the display device 16. If the operation type information indicates that a setting change process was executed, the browsing history may also be displayed, and if the operation type information indicates that a setting change process was executed, the browsing history may not be displayed.

In addition, the history recording process in steps S306 and S307 is performed when viewing is performed multiple times between the start of the hall menu display process in step S302 and the execution of the game screen return display process in step S317. However, the viewing record is executed only once in step S306 or step S307, which is executed when the setting change process or setting confirmation process is completed. For example, if you select and confirm "setting change/confirmation history" on the hall menu screen (for example, see FIG. 111) (YES in step S3046), the setting change/confirmation history screen (for example, see FIG. 119) is displayed. However, if you select and confirm "Return" on this setting change/confirmation history screen, you will be returned to the hall menu screen again. Then, when the user selects and confirms "setting change/confirmation history" on this hall menu screen, the setting change/confirmation history screen is displayed again. In this way, even if the setting change/confirmation history screen is viewed multiple times between steps S302 and S317, the viewing record will be one time.

The reason why it is preferable to limit the number of viewing records performed between step S302 and step S317 to one time is as follows. That is, for example, a person who changes settings, confirms settings, or browses for the purpose of fraud may intentionally increase the number of viewing records to increase the number of histories, thereby making it difficult to detect fraud. Therefore, even if such an action is performed, even if settings are changed, checked, or viewed multiple times between steps S301 and S314, the history of these settings is recorded only once, and the power is turned off. By not recording the history unless it is turned off and turned on again, it is possible to prevent these histories from increasing unnecessarily.

Furthermore, in the pachinko gaming machine 1 of the present embodiment, after the setting change process is finished, the hall menu redisplay process (step S312) is executed, and after the setting confirmation process is finished, the hall menu redisplay process is not executed and the game is played. Screen return processing (step S317) is executed, but for example, even after the setting key 328 is turned OFF and the setting change processing or setting confirmation processing is completed, if the setting key 328 is turned ON again, the hall menu is displayed. If the screen is designed to be displayed, the hall menu screen can be displayed again after returning to the game screen. In this case, each time you select and confirm "Setting change/confirmation history" on the hall menu screen that is displayed again, or repeatedly turn the setting key 328 on and off, you will be viewing the information. Even if there is, it is preferable to record the viewing only once.

In addition to the main button 662 and the select button 664, the pachinko game machine 1 has operation means such as a power switch 35, a firing handle 32, a volume switch 108, a setting switch 332, a setting key 328, and a backup clear switch 330. ing. Among these, the main button 662, select button 664, and firing handle 32 are operation parts that can be operated by the player, but the power switch 35, volume switch 108, setting switch 332, setting key 328, and backup clear switch 330 is an operation section that cannot be operated by the player and can only be operated by a specific person such as a gaming machine administrator.

Furthermore, in this embodiment, the display of a setting change/confirmation history screen (for example, see FIG. 119) that allows setting values to be confirmed is stored as a viewing history, but setting changes that do not display setting values - The display of the confirmation history screen (for example, see FIG. 124 described later) may be stored as the viewing history.

Next, referring to FIGS. 117, 118, and 119 to 123, the setting change/confirmation history process executed by the host control circuit 2100, and the display device 16 when the setting change/confirmation history process is executed. This will be explained in comparison with the setting change/confirmation history screen displayed in the display area.

Note that FIG. 117 is a flowchart illustrating an example of setting change/confirmation history processing executed by the host control circuit 2100. FIG. 118 is an example of the setting change/confirmation history process executed by the host control circuit 2100, and is a flowchart continued from FIG. 117. FIG. 119 is a diagram illustrating an example of the initial screen of the setting change/confirmation history screen (screen when transitioning to the setting change/confirmation history screen) displayed in the display area of the display device 16. FIG. 120 is a diagram showing an example when "Page" is selected on the setting change/confirmation history screen. FIG. 121 is a diagram illustrating an example of a page update screen that allows page updates on the setting change/confirmation history screen. FIG. 122 is a diagram showing an example when "Clear" is selected on the setting change/confirmation history screen. FIG. 123 is a diagram showing an example of a data clear screen in which each history data is cleared on the setting change/confirmation history screen.

When "setting change/confirmation history" is selected in the hall menu process (see FIG. 115) (YES in step S3006 of FIG. 115), the host control circuit 2100 performs a setting change/confirmation history screen display process (step S3051). ). At this time, the initial screen (see FIG. 119) of the setting change/confirmation history screen is displayed in the display area of the display device 16. On the initial screen of this setting change/confirmation history screen, "Back" is highlighted.

Note that the setting change/confirmation history screen displayed in the display area of the display device 16 (for example, see FIG. 119) includes a setting change/confirmation history display area 1640, an operation explanation area 1650, a first selection area 1660a, and a first selection area 1660a. 2 selection area 1660b. In FIG. 119, an example is shown in which "Page" is displayed in the first selection area 1660a, and "Clear" and "Back" are displayed in the second selection area 1660b.

For example, as shown in FIG. 119, the setting change/confirmation history display area 1640 displays a list of time information, operation type information, and setting value information in association with each other. The date and time column displays the date and time when settings were changed, settings were confirmed, and viewed. The operation type column displays the operation type (setting change, setting confirmation, viewing). In the setting value column, when a setting change is made, the setting value after the change is displayed, and when the setting is confirmed, the setting value at that time is displayed. In addition, in the operation type column, in the case of setting change, it is simply displayed as "change", and in the case of setting confirmation, it is simply displayed as "confirmation".

In this way, in the pachinko gaming machine 1 of the present embodiment, time information and operation type information (setting change, setting confirmation, viewing) are displayed in association with each other on the initial screen of the setting change/confirmation history screen. . Further, when the operation type is a setting change, the setting value after setting is displayed, and when the operation type is a setting confirmation, the setting value at that time is displayed in association with the date and time and the operation type.

The host control circuit 2100 executes a setting change/confirmation history screen display process (step S3051), and then executes a time measurement process (step S3052). This time measurement process is a process for starting time measurement by a timer built in the host control circuit 2100. Here, the timer starts counting after the setting change/confirmation history screen display process (step S3051) is executed (the initial screen of the setting change/confirmation history screen (see FIG. 119) is displayed in the display area of the display device 16. ) is displayed and no processing is performed within a predetermined time (for example, 30 seconds), the hall menu screen (for example, see FIG. 110) is displayed.

Host control circuit 2100 determines whether select button 664 has been operated in step S3053. If the select button 664 is not operated (NO in step S3053), the process moves to step S3071, which will be described later, and it is determined whether "return" has been determined on the initial screen of the setting change/confirmation history screen (see FIG. 119). On the initial screen of the setting change/confirmation history screen, "Back" is highlighted (selected) as described above, so if the main button 662 is pressed without operating the select button 664, "Back" is determined. be done.

When host control circuit 2100 determines that select button 664 has been operated (YES in step S3053), it highlights the selected item (step S3054). For example, if you operate the upper select button 664a on the initial screen of the setting change/confirmation history screen (see FIG. 119) where "Back" is highlighted, the highlight will move from "Back" to "Page" ( (See Figure 120).

After highlighting the selected item (step S3054), the host control circuit 2100 executes a time measurement process (step S3055). This time measurement process is a process of clearing the time measurement of the timer started in step S3052, and restarting the time measurement of the timer built in the host control circuit 2100. The purpose of clearing the timer and restarting the time measurement is if no processing is performed within a predetermined period of time (for example, 30 seconds) after the selected item is highlighted on the setting change/confirmation history screen (step S3054). This is to ensure that the hall menu screen (for example, see FIG. 110) is displayed when it is not performed.

In step S3056, host control circuit 2100 determines whether "Page" has been determined. When the operator presses the main button 662 with "Page" selected (highlighted) on the setting change/confirmation history screen displayed in the display area of the display device 16, the host control circuit 2100 It is determined that "Page" has been determined.

When the host control circuit 2100 determines that "Page" has been determined (YES in step S3056), it executes page update screen display processing (step S3057). When the page update screen display process is executed, a page update screen (see FIG. 121) in the setting change/confirmation history screen is displayed in the display area of the display device 16. In the page update screen of this setting change/confirmation history screen, images imitating left and right select buttons 664c and 664d, as well as "next page" and "previous page" are displayed on the left and right sides of the notation "Page". This allows the operator to understand that operating the left select button 664c will update the setting change/confirmation history screen to the previous page, and operating the right select button 664d will update the setting change/confirmation history screen to the next page. can do. Note that if you operate the left select button 664c while the first page of the setting change/confirmation history screen is displayed, the last page will be displayed, and if you operate the right select button 664d while the last page is displayed, the first page will be displayed. Convenience can be improved by cyclically displaying the eyes.

On the other hand, if "Page" has not been determined (NO in step S3056), the host control circuit 2100 moves to step S3065, which will be described later, and determines whether "clear" has been determined on the setting change/confirmation history screen. .

After executing the page update screen display process (step S3057), the host control circuit 2100 executes a time measurement process (step S3058). This time measurement process is a process of clearing the time measurement of the timer started in step S3055, and restarting the time measurement of the timer built in the host control circuit 2100. Clearing the timer's time measurement and starting time measurement again is after the page update screen display process (step S3057) is executed (after the page update screen (see Figure 121) on the setting change/confirmation history screen is displayed). ), this is to display the hall menu screen (for example, see FIG. 110) when no processing is performed within a predetermined time (for example, 30 seconds).

In step S3059, host control circuit 2100 determines whether a page update operation has been performed. If the page update operation has not been performed (NO in step S3059), the process moves to step S3062, which will be described later.

When host control circuit 2100 determines that a page update operation has been performed (YES in step S3059), it executes page update processing (step S3060). When the left and right select buttons 664c and 664d are operated on the page update screen (see FIG. 121) on the setting change/confirmation history screen displayed in the display area of the display device 16, the host control circuit 2100 performs page update processing. The setting change/confirmation history screen displayed in the display area of the display device 16 is updated to the next page or previous page's setting change/confirmation history screen and displayed. Note that illustration of the setting change/confirmation history screen when updated to the next page or previous page's setting change/confirmation history screen is omitted.

In this embodiment, the host control circuit 2100 operates when the left and right select buttons 664c and 664d are operated on the page update screen (see FIG. 121) in the setting change/confirmation history screen displayed in the display area of the display device 16. Although page update processing is performed, operations for performing page update processing are not limited to this. For example, by operating the upper and lower select buttons 664a and 664b, one of "No. 1" to "No. 5" on the setting change/confirmation history screen can be selected, and by operating the lower select button 664b, In addition, the page update process may be performed when it is determined that the row is the last row. The same applies to page update processing in a modification of the setting change/confirmation history processing to be described later.

After executing the page update process (step S3060), the host control circuit 2100 executes a time measurement process (step S3061). This time measurement process is a process of clearing the time measurement of the timer started in step S3058 and restarting the time measurement of the timer built in the host control circuit 2100. The timer is cleared and restarted after the page update process (step S3060) is executed (after the setting change/confirmation history screen for the next or previous page is displayed), and after a predetermined period of time ( This is to display the hall menu screen (for example, see FIG. 110) when no processing is performed within 30 seconds, for example.

After executing the time measurement process in step S3061, the host control circuit 2100 returns to step S3059 and determines whether a page update operation has been performed.

Host control circuit 2100 determines whether select button 664 has been operated in step S3062. If the select button 664 is not operated (NO in step S3062), the process moves to step S3072, which will be described later. In this case, the reason for moving to step S3072 instead of step S3071 is that "Back" is highlighted (selected) on the page update screen of the settings change/confirmation history screen, as in the initial screen of the settings change/confirmation history screen. That's because there aren't any.

When host control circuit 2100 determines that select button 664 has been operated (YES in step S3062), it highlights the selected item (step S3063). For example, when the lower select button 664b is operated on the setting change/confirmation history screen (see FIG. 121), the highlight display moves from "Page" to "Clear" (see FIG. 122).

After highlighting the selected item (step S3063), the host control circuit 2100 executes a time measurement process (step S3064). This time measurement process is a process of clearing the time measurement of the timer started in step S3061 and restarting the time measurement of the timer built in the host control circuit 2100. Clearing the timer and restarting the timer is only possible if no action is taken within a predetermined period of time (for example, 30 seconds) after the selected item is highlighted on the setting change/confirmation history screen. This is to allow the hall menu screen (see FIG. 110, for example) to be displayed at times.

After executing the time measurement process in step S3064, the host control circuit 2100 moves to step S3065 and determines whether "clear" has been determined. When the operator presses the main button 662 with "Clear" selected (highlighted) on the setting change/confirmation history screen displayed in the display area of the display device 16, the host control circuit 2100 It is determined that it has been determined to be "clear".

When the host control circuit 2100 determines that "clear" has been determined (YES in step S3065), it executes a setting change/confirmation history data clearing process (step S3066). This setting change/confirmation history data clearing process is a process for erasing all data of the setting change history, setting confirmation history, and viewing history stored in the sub-work RAM 2100a. When the setting change/confirmation history data clearing process is executed, all the history data displayed in the setting change/confirmation history display area 1640 in the display area of the display device 16 is erased (see FIG. 123). When the setting change/confirmation history data clearing process in step S3065 is executed, the item "Return" is highlighted.

Note that in the setting change/confirmation history data clearing process (step S3066) described above, all data of the setting change history, setting confirmation history, and viewing history stored in the subwork RAM 2100a is erased. The present invention is not limited to erasing data, and it may be possible to erase only part of the data. As a mode of erasing some data, for example, No. 1 in FIG. 1~No. A mode in which time (date and time) information, operation type information, and setting value information corresponding to a specific No. , setting confirmation, viewing), how to delete date and time information, operation type information, and setting value information corresponding to a specific operation type, and among time (date and time) information, operation type information, and setting value information. A mode may be considered in which only specific information (for example, setting value information) is deleted.

Further, it is preferable that the setting change/confirmation history data clearing process (step S3066) be executed only by those who meet specific conditions. For example, when "Clear" is selected (highlighted) on the setting change/confirmation history screen, inputting a password may be used as a condition for enabling pressing of the main button 662, for example. In this case, if the operator presses the main button 662 without entering a password, a screen requesting a password will be displayed, and only if the correct password is entered, the setting change/confirmation history data clearing process will be executed. You can do it like this. This can prevent data on setting change history, setting confirmation history, and browsing history from being cleared by mistake. Furthermore, for example, a person who has performed setting change processing or viewing for the purpose of fraud may erase the data of the setting change history, setting confirmation history, and viewing history in order to hide his or her own fraud. Therefore, by making it possible for only specific people, such as those who know the password, to execute settings change/confirmation history data clearing, it is possible to prevent settings changes or viewing for fraudulent purposes. It becomes possible.

After executing the setting change/confirmation history data clearing process (step S3066), the host control circuit 2100 executes a timekeeping process (step S3067). This time measurement process is a process of clearing the time measurement of the timer started in step S3064 and restarting the time measurement of the timer built in the host control circuit 2100. The timer clears the time measurement and restarts it after the setting change/confirmation history data clearing process (step S3066) is executed (each history data displayed in the setting change/confirmation history display area 1640 This is to display the hall menu screen (for example, see FIG. 110) when no processing is performed within a predetermined time (for example, 30 seconds) after all data have been erased.

Host control circuit 2100 determines whether select button 664 has been operated in step S3068. If the select button 664 is not operated (NO in step S3068), the process moves to step S3072, which will be described later. In this case, the reason why the process moves to step S3071 instead of step S3072 is because "Back" is highlighted (selected) on the data clear screen where each history data is cleared unless the select button 664 is operated. . Therefore, if the specifications are such that "Return" is not highlighted on the data clear screen where each history data is cleared, the process moves to step S3072.

When host control circuit 2100 determines that select button 664 has been operated (YES in step S3068), it highlights the selected item (step S3069).

After highlighting the selected item (step S3069), the host control circuit 2100 executes a time measurement process (step S3070). This time measurement process is a process of clearing the time measurement of the timer started in step S3067 and restarting the time measurement of the timer built in the host control circuit 2100. Clearing the timer and restarting the timer is possible if no processing is done within a predetermined period of time (for example, 30 seconds) after the selected item is highlighted on the setting change/confirmation history screen (step S3069). This is to ensure that the hall menu screen (for example, see FIG. 110) is displayed when it is not performed.

In step S3071, the host control circuit 2100 determines whether "return" has been determined. When the operator presses the main button 662 with "Back" selected (highlighted) on the setting change/confirmation history screen displayed in the display area of the display device 16, the host control circuit 2100 It is determined that "Go back" has been determined.

When the host control circuit 2100 determines that "return" has been determined (YES in step S3071), it executes the hall menu screen display process (step S3073), and ends the setting change/confirmation history process. This hall menu screen display process is a process of displaying the initial screen of the hall menu screen (see FIG. 110) in the display area of the display device 16 instead of the setting change/confirmation history screen.

Note that if "return" is not determined in step S3071 (NO in step S3071), the host control circuit 2100 determines whether a predetermined time has elapsed (step S3072).

If the host control circuit 2100 determines in step S3072 that the predetermined time has elapsed (YES in step S3072), the process proceeds to step S3073, closes the setting change/confirmation history screen displayed in the display area of the display device 16, and closes the hall. The initial screen of the menu screen (see FIG. 110) is displayed. In other words, even if the operator does not select and decide on the "return" item, if the period of no operation continues for a predetermined period, the display of the setting change/confirmation history screen will end and the initial screen of the hall menu screen will be displayed. The Rukoto.

On the other hand, if the predetermined time has not elapsed in step S3072 (NO in step S3072), the host control circuit 2100 returns to step S3053 and continues the processing from step S3053 onwards.

In this way, on the setting change/confirmation history screen displayed on the display device 16 while changing or confirming settings, the setting change/confirmation history screen ends when a predetermined period of time elapses without any operations being performed. , the hall menu screen is configured to be displayed. However, on the hall menu screen, even if there is no operation, the hall menu screen will not end as long as the settings are being changed or settings are being confirmed, and the host control circuit 2100 controls the hall menu screen to continue displaying. do. In this case, the item for ending the hall menu is not displayed on the hall menu screen.

Note that the process of proceeding to step S3073 when it is determined in step S3072 that a predetermined time has elapsed (YES in step S3072) is performed during the hall menu process (i.e., during the setting change or During the setting confirmation), a different process (not shown) is executed in the hall menu process (that is, after the setting change or setting confirmation is completed) in step S313 (see FIGS. 108 and 114). Specifically, when a predetermined time has elapsed without any operation in the setting change/confirmation history process (step S3007) in the hall menu process in step S313 (when a predetermined time has elapsed in step S3072 in the hall menu process in step S313) (step S3072 (YES), the host control circuit 2100 moves to step S317 (see FIGS. 108 and 114), finishes displaying the setting change/confirmation history screen, and executes a game screen return display process (step S317). Then, the hall menu display prohibition process (step S318) is executed. In other words, on the setting change/confirmation history screen while changing settings or checking settings, if no operation continues for a predetermined period of time, the screen simply returns to the hall menu screen (you can view the setting change/confirmation history screen again). However, on the setting change/confirmation history screen that is displayed via the hall menu screen that is redisplayed after the setting change process is completed, if no operation continues for a predetermined period of time, the setting change/confirmation history screen will be displayed again. become unable to do so.

Furthermore, regarding the process of returning to step S3053 when it is determined in step S3072 that the predetermined time has not elapsed (NO in step S3072), the hall menu process (i.e., the setting This is a process during change or confirmation of settings), and a different process is executed in the hall menu process of step S313 (see FIGS. 108 and 114) (that is, after the setting change or confirmation is completed) (not shown). Specifically, even if the no-operation period has not reached a predetermined period in the setting change/confirmation history process (step S3007) in the hall menu process in step S313 (NO in step S3072), for example, a production control object is generated. Based on the fulfillment of a predetermined termination condition such as when it is determined that a command has been received, a game screen return process (step S317) and a hall menu display prohibition process (step S318) are executed. In other words, on the setting change/confirmation history screen while changing settings or checking settings, if no operation continues for a predetermined period of time, the screen simply returns to the hall menu screen (you can view the setting change/confirmation history screen again). However, on the setting change/confirmation history screen that is displayed via the hall menu screen that is redisplayed after the setting change process is completed, the setting change/confirmation history will be displayed again even if the inactivity time has not reached the specified time. You will be unable to view the screen. In other words, on the setting change/confirmation history screen that is displayed via the hall menu screen that is redisplayed after the setting change process is completed, the period of no operation continues for a predetermined period, and the above predetermined end condition is met. Unless this holds true, the processes from step S3053 to step S3072 will be repeatedly executed.

In this way, when the setting change process is executed, even if the setting change process is completed, the operator is allowed time to view confidential information such as the history of setting changes and setting confirmations, and the process is performed for a predetermined period of time ( For example, if there is no operation for a period of 30 seconds, the display of the setting change/confirmation history screen will end and the game screen return process (step S317) and hole menu prohibition process (step S318) will be executed. (For example, a hall attendant who is not a game machine manager or a player) cannot easily view confidential information such as setting change history, setting confirmation history, viewing history, etc., making it possible to ensure security.

In addition, in the pachinko gaming machine 1 of this embodiment, for example, on the setting change/confirmation history screen shown in FIG. A list screen showing all the information will be displayed. That is, the first information (for example, No. 3 in FIG. 119) in which the time information and setting value information when the setting is changed is displayed, and the time information and setting value information when the setting is confirmed are displayed. The second information displayed (for example, No. 3, No. 4 in FIG. 119), and the third information (for example, No. 4 in FIG. 119) displaying the time information and setting value information when viewed. 2, No. 5) are displayed in a list. However, an operator (for example, a gaming machine manager) may want to narrow down the target to display specific operation type information. Therefore, there is a screen where time information, operation type information, and setting value information are displayed in a list (for example, see FIG. 119), and the above first information, the above second information, and the above third information. It is preferable that the narrowing-down screen narrowed down to only specific information can be selectively displayed in the display area of the display device 16 according to the intention of the operator. This makes it possible to improve convenience for the operator. In particular, the above-mentioned first information is highly convenient for business because it not only allows fraud to be detected but also information such as how many days the business was conducted with the set value. The above-mentioned narrowing-down screen may display information unrelated to the operation type (for example, current time information, etc.) because it is sufficient to narrow down the target to specific operation type information and display it.

[10-21. Other examples of display screens displayed during setting change/confirmation history processing]
Next, other examples of display screens displayed in the display area of the display device 16 in the setting change/confirmation history process will be described with reference to FIGS. 124 to 128. However, since the setting change/confirmation history process executed by the host control circuit 2100 is the same as that shown in FIGS. 117 and 118, in this other example, the screen displayed in the display area of the display device 16 will be described. A description of the setting change/confirmation history process executed by the host control circuit 2100 will be omitted.

FIG. 124 is another example of the setting change/confirmation history screen displayed in the display area of the display device 16, and is a diagram showing an example of the initial screen. FIG. 125 is another example of the setting change/confirmation history screen displayed in the display area of the display device 16, and is a diagram showing an example when "setting display" is selected. FIG. 126 is another example of the setting change/confirmation history screen displayed in the display area of the display device 16, and is a diagram showing an example when setting values are newly added and displayed. FIG. 127 is another example of the setting change/confirmation history screen displayed in the display area of the display device 16, and is a diagram showing an example when "Page" is selected. FIG. 128 is another example of the setting change/confirmation history screen displayed in the display area of the display device 16, and is a diagram illustrating an example of a page update screen on which page updates can be performed.

For example, as shown in FIG. 124, the setting change/confirmation history screen includes a setting change/confirmation history display area 1670, an operation explanation area 1680, a first selection area 1690a, and a second selection area 1690b.

In the initial screen of the setting change/confirmation history screen shown in FIG. 124, time information and operation type information are displayed in the setting change/confirmation history display area 1670, but setting value information is not displayed. That is, the setting change/confirmation history screen shown in FIG. 124 is a screen in which only time information and operation type information among the time information, operation type information, and setting value information are displayed. Note that the date and time column where time information is displayed displays the date and time when settings were changed, settings confirmed, or viewed, and the operation type column where operation type information is displayed displays the operation type (settings change, (Setting confirmation, viewing) will be displayed.

Further, in the initial screen of the setting change/confirmation history screen, in addition to "clear" and "return", "setting display" is also displayed in the second selection area 1690b. In addition, on the initial screen of the setting change/confirmation history, "Back" is selected and displayed (highlighted). In this other example as well, by operating the select button 664, it is possible to select an item to be highlighted.

When "setting display" is selected by operating the select button 664, "setting display" is highlighted (see FIG. 125). When the host control circuit 2100 detects that the main button 662 is pressed while "setting display" is selected (highlighted), the time information and operation type information are displayed, but the setting value information is displayed. In place of the initial screen of the setting change/confirmation history screen that is not displayed, a setting change/confirmation history screen (list screen) is displayed that displays time information, operation type information, and setting value information in a list (Figure 126). In this way, in this other example, although the setting values are not displayed on the initial screen of the setting change/confirmation history screen, by selecting and confirming "Setting display", you can associate them with the date and time and operation type. A new list of setting values will be displayed. Note that when the settings change/confirmation history screen that displays time information, operation type information, and setting value information is displayed instead of the initial screen of the settings change/confirmation history screen, as shown in FIG. Back” will be highlighted.

If you operate the select button 664 and select "Page" on the setting change/confirmation history screen (see Figure 126) where time information, operation type information, and setting value information are displayed, "Page" will be highlighted. (See Figure 127). When the host control circuit 2100 detects that the main button 662 is pressed while "Page" is selected (highlighted), the host control circuit 2100 executes page update processing. When this page update process is executed, a page update screen (see FIG. 128) in the setting change/confirmation history screen is displayed in the display area of the display device 16. On this page update screen, it is possible to update to the next page or previous page by operating the left and right select buttons 664c and 664d.

Also, if you select "Page" and press the main button 662 on the initial screen of the setting change/confirmation history screen (see Figure 124) where time information and operation type information are displayed but setting value information is not displayed, Also, page update processing is executed by the host control circuit 2100. However, when this page update process is executed, although the time information and operation type information are displayed in the display area of the display device 16, the page update screen on the setting change/confirmation history screen where setting value information is not displayed is displayed. Is displayed. On this page update screen, by operating the left and right select buttons 664c and 664d, it is possible to update to the next page or the previous page of the setting change/confirmation history screen in which setting values are not displayed. However, the configuration may be such that the page update process cannot be executed on the setting change/confirmation history screen where time information and operation type information are displayed but setting value information is not displayed.

Note that in other examples, of the time information, operation type information, and setting value information, only the time information and operation type information are displayed on the screen as shown in FIG. 124, and the time information and operation type information are displayed on the screen as shown in FIG. Although it is possible to selectively display a screen displaying a list of information and setting value information, the screen in FIG. 124 displays one or two of the time information, operation type information, and setting value information. Any screen that displays only information will suffice.

Additionally, the settings change/confirmation history screen, which displays a list of time information, operation type information, and setting value information, can only be viewed by those who meet certain conditions (for example, those who have entered the correct password). However, this will be described later.

FIG. 129 shows a setting change/confirmation history screen on which setting values can be checked on the hall menu screen displayed in the display area of the display device 16 of the pachinko gaming machine 1 according to the first embodiment of the present invention. It is a flowchart which shows an example of the operation procedure until it is displayed. As shown in FIG. 129, in the pachinko gaming machine 1 according to the present embodiment, as a first step for viewing setting change/confirmation history information, when a setting change process or a setting confirmation process is executed, a hall menu Display the screen. As described above, the setting change process can be executed by turning on the setting key 328, pressing the backup clear switch 330, and turning on the power switch 35 while the power is not turned on. Further, the setting confirmation process can be executed by turning on the setting key 328 while the power is not turned on. The setting key switch signal can be turned on by turning the setting key 328 in one direction, and the setting key switch signal can be turned off by turning it in the opposite direction (returning to the original position). It is configured to allow.

Note that in the pachinko gaming machine 1 of this embodiment, the ON operation of the setting key 328 is an operation that is performed regardless of whether the setting change process or the setting confirmation process is executed, but is not limited to this. The operation may be performed when executing at least one of the change process and the setting confirmation process. The same applies to any of the modified examples described below.

As a second step, the pachinko gaming machine 1 selects and determines "setting change/confirmation history" in the hall menu on the hall menu screen (for example, see FIG. 111). ” is highlighted, and a preview of the settings change/confirmation history screen containing the settings change/confirmation history information with only the date/time data and operation type (corresponding operation type among settings change, confirmation, and viewing) displayed. Display the screen (see Figure 111) (setting values are not displayed).

As a third step, the pachinko gaming machine 1 presses the main button 662 on the hole menu screen displayed in the second step (see FIG. 111) with "setting change/confirmation history" highlighted. When pressed, a setting change/confirmation history screen (see FIG. 119) is displayed in the display area of the display device 16. On this setting change/confirmation history screen, date and time data, operation type (corresponding operation type among setting change, confirmation, and viewing) and setting values are associated with each other.

Therefore, a person who can use and operate the setting key 328 (person with authority) cannot change the settings or change the settings on the setting change/confirmation history screen (see FIG. 119) that is displayed after the first to third steps above. By viewing the confirmation history, you will be able to see at a glance the history of setting changes, confirmation of setting changes, and viewing of setting changes and confirmations and the corresponding setting values that define the ball payout rate. . It should be noted that the person with authority is a person who has been given authority to change settings, confirm changes in settings, etc., and means a manager of a hall or the like. Hereinafter, the "authorized person" may also be referred to as the "administrative authority person."

As described above, the pachinko game machine 1 constituting the game machine according to the present invention includes a display device 16 that displays various images, a group of operation buttons 66 such as a main button 662 and a select button 664, and controls related to the game. The control unit includes a main CPU 101 that is a control unit that controls display, and a host control circuit 2100 that is a display control unit that controls display on the display device 16. The display control section includes a setting switch 332 that is a setting means that enables the display, and a data transmitting means that transmits various data to the host control circuit 2100, and a receiving means that receives various data from the data transmitting means. The main CPU 101 includes a sub-work RAM 2100a that functions as a backup memory that can store and retain written information even in a power-off state, and an RTC 209 that measures date and time. and the setting value to the host control circuit 2100, and if the data received by the data receiving means is a setting change or setting confirmation, the host control circuit 2100 sends the setting change or setting confirmation or setting value to the subwork RAM 2100a. and a setting display function that stores date and time data from the RTC 209 as setting change/confirmation history information, and displays setting changes or setting confirmations and date and time data stored in the subwork RAM 203 on the display device 16. The setting value stored in the sub-work RAM 2100a is displayed when the main button 662 is operated while the confirmation and date/time data are displayed.

With this configuration, setting changes or setting confirmations, setting values, and date and time data from the RTC 209 are stored in the subwork RAM 2100a as setting change/confirmation history information. When button 662 is operated, setting values stored in sub-work RAM 2100a can be displayed. Therefore, when "setting change/confirmation history" in the hall menu is selected, it is possible to check each history regarding setting values, and it is possible to determine whether or not unauthorized setting changes or setting confirmations have been made. It becomes like this.

Furthermore, the pachinko gaming machine 1 according to the present embodiment may have a configuration in which the date and time data on which the setting value is received is acquired from the RTC 209, and the setting value, the date and time data, and information representing a setting change are stored in association with each other. good.

With this configuration, the changed setting value, changed date and time data, and information representing the setting change are stored in association with each other, so that an authorized person can identify the date and time when the setting value was changed. This makes it possible to identify fraud, such as changing setting values, if it has been committed.

Furthermore, the pachinko gaming machine 1 according to the present embodiment acquires the date and time when information indicating that the setting value has been confirmed is received from the RTC 209, and stores the date and time data and the information indicating the setting confirmation in association with each other. Good too.

With this configuration, the date and time data when setting values were confirmed and the information representing the setting confirmation are stored in association with each other, so an authorized person can specify the date and time when setting values were confirmed, and If fraud, such as checking a value, has been carried out, it becomes possible to identify the fraud.

Furthermore, in the pachinko gaming machine 1 according to the present embodiment, when setting changes or setting confirmations, setting values, and date and time data are displayed among the setting change/confirmation history information of the sub-work RAM 2100a, the displayed The configuration may be such that date and time data is stored in the sub-work RAM 2100a as a viewing history, and the viewing history is displayed on the display device 16.

With this configuration, when setting changes or setting confirmations, setting values, and date and time data are displayed in the setting change/confirmation history information, the displayed date and time data is stored in the subwork RAM 2100a as the viewing history, You can view your browsing history. Therefore, when "Setting change/confirmation history" is selected in the hall menu where setting values are not displayed, in addition to displaying setting changes or setting confirmations, setting values, and date and time data among setting change/confirmation history information, Since the history can be displayed, it can be determined whether or not the viewing history for setting changes or setting confirmations has been viewed for fraudulent purposes such as cheating.

With the above configuration, in this embodiment, it is possible to save and display setting change/confirmation history information that associates setting changes or setting confirmations, setting values, and date and time data, so that each history related to setting values can be saved and displayed. It is possible to provide a pachinko game machine 1 that can confirm whether or not an unauthorized setting change or setting confirmation has been made.

Further, the pachinko game machine 1 constituting the game machine according to the present invention includes a display device 16 that displays various images, operation units such as a main button 662 and a select button 664, and a control unit that performs control related to the game. It includes a main CPU 101 and a host control circuit 2100 that is a display control unit that controls the display of the display device 16, and the control unit has settings that enable changing or checking of setting values (for example, settings 1 to 6). The display control unit includes a setting switch 332 as a means, and a data transmitting means for transmitting various data to the host control circuit 2100, and a receiving means for receiving various data from the data transmitting means, and The main CPU 101 is equipped with a sub-work RAM 2100a that can store and hold information written even when the computer is in use, and an RTC 209 that measures date and time. If the data received by the data receiving means is a setting change or setting confirmation, the host control circuit 2100 sends the setting change or setting confirmation, setting value, and date and time data from the RTC 209 to the subwork RAM 2100a. The display device 16 has a setting display function that displays setting change/confirmation history information stored in the subwork RAM 2100a as confirmation history information on the display device 16. , the date and time data is stored in the sub-work RAM 2100a as a viewing history, and the viewing history is displayed on the display device 16.

With this configuration, when the setting change/confirmation history information of the subwork RAM 2100a is displayed, the displayed date and time data is stored as the viewing history in the subwork RAM 2100a, and the viewing history is displayed in the display area of the display device 16. be able to. Therefore, it is not only possible to determine whether an unnatural operation has been performed, but also whether it is an opportunity to investigate fraudulent activity.

Furthermore, the pachislot machine according to the present embodiment acquires date and time data when setting change/confirmation history information is displayed on the display device 16 from the RTC 209, and stores the date and time data in association with information representing the viewing history. You can also use it as

With this configuration, the date and time data and information representing the viewing history are stored in association with each other, so it is possible to identify the date and time when information related to setting values was viewed, and to prevent fraud such as changing setting values. This makes it possible to identify fraud if it has been committed.

Furthermore, in the pachinko gaming machine 1 according to the present embodiment, when setting changes or setting confirmations, setting values, and date and time data are displayed among the setting change/confirmation history information of the sub-work RAM 2100a, the displayed The configuration may be such that date and time data is stored in the sub-work RAM 2100a as a viewing history, and the viewing history is displayed on the display device 16.

With this configuration, when setting changes or setting confirmations, setting values, and date and time data are displayed in the setting change/confirmation history information, the displayed date and time data is stored in the subwork RAM 2100a as the viewing history, The viewing history can be displayed on the display device 16. Therefore, when "Setting change/confirmation history" is selected in the hall menu where setting values are not displayed, in addition to displaying setting changes or setting confirmations, setting values, and date and time data among setting change/confirmation history information, Since the history can be displayed, it can be determined whether or not the viewing history for setting changes or setting confirmations has been viewed for fraudulent purposes such as cheating.

With the above-described configuration, in this embodiment, it is possible to save and display viewing history information that associates the viewing history of viewing setting change confirmation/history information with date and time data, thereby preventing unnatural operations regarding setting values. It is possible to provide a pachinko game machine 1 that can not only determine whether a fraudulent act has been committed, but also determine whether or not it is an opportunity to investigate a fraudulent act.

[10-22. Maintenance processing]
Next, referring to FIGS. 130 to 132, the maintenance process executed by host control circuit 2100 (step S3019) and the maintenance screen displayed in the display area of display device 16 when the maintenance process is executed. Explain by comparing. Note that FIG. 130 is a flowchart illustrating an example of maintenance processing executed by the host control circuit 2100. FIG. 131 is a diagram illustrating an example of a maintenance screen displayed in the display area of the display device 16. FIG. 132 is an example of a maintenance screen displayed in the display area of the display device 16.

In the maintenance process, the host control circuit 2100 displays a maintenance screen (see FIGS. 131 and 132) in the display area of the display device 16. In this maintenance process, devices connected to the host control circuit 2100 (e.g., various sensors, various operating accessories, etc.), such as performance accessories such as the performance button switch 621 and the performance accessory group 1000, are subject to maintenance processing. This allows the operator to check whether these devices are working properly.

As shown in FIGS. 131 and 132, the host control circuit 2100 displays an operation status display table of various devices (such as various sensors and various accessories) approximately in the center of the maintenance screen (see FIGS. 131 and 132). . This operating status display table includes, for example, a name column in which the names of 28 various devices are displayed, and a number column in which serial numbers (1 to 28) assigned to the various devices displayed in the name column are displayed. and an operation status column indicating the operation status of various devices. The "OFF" display in the operation state column indicates that there is no input from various devices. When input is received from various devices, the display in the operation state column is changed from "OFF" display to "ON" display. For example, when the production button 1 is operated while the maintenance screen is displayed, the host control circuit 2100 changes the display of the operation state column of the production button 1 from "OFF" display to "ON" display. Note that the "ON" display is displayed in red. The above-mentioned "input from each device" is based on detection of input ports, etc. by the host control circuit 2100. In addition, each performance accessory has at least an accessory detection sensor group 1002 (see FIG. 9) that detects its presence in a normal position (for example, an initial position), and when the sensor that detects the normal position is ON, It is assumed that the display is turned OFF and the display is turned ON when the accessory object detection sensor group 1002 that detects the normal position is OFF, that is, when the performance accessory moves.

Further, the host control circuit 2100 displays the operation method on the maintenance screen at the bottom of the maintenance screen. Specifically, if the main button 662, upper select button 664a, and lower select button 664b are pressed at the same time, a message is displayed indicating that the initial screen of the hall menu screen (see FIG. 110) will be returned to (redisplayed). Further below, images corresponding to the main button 662 and the select button 664 are displayed. In FIG. 132, the images corresponding to all the select buttons 664a to 624d are displayed in white to indicate that they are valid.

In the maintenance process (see FIG. 130), the host control circuit 2100 first obtains subdevice input information (step S3081). The sub-device input information is the detection results of the operating states of the various devices numbered 21 to 28 in the operating state display table shown in FIG. The sub-device input information includes sub-input state information indicating whether the various devices described above are in an on state, which is a state in which there is an input, or an off state, which is a state in which there is no input.

Next, the host control circuit 2100 performs sub-input state information editing processing to read sub-input state information in the acquired sub-device input information (step S3082).

Next, the host control circuit 2100 performs maintenance screen display processing to display a maintenance screen (see FIGS. 131 and 132) in the display area of the display device 16 based on the sub-input state information read out in step S3082 (step S3082). S3083). In this process, the maintenance screen is displayed and the display is updated (for example, changing from "OFF" display to "ON" display).

Next, the host control circuit 2100 determines whether the main button 662, the upper select button 664a, and the lower select button 664b are operated at the same time (step S3084). If it is determined that the main button 662, the upper select button 664a, and the lower select button 664b are operated at the same time (YES in step S3084), the host control circuit 2100 ends the maintenance process and the hall menu process (see FIG. 115), The process returns to step S304 of the hole menu task (see FIG. 108).

On the other hand, if it is determined that the main button 662, the upper select button 664a, and the lower select button 664b are not operated at the same time (NO in step S3084), the host control circuit 2100 returns the process to step S3081.

By the way, some of the recent pachinko gaming machines and pachislot machines have multiple functions in one device. For example, in the pachinko game machine 1 of this embodiment, the production button 62 has the functions of an operation button and a production button. The function of the production button corresponds to, for example, a function of protruding upward based on the lottery result of a special symbol. Then, when the "effect button 1" with the serial number 21 shown in FIG. Further, when the "effect button 2" with the serial number 22 shown in FIG. 132 is selected, the host control circuit 2100 moves the effect button 62 upward and performs maintenance on the effect function. If the result of the maintenance operation is determined to be normal, the host control circuit 2100 executes maintenance screen display processing (step S3083), and executes maintenance screen display processing (changes from "OFF" display to "ON" display). ). Note that the effect button 62 that protrudes upward due to the selection and determination of “effect button 2” can be used, for example, if it is determined to be normal, the selection button 664 can be operated to select the item with the other serial number shown in FIG. 132. If the main button 662, upper select button 664a, and lower select button 664b are pressed at the same time and the maintenance mode ends, the host control circuit 2100 causes the host control circuit 2100 to return to the normal state (the state before protruding upward). controlled.

In addition, some recent pachinko and pachislot machines are equipped with multiple performance accessories with different drive means, and in such game machines, multiple performance accessories with different drive means can be operated at the same time. Maintenance may be performed, or maintenance may be performed by operating each of a plurality of performance accessories having different drive means at different timings, or maintenance may be performed by operating each of the performance accessories individually. For example, in a game machine including performance accessory 1 to performance accessory 3 having different driving means, when "performance accessory 1+2" with serial number 14 shown in FIG. 132 is selected, the host control circuit 2100 Maintenance is performed by simultaneously operating a performance accessory 1 and a performance accessory 2. Further, for example, when "performance accessory 1 → 2" with serial number 17 shown in FIG. and perform maintenance. Further, for example, when "performance accessory 1" with serial number 11 shown in FIG. 132 is selected and determined, the host control circuit 2100 operates the performance accessory 1 independently and performs maintenance. In addition, for example, if production 1 and production 3 are activated at the same time, they will interfere with each other and become inoperable, for example, "performance accessory 1 + 3" with serial number 15 in FIG. 132 cannot be selected, or even if selected, it cannot be determined. (The operation of the main button 662 is not enabled). In FIG. 132, "performance accessory 1+3" with serial number 15 is shaded as an item that cannot be selected. However, if, for example, production 1 and production 3 are activated at the same time, they will interfere with each other and become inoperable, but if they are activated at different timings (for example, first production accessory 1 is activated, then If this does not interfere with the operation of performance accessory 3), it is preferable to allow selection of "performance accessory 1→3" with serial number 18 shown in FIG. 132, for example. In this way, it is possible to operate multiple performance accessories, to operate them at different timings, or to operate them independently, and in cases where they would interfere if they were activated at the same time, they can be operated simultaneously. By disabling the operation, it is possible to improve maintainability while avoiding troubles.

Although not shown in FIG. 132, there are included sensors such as a payout sensor for game balls and medals, a payout security ball sensor, a lending button (also referred to as a ball lending button), a return button for a CR card, a settlement button for a pachislot machine, and a payout sensor for game balls and medals. In a pachinko game machine that enables games by circulating game balls, it is preferable that the game ball launch detection sensor and the like be subject to maintenance as well. Furthermore, in the pachinko gaming machine 1 of the present embodiment, the explanation has been made regarding the devices (various sensors, various accessories, etc.) connected to the host control circuit 2100 as being subject to maintenance processing, but the invention is not limited to this. The maintenance processing may be performed on devices such as the power switch 35, the first starting port switch 421, the second starting port switch 441, etc. Furthermore, in the CR machine, based on the operation of the lending button or the return button of the CR card, a pseudo Alternatively, the normal state of the signal communication may be detected, and if it is normal, a maintenance screen display process may be executed (change from "OFF" display to "ON" display).

[10-23. Mobile device linkage function]
Next, referring to FIGS. 133 to 135, the mobile terminal cooperation function of the pachinko gaming machine 1 will be explained as an example.

The mobile terminal cooperation function of the pachinko game machine 1 is a function that allows the pachinko game machine 1 and the mobile terminal to cooperate. By using the mobile terminal linkage function of the pachinko game machine 1, you can record detailed information about the games played by the player, and customize functions that do not affect the game results of the pachinko game machine 1 by meeting predetermined conditions. You can do it.

Examples of the predetermined conditions include, for example, that the result of the jackpot determination of the special symbol is determined to be a small hit that does not involve the operation of a conditional device, or that a specific performance has been executed. In addition, customizing functions that do not affect the game results of the pachinko game machine 1 includes, for example, changing the music output during jackpot games or high probability game states to special songs, and Examples include changing the costume of the character displayed on the screen.

When using the mobile terminal cooperation function, first, a guide menu screen (guide initial image) is displayed in the display area of the display device 16. If, for example, the main button 662 is pressed in a state where the decorative symbols displayed in the display area of the display device 16 are not displayed in a variable manner, a guide initial image is displayed in the display area of the display device 16.

FIG. 133 is a diagram showing an example when the guide initial image is displayed in the display area of the display device 16. The initial guide image includes the words "UNIMEMO (registered trademark)", the words "Please choose your favorite menu", and a guide menu.

As shown in FIG. 133, the items of the guide menu include "Start Unimemo", "Jackpot symbol/Number of rounds", "Model site", and "Return to game". In the initial guide image, "Start Unimemo" is highlighted. The highlighted item among the plurality of guide menu items can be selected by operating the upper and lower select buttons 664a and 664b. Furthermore, when the main button 662 is operated, the highlighted item is determined. In FIG. 133, each item is surrounded by a solid line frame, and the highlighted item "Start Unimemo" is surrounded by a thicker solid line frame.

When "Start UniMemo" is selected from the guide menu, an initial UniMemo image is displayed in the display area of the display device 16. Furthermore, when "jackpot symbol/number of rounds" is selected, the jackpot symbol/number of rounds is displayed in the display area of the display device 16 (not shown). When "model site" is selected, a model site registration code is displayed in the display area of the display device 16 (not shown).

When "Return to Game" is selected, the display of the initial guide image displayed in the display area of the display device 16 ends (the display of the guide menu also ends). In the display area of the display device 16, there are displayed images for effects to be displayed when playing a game, information on whether the firing handle 32 has not been operated for a predetermined period, whether the first starting port 420 or the second starting port 440 has been activated, etc. A demo video will be displayed if you do not win a prize for a predetermined period of time. Furthermore, even if a predetermined period of time has passed without selecting any of the items on the guide menu, the display area of the display device 16 will display the performance video displayed when playing the game and the above-mentioned demo video. be done.

FIG. 134 is a diagram showing an example when the UniMemo initial image is displayed in the display area of the display device 16. The UniMemo initial image displays the words "UniMemo", the words "Customize your favorite character", and the UniMemo menu. Items on the UniMemo menu include "password input," "record," "record and exit," "membership registration," "return to game," and "return." In the UniMemo initial image, "Password input" is highlighted. The highlighted item among the plurality of UniMemo menu items can be selected by operating the select buttons 664a to 664d. Furthermore, when the main button 662 is operated, the highlighted item is determined. In FIG. 134, each item is surrounded by a solid line frame, and the highlighted "Password Input" is surrounded by a thicker solid line frame.

When "password input" is selected and determined, a password request screen is displayed in the display area of the display device 16 (see FIG. 135).

FIG. 135 is a diagram showing an example when a password request screen is displayed in the display area of the display device 16. The password display image includes the text "Please enter your password" and a password input menu.

A plurality of password input menu items are displayed in the password input menu. The password input menu items are "Confirm", "Delete", numbers "0" to "9", alphabets "A" to "F", "Return to game", and "Back". including. In the password display image, the highlighted item from "0" to "9" and "A" to "F" can be selected by operating the select buttons 664a to 664d, and by operating the main button 662. , determined by the highlighted number or alphabet. The determined numbers or alphabets are displayed on the password display image. When "Determination" in the password input menu is selected and determined, the plurality of characters displayed in the password display image are determined as the password to be input. Then, when "Delete" is selected in the password input menu, each character from the last input character is deleted from the password display image.

When "Return to Game" is selected in the password input menu, the display area of the display device 16 will display an image for presentation to be displayed when playing the game, or if the firing handle 32 has not been operated for a predetermined period or if the first A demonstration video that is displayed when no prize is won in either the starting opening 420 or the second starting opening 440 for a predetermined period is displayed. Further, when "Back" is selected in the password input menu, the UniMemo initial image is displayed in the display area of the display device 16.

[10-24. Modified example of setting change/confirmation history processing]
Modifications 1 to 3 of the setting change/confirmation history process will be described below.
[10-24-1. Modification example 1 of setting change/confirmation history processing]
First, modification example 1 of setting change/confirmation history processing will be described with reference to FIGS. 136 to 141.

The setting change/confirmation history process in this modification 1 is substantially the same as the setting change/confirmation history process described above with reference to FIGS. 117 and 118, except that it includes an authentication function for viewing setting values. . In the following, points different from the setting change/confirmation history process described above will be explained in detail with reference to FIGS. 117 and 118. In addition, in the setting change/confirmation history processing described above with reference to FIGS. 117 and 118, if no processing is performed within a predetermined time (for example, 30 seconds), the hall menu screen (for example, see FIG. 110) It has been explained that the timing process (see step S3052 in FIG. 117, etc.) is performed in order to display the . In this modification example 1 as well, when the timing process is performed in the same way as the setting change/confirmation history process described above with reference to FIGS. 117 and 118, and no process is performed within a predetermined time (for example, 30 seconds), Although the hall menu screen may be displayed at the same time, the explanation of the time measurement process will be omitted in the following explanation.

FIG. 136 is a flowchart showing a first modification of the setting change/confirmation history process executed by the host control circuit 2100. This setting change/confirmation history process is performed in step S3006 of FIG. 115 when "Setting change/confirmation history" is selected (highlighted) from the hall menu screen being displayed (see FIGS. 110 and 111). The process is started on the condition that the main button 662 is pressed.

When the setting change/confirmation history process is started, the host control circuit 2100 performs an authentication process to authenticate administrator authority (step S3100). This authentication process will be explained with reference to FIG. 137. FIG. 137 is a flowchart illustrating an example of authentication processing in modification example 1 of the setting change/confirmation history processing executed by the host control circuit 2100.

As shown in FIG. 137, in the authentication process, the host control circuit 2100 first enters a password in the display area of the display device 16 where the hall menu screen is displayed, as shown in FIGS. 138 and 139, for example. A password request screen is further displayed (step S3101). FIG. 138 shows a password request screen displayed in the display area of the display device 16 when the setting change/confirmation history process is executed in modification example 1 of the setting change/confirmation history process executed by the host control circuit 2100. FIG. FIG. 139 is an example of a password request screen displayed in the display area of the display device 16 in modification example 1 of the setting change/confirmation history process executed by the host control circuit 2100.

In this modification example 1, when the setting change/confirmation history process is started (the main button 662 is pressed while "setting change/confirmation history" is selected (highlighted) on the hall menu screen). For example, as shown in FIGS. 138 and 139, the password request screen is displayed while the hall menu screen is being displayed, but this is not necessarily the case. For example, when the settings change/confirmation history is started, the settings change/confirmation history screen displays only time information, operation type information, and setting value information (setting values are not displayed). , and the password request screen may be displayed while this setting change/confirmation history screen is displayed, or the password request screen may be displayed without displaying either the hall menu or the setting change/confirmation history screen. Only the screen may be displayed.

When the password is input, the host control circuit 2100 executes password input processing (step S3102), and moves to step S3103.

In step S3103, the host control circuit 2100 determines whether or not the input password is appropriate. If the input password is appropriate (YES in step S3103), the authentication process ends. On the other hand, if it is determined that the input password is incorrect (NO in step S3103), the host control circuit 2100 executes authentication NG display processing (step S3104). When the authentication NG display process is executed, the screen shown in FIG. 140, for example, is displayed in the display area of the display device 16. Here, FIG. 140 is an example of a screen displayed in the display area of the display device 16 when the input password is inappropriate in modification example 1 of the setting change/confirmation history process executed by the host control circuit 2100. FIG.

When the host control circuit 2100 executes the authentication process in step S3100, if it determines that the authentication result is correct, that is, the password is appropriate (YES in step S3103), it determines that the authentication is OK (YES in step S3110). , the process moves to step S3120. On the other hand, if it is determined that the password is incorrect (NO in step S3103), the host control circuit 2100 determines that the authentication is not OK (NO in step S3110), and ends the setting change/confirmation history process.

Note that, for example, when the main button 662 is pressed after a password is input on the password request screen, the host control circuit 2100 determines whether the input password is appropriate. If the entered password is inappropriate or if the main button 662 is pressed without entering a password, the authentication NG process in step S3103 described above is executed. Then, only when the correct password is input and, for example, the main button 662 is pressed, a setting change/confirmation history screen on which time information, operation type information, and setting value information are displayed is displayed. Can be done. This makes it possible to prevent the setting value history information from being viewed for fraudulent purposes.

The host control circuit 2100 performs a setting change/confirmation history screen display process in step S3120. At this time, a setting change/confirmation history screen (for example, see FIG. 119) is displayed in the display area of the display device 16, in which date and time data, operation type, and setting value are shown in association with each other.

After the setting change/confirmation history screen display process in step S3120, the host control circuit 2100 determines whether a page update operation has been performed (step S3130). If it is determined that a page update operation has been performed (YES in step S3130), the page update process is executed (step S3140), and then the process moves to step S3130. On the other hand, if the page update operation has not been performed (NO in step S3130), the process moves to step S3150.

Host control circuit 2100 determines whether "clear" has been determined in step S3150. When the operator presses the main button 662 with "Clear" selected (highlighted) on the setting change/confirmation history screen displayed in the display area of the display device 16 (for example, see FIG. 122), , the host control circuit 2100 determines that "clear" has been determined.

When the host control circuit 2100 determines that "clear" has been determined (YES in step S3150), the host control circuit 2100 executes a setting change/confirmation history data clearing process (step S3180), and moves to step S3180. The setting change/confirmation history data clearing process described above is a process for erasing the setting change history, setting confirmation history, and viewing history data stored in the subwork RAM 2100a. When the setting change/confirmation history data clearing process is executed, all the history data displayed in the display area of the display device 16 is erased (for example, see FIG. 123). On the other hand, if "clear" is not determined (NO in step S3150), the process moves to step S3170.

Host control circuit 2100 determines whether "return" has been determined in step S3170. When the operator presses the main button 662 with "Back" selected (highlighted) on the setting change/confirmation history screen displayed in the display area of the display device 16 (for example, see FIG. 119), , the host control circuit 2100 determines that "return" has been determined.

When the host control circuit 2100 determines that "return" has been determined (YES in step S3170), it executes the hall menu screen display process (step S3180) and ends the setting change/confirmation history process. On the other hand, if it is not determined to "return" (NO in step S3170), the process moves to step S3130 and continues the processing of step S3130.

FIG. 141 shows a setting change/confirmation history process that allows setting values to be confirmed on the hall menu screen displayed in the display area of the display device 16 in modification example 1 of the setting change/confirmation history process executed by the host control circuit 2100. It is a flow diagram showing an example of an operation procedure until a confirmation history screen is displayed. As shown in FIG. 141, in the pachinko gaming machine 1 according to the present embodiment, as a first step for viewing setting change/confirmation history information, when a setting change process or a setting confirmation process is executed, a hall menu Display the screen. As described above, the setting change process can be executed by turning on the setting key 328, pressing the backup clear switch 330, and turning on the power switch 35 while the power is not turned on. Further, the setting confirmation process can be executed by turning on the setting key 328 while the power is not turned on. The setting key switch signal can be turned on by turning the setting key 328 in one direction, and the setting key switch signal can be turned off by turning it in the opposite direction (returning to the original position). It is configured to allow.

As a second step, the pachinko gaming machine 1 selects and determines "setting change/confirmation history" in the hall menu on the hall menu screen (for example, see FIG. 111). ” is highlighted, and a preview of the settings change/confirmation history screen containing the settings change/confirmation history information with only the date/time data and operation type (corresponding operation type among settings change, confirmation, and viewing) displayed. Display the screen (see Figure 111) (setting values are not displayed).

As a third step, the pachinko gaming machine 1 requests the input of a password (see FIGS. 138 and 139), and determines whether the input password is appropriate.

As a fourth step, if the password input in the third step is correct, the pachinko gaming machine 1 will provide setting value information, more specifically, date and time data and operation type (among setting change, confirmation, and viewing). A setting change/confirmation history screen (for example, see FIG. 126) in which the corresponding operation type) and setting values are associated is displayed in the display area of the display device 16.

Therefore, a person who can use and operate the setting key 328 (person with authority) cannot change the settings or change the settings on the setting change/confirmation history screen (see FIG. 119) that is displayed after the first to fourth steps above. By viewing the confirmation history, you will be able to see at a glance the history of setting changes, confirmation of setting changes, and viewing of setting changes and confirmations and the corresponding setting values that define the ball payout rate. . It should be noted that the person with authority is a person who has been given authority to change settings, confirm changes in settings, etc., and means a manager of a hall or the like. Hereinafter, the "authorized person" may also be referred to as the "administrative authority person."

As described above, the pachinko game machine 1 constituting the game machine according to the present invention includes a display device 16 that displays various images, a group of operation buttons 66 such as a main button 662 and a select button 664, and controls related to the game. The control unit includes a main CPU 101 that is a control unit that controls display, and a host control circuit 2100 that is a display control unit that controls display on the display device 16. The display control section includes a setting switch 332 that is a setting means that enables the display, and a data transmitting means that transmits various data to the host control circuit 2100, and a receiving means that receives various data from the data transmitting means. The main CPU 101 includes a sub-work RAM 2100a that functions as a backup memory that can store and retain written information even in a power-off state, and an RTC 209 that measures date and time. and the setting value to the host control circuit 2100, and if the data received by the data receiving means is a setting change or setting confirmation, the host control circuit 2100 sends the setting change or setting confirmation or setting value to the subwork RAM 2100a. and a setting display function that stores date and time data from the RTC 209 as setting change/confirmation history information, and displays setting changes or setting confirmations and date and time data stored in the subwork RAM 203 on the display device 16. The setting value stored in the sub-work RAM 2100a is displayed when the main button 662 is operated while the confirmation and date/time data are displayed.

With this configuration, setting changes or setting confirmations, setting values, and date and time data from the RTC 209 are stored in the subwork RAM 2100a as setting change/confirmation history information. When button 662 is operated, setting values stored in sub-work RAM 2100a can be displayed. Therefore, when "setting change/confirmation history" in the hall menu is selected, it is possible to check each history regarding setting values, and it is possible to determine whether or not unauthorized setting changes or setting confirmations have been made. It becomes like this.

Furthermore, the pachinko gaming machine 1 according to the present embodiment may have a configuration in which the date and time data on which the setting value is received is acquired from the RTC 209, and the setting value, the date and time data, and information representing a setting change are stored in association with each other. good.

With this configuration, the changed setting value, changed date and time data, and information representing the setting change are stored in association with each other, so that an authorized person can identify the date and time when the setting value was changed. This makes it possible to identify fraud, such as changing setting values, if it has been committed.

Furthermore, the pachinko gaming machine 1 according to the present embodiment acquires the date and time when information indicating that the setting value has been confirmed is received from the RTC 209, and stores the date and time data and the information indicating the setting confirmation in association with each other. Good too.

With this configuration, the date and time data when setting values were confirmed and the information representing the setting confirmation are stored in association with each other, so an authorized person can specify the date and time when setting values were confirmed, and If fraud, such as checking a value, has been carried out, it becomes possible to identify the fraud.

Furthermore, in the pachinko gaming machine 1 according to the present embodiment, when setting changes or setting confirmations, setting values, and date and time data are displayed among the setting change/confirmation history information of the sub-work RAM 2100a, the displayed The configuration may be such that date and time data is stored in the sub-work RAM 2100a as a viewing history, and the viewing history is displayed on the display device 16.

With this configuration, when setting changes or setting confirmations, setting values, and date and time data are displayed in the setting change/confirmation history information, the displayed date and time data is stored in the subwork RAM 2100a as the viewing history, You can view your browsing history. Therefore, when "Setting change/confirmation history" is selected in the hall menu where setting values are not displayed, in addition to displaying setting changes or setting confirmations, setting values, and date and time data among setting change/confirmation history information, Since the history can be displayed, it can be determined whether or not the viewing history for setting changes or setting confirmations has been viewed for fraudulent purposes such as cheating.

With the above configuration, in this embodiment, it is possible to save and display setting change/confirmation history information that associates setting changes or setting confirmations, setting values, and date and time data, so that each history related to setting values can be saved and displayed. It is possible to provide a pachinko game machine 1 that can confirm whether or not an unauthorized setting change or setting confirmation has been made.

Further, the pachinko game machine 1 constituting the game machine according to the present invention includes a display device 16 that displays various images, operation units such as a main button 662 and a select button 664, and a control unit that performs control related to the game. It includes a main CPU 101 and a host control circuit 2100 that is a display control unit that controls the display of the display device 16, and the control unit has settings that enable changing or checking of setting values (for example, settings 1 to 6). The display control unit includes a setting switch 332 as a means, and a data transmitting means for transmitting various data to the host control circuit 2100, and a receiving means for receiving various data from the data transmitting means, and The main CPU 101 is equipped with a sub-work RAM 2100a that can store and hold information written even when the computer is in use, and an RTC 209 that measures date and time. If the data received by the data receiving means is a setting change or setting confirmation, the host control circuit 2100 sends the setting change or setting confirmation, setting value, and date and time data from the RTC 209 to the subwork RAM 2100a. The display device 16 has a setting display function that displays setting change/confirmation history information stored in the subwork RAM 2100a as confirmation history information on the display device 16. , the date and time data is stored in the sub-work RAM 2100a as a viewing history, and the viewing history is displayed on the display device 16.

With this configuration, when the setting change/confirmation history information of the subwork RAM 2100a is displayed, the displayed date and time data is stored as the viewing history in the subwork RAM 2100a, and the viewing history is displayed in the display area of the display device 16. be able to. Therefore, it is not only possible to determine whether an unnatural operation has been performed, but also whether it is an opportunity to investigate fraudulent activity.

Furthermore, the pachislot machine according to the present embodiment acquires date and time data when setting change/confirmation history information is displayed on the display device 16 from the RTC 209, and stores the date and time data in association with information representing the viewing history. You can also use it as

With this configuration, the date and time data and information representing the viewing history are stored in association with each other, so it is possible to identify the date and time when information related to setting values was viewed, and to prevent fraud such as changing setting values. This makes it possible to identify fraud if it has been committed.

Furthermore, in the pachinko gaming machine 1 according to the present embodiment, when setting changes or setting confirmations, setting values, and date and time data are displayed among the setting change/confirmation history information of the sub-work RAM 2100a, the displayed The configuration may be such that date and time data is stored in the sub-work RAM 2100a as a viewing history, and the viewing history is displayed on the display device 16.

With this configuration, when setting changes or setting confirmations, setting values, and date and time data are displayed in the setting change/confirmation history information, the displayed date and time data is stored in the subwork RAM 2100a as the viewing history, The viewing history can be displayed on the display device 16. Therefore, when "Setting change/confirmation history" is selected in the hall menu where setting values are not displayed, in addition to displaying setting changes or setting confirmations, setting values, and date and time data among setting change/confirmation history information, Since the history can be displayed, it can be determined whether or not the viewing history for setting changes or setting confirmations has been viewed for fraudulent purposes such as cheating.

With the above-described configuration, in this embodiment, it is possible to save and display viewing history information that associates the viewing history of viewing setting change confirmation/history information with date and time data, thereby preventing unnatural operations regarding setting values. It is possible to provide a pachinko game machine 1 that can not only determine whether a fraudulent act has been committed, but also determine whether or not it is an opportunity to investigate a fraudulent act.

[10-24-2. Modification example 2 of setting change/confirmation history processing]
Next, modification example 2 of setting change/confirmation history processing will be described with reference to FIGS. 142 to 146.

The setting change/confirmation history process in the second modification of the setting change/confirmation history process has substantially the same basic configuration as that in the first modification except for the configuration of the authentication function. In the following, differences from Modification Example 1 will be explained in detail.

The pachinko game machine 1 according to the second modification of the setting change/confirmation history process is equipped with, for example, a slide switch as a volume adjustment means for adjusting the volume of the speaker 24, and has a plurality of volume positions (volume positions), for example, the volume "high". ”, “Medium”, and “Small”, as well as a plurality of volume positions in a predetermined order of operation, and the order of the switching operations is preset. If the order matches the order, the user is authenticated as a user with administrator privileges. Note that the volume adjusting means for adjusting the volume of the speaker 24 is not limited to a slide switch, and may be configured such that, for example, the volume is adjusted by rotating a jog dial, and the volume is determined by pressing the jog dial.

As described above, the pachinko gaming machine 1 according to the second modification of the setting change/confirmation history process has an authentication processing function that performs authentication based on the volume password corresponding to the change order of the volume position. In this second modification, for example, a control program to which the above authentication processing function is added is stored in the audio/LED control circuit 2200, and the host control circuit 2100 executes the authentication processing based on the volume password according to the control program.

FIG. 142 is a diagram showing a configuration example of the volume switch 108 that generates the volume password applied to the authentication process (see FIG. 143) in the second modification of the setting change/confirmation history process executed by the host control circuit 2100. be. The volume switch 108 is arranged, for example, in the circuit board of the sub-control circuit 200, and can be slid to set an initial setting value. For example, the volume switch 108 is set to one of three volume positions 603a, 603b, and 603c (hereinafter also referred to as volume positions 1, 2, and 3) corresponding to volume "low," "medium," and "high." In addition to the switching operation, the switching operation is also performed sequentially to a plurality of volume positions 1, 2, and 3 in a predetermined order of operations. Specifically, when setting the initial setting value, it can be set by sliding the volume switch 108 from "large" to "medium" to "small" to "medium". That is, the host control circuit 2100 constitutes a position detection unit that detects volume positions 1, 2, and 3 of the volume switch 108.

On the other hand, when setting a user with administrator authority (person with administrator authority), according to a prescribed administrator setting procedure, the volume switch 108 is operated in a different order from the initial setting, and a prescribed authentication operation is performed via multiple volume positions. A plurality of volume positions and the order of operations are stored in a memory by performing operations in a pattern. When administrator authority is required to view the change history of setting values, etc., the volume switch 108 is operated in a predetermined authentication operation pattern to enable viewing of the change history of setting values.

The authentication operation pattern may be, for example, an operation pattern representing a change in position from volume position 2 (volume "medium") to volume position 1 (volume "low") in FIG. 142, or from volume position 2 to volume position 3 (volume position 3). An operation pattern or the like representing a change in position to "loud" volume can be stored in advance.

Thereby, the host control circuit 2100 recognizes the operation pattern from the volume position information indicating each of the volume positions of the volume switch 108, and determines whether or not the operation pattern matches the preset authentication operation pattern. It is possible to determine whether or not the person

In this manner, in the second modification of the setting change/confirmation history process, the volume switch 108 functions as an operation unit for inputting a volume password corresponding to the operation pattern of the volume position. The volume switch 108 in the second modification of the setting change/confirmation history process is an operation unit that cannot be operated by the player, like the setting switch 332, setting key 328, power switch 35, and backup clear switch 330. On the other hand, for example, the main button 662, the select button 664, the firing handle 32, etc. are operation units that can be operated by the player.

FIG. 143 is a flowchart illustrating an example of the authentication process in the second modification of the setting change/confirmation history process executed by the host control circuit 2100. In this authentication process, "Setting change/confirmation history" is selected from the hall menu being displayed (see FIG. 110) in step S3006 of FIG. 115 (YES in step S3006), and "Setting change/confirmation history" is selected on the hall menu screen. The process is started by pressing the main button 662 while "History" is highlighted (see FIG. 111).

When this authentication process is started, the host control circuit 2100 performs a volume password request display process (step S3201) that displays a screen prompting the input of a volume password in the display area of the display device 16 where the hall menu screen is displayed. Execute.

FIG. 144 shows a password request screen displayed in the display area of the display device 16 when the setting change/confirmation history process is executed in the second modification of the setting change/confirmation history process executed by the host control circuit 2100. FIG. FIG. 145 is an example of a volume password request display screen displayed in the display area of the display device 16 in the second modification of the setting change/confirmation history process executed by the host control circuit 2100. As shown in FIGS. 144 and 145, in the volume password request display process of step S3201 in FIG. Please enter the password.The setting value will be displayed after entering the password.'' is displayed along with setting change/confirmation history information.

In this modification example 2, when the setting change/confirmation history process is started (the main button 662 is pressed while "setting change/confirmation history" is selected (highlighted) on the hall menu screen) For example, as shown in FIGS. 144 and 145, the volume password request screen is displayed while the hall menu screen is being displayed, but this is not necessarily the case. For example, when the settings change/confirmation history is started, the settings change/confirmation history screen displays only time information, operation type information, and setting value information (setting values are not displayed). You can display the volume password request screen while displaying the settings change/confirmation history screen, or change the volume password without displaying either the hall menu or the settings change/confirmation history screen. Only the password request screen may be displayed.

After displaying the volume password request display screen, the host control circuit 2100 continuously executes operation pattern acquisition processing for monitoring the change order of the volume position information of the volume switch 108, that is, the operation pattern (step S3202).

When volume position information is input during the input monitoring of the volume position information, the host control circuit 2100 extracts an operation pattern corresponding to the volume position information from the volume position information, and extracts a preset authentication operation pattern. It is determined whether the correct operation was performed based on whether the two match (step S3203). Here, if it is determined that the correct operation has been performed (YES in step S3203), the host control circuit 2100 executes the processing from step S3120 in FIG. 136.

On the other hand, if it is determined that the correct operation has not been performed (NO in step S3203), the host control circuit 2100 performs authentication NG display processing to display in the display area of the display device 16 that the authentication is NG. (Step S3204). Thereby, the host control circuit 2100 ends the authentication process and proceeds to the process of step S3110 in FIG. 136. In the authentication NG display process, a message such as "The volume password is incorrect. Please try again from the beginning" is displayed in the display area of the display device 16.

Although FIG. 142 shows an example in which the volume switch 108 having three volume positions is used as the operation switch according to the present invention, the operation switch is not limited to this. It may also be a switch that can assume different positions. In this case, the host control circuit 2100 is provided with a position detection function that can detect each volume position of the operation switch, and the position information (volume position information) detected by this position detection function is acquired, and the acquired order and subwork The setting change/confirmation history information stored in the sub-work RAM 2100a may be displayed on the condition that it matches a predetermined operation order stored in advance in the RAM 2100a.

FIG. 146 is a flow diagram illustrating an example of a setting value confirmation procedure for setting change/confirmation history information in modification example 2 of the setting change/confirmation history process executed by the host control circuit 2100. As shown in FIG. 146, in the second modification of the setting change/confirmation history process, as the first step for confirming the setting value of the setting change/confirmation history information, when the setting change process or setting confirmation process is executed, Display the menu screen. As described above, the setting change process can be executed by turning on the setting key 328, pressing the backup clear switch 330, and turning on the power switch 35 while the power is not turned on. Further, the setting confirmation process can be executed by turning on the setting key 328 while the power is not turned on. The setting key switch signal can be turned on by turning the setting key 328 in one direction, and the setting key switch signal can be turned off by turning it in the opposite direction (returning to the original position). It is configured to allow.

As a second step, the pachinko gaming machine 1 selects and determines "setting change/confirmation history" in the hall menu on the hall menu screen (for example, see FIG. 111). ” is highlighted, and a preview of the settings change/confirmation history screen containing the settings change/confirmation history information with only the date/time data and operation type (corresponding operation type among settings change, confirmation, and viewing) displayed. Display the screen (see Figure 111) (setting values are not displayed).

As a third step, the pachinko game machine 1 requests input of a volume password (see FIGS. 144 and 145), captures the input volume password, and determines whether the captured volume password is appropriate. The appropriateness of the volume password is determined by comparing the imported volume password with the authentication operation pattern (authentication password). If the two match and authentication is OK, the volume password is determined to be appropriate. to decide.

As a fourth step, if the volume password input in the third step is correct, the pachinko gaming machine 1 will provide setting value information, more specifically, date and time data and operation type (among settings change, confirmation, and viewing). A setting change/confirmation history screen (for example, see FIG. 126) in which the corresponding operation type) and the setting value are associated is displayed in the display area of the display device 16.

As described above, the pachinko game machine 1 constituting the game machine according to the present invention includes a display device 16 that displays various images, a main button 662 and a select button 664 that are operation units that receive at least operations from a player. It includes a non-gaming operation section that is not operated by the player, a main CPU 101 that is a control section that performs control related to games, and a host control circuit 2100 that is a display control section that controls the display of the display device 16. , the control unit includes a setting switch 332 that allows changing or checking setting values (for example, settings 1 to 6), and data transmission means that transmits various data to the display control unit, and the display control unit includes: The main CPU 101 includes a receiving means for receiving various data from a data transmitting means, a sub-work RAM 2100a capable of storing and retaining written information even in a power-off state, and an RTC 209 for measuring date and time. The transmitting means transmits the setting change or setting confirmation and the set value to the host control circuit 2100, and the host control circuit 2100 stores the data in the subwork RAM 2100a when the data received by the data receiving means is a setting change or setting confirmation. Equipped with a setting display function that stores settings change or setting confirmation, setting values, and date and time data from the RTC 209 as setting change/confirmation history information, and displays the setting change/confirmation history information stored in the subwork RAM 2100a on the display device 16. , the setting change/confirmation history information stored in the sub-work RAM 2100a is displayed on the condition that the non-gaming operation sections are operated in a predetermined order.

With this configuration, the setting change/confirmation history information stored in the sub-work RAM 2100a can be displayed on the condition that the non-gaming operation sections are operated in a predetermined order. Therefore, only authorized persons who know the predetermined operation order can save and display setting change/confirmation history information, making it easy to determine whether or not unnatural operations have been performed regarding setting values. It will be possible to determine whether or not it is an opportunity to investigate misconduct.

Furthermore, when the setting change/confirmation history information of the sub-work RAM 2100a is displayed, the pachinko gaming machine 1 according to the present embodiment stores the displayed date and time data as the viewing history in the sub-work RAM 2100a, and It is also possible to display the browsing history on the screen.

With this configuration, when setting change/confirmation history information of the subwork RAM 2100a is displayed, the displayed date and time data can be stored in the subwork RAM 2100a as a viewing history, and the viewing history can be displayed on the display device 16. . Therefore, it is not only possible to determine whether an unnatural operation has been performed, but also whether it is an opportunity to investigate fraudulent activity.

Furthermore, in the pachinko gaming machine 1 according to the present embodiment, the non-gaming operation section may be configured to be an operation switch that adjusts the volume, for example, the volume switch 108.

With this configuration, authentication can be performed using an operation order known only to an authorized person, so it is not necessary to add an operation switch to identify an authorized person, and costs can be reduced. Note that this order of operation is shown when the pachinko game machine 1 is delivered to the hall, and is used only by those with authority when changing or confirming the settings.

Further, in the pachinko game machine 1 according to the present embodiment, the operation switch is a switch that can take at least three or more arbitrary positions, and the host control circuit 2100 controls each volume position of the operation switch. The device further includes a detectable position detection function, and the setting display function acquires volume position information detected by the position detection function, and matches the order of the acquired volume position information with a predetermined operation order stored in advance. The configuration may be such that setting change/confirmation history information stored in the sub-work RAM 2100a is displayed on the condition that.

With this configuration, the operation order of three or more arbitrary volume positions is stored in advance as a predetermined operation order, and the operation order is made known to the authorized person in advance, so that the authorized person can be identified. There is no need to add any operation switches, and authentication can be performed using an operation order known only to an authorized person.

With the above-described configuration, in this embodiment, only an authorized person can save and display the setting change/confirmation history information, so it is possible to determine whether or not an unnatural operation regarding the setting value has been performed. It is possible to provide a pachinko game machine 1 that can determine whether or not it is an opportunity to investigate fraudulent activity.

As described above, in the pachinko gaming machine 1 according to the present embodiment, when displaying setting change/confirmation history information, only a person who has authority regarding setting values in the hall can be authenticated by operating the volume switch 108. Although the configuration has been explained, when displaying setting change/confirmation history information, as in the pachinko gaming machine 1 according to modification example 3 of setting change/confirmation history processing described below, from the input section of the pachinko gaming machine 1. It may also be configured to authenticate using an input password.

[10-24-3. Modification example 3 of setting change/confirmation history processing]
Next, modification example 3 of setting change/confirmation history processing will be described with reference to FIGS. 147 to 154.

FIG. 147 is a diagram illustrating a configuration example of the gaming system 210 according to modification example 3 of the setting change/confirmation history process executed by the host control circuit 2100. This gaming system 210 is configured to include a pachinko gaming machine 1A, a mobile wireless communication terminal 220, and a server device 240 arranged in a network 230. In the gaming system 210, as will be described later, the pachinko gaming machine 1A, the mobile wireless communication terminal 220, and the server device 240 cooperate to perform authentication processing related to setting change and confirmation of confirmation history information.

In the gaming system 210, the pachinko gaming machine 1A has, in addition to the functions of the pachinko gaming machine 1 described above, a function of generating a two-dimensional code including setting change/confirmation history information and a URL (Uniform Resource Locator); It has a function of displaying the code in the display area of the display device 16A (see FIG. 150). Specifically, the setting change/confirmation history information included in the two-dimensional code is information content as displayed on the setting change/confirmation history screen shown in FIG. 119, for example, and includes setting values. The sub-CPU in the pachinko gaming machine 1A constitutes a generation means for generating a two-dimensional code according to the present invention.

The portable wireless communication terminal 220 is a mobile communication terminal such as a smart phone, and includes a control section 221, a display operation section 222, a camera section (not shown), and the like. The display/operation unit 222 has the functions of a display unit and an operation unit, and is configured with a touch panel or the like. The camera unit is a functional unit that reads (takes an image of) the two-dimensional code 161a etc. (see FIG. 150) displayed in the display area of the display device 16A of the pachinko gaming machine 1A. The display/operation section 222 and the camera section constitute an operation/display section and an imaging means in the present invention, respectively.

The control unit 221 includes a CPU, a storage device (flash memory, microSD memory card, etc.), a RAM, a communication circuit, etc., and the CPU controls various operations according to a control program stored in the storage device or RAM, for example. conduct. In this embodiment, the control unit 221 includes an extraction unit that analyzes a captured two-dimensional code and extracts setting change/confirmation history information and a URL, and a password input screen (see the figure below) that inputs a password into the operation display unit 222. 153); and an authentication result acquisition unit that transmits the input password entered on the password input screen to the server device 240 based on the above URL and obtains the authentication result notified from the server device 240. , has a history information display control unit that displays setting change/confirmation history information including setting values on the display operation unit 222 when the acquired authentication result is correct. The extraction unit, display control unit, authentication result acquisition unit, and history information display control unit are functions that can be realized by a CPU that operates according to a dedicated application installed in advance in the storage device or the like. The extraction unit, input screen display control unit, authentication result acquisition unit, and history information display control unit, which are the components of the control unit 221 according to the present embodiment, are the extraction means, the input screen display control unit, and the authentication result in the present invention, respectively. It constitutes an acquisition means and a history information display control means.

The server device 240 is realized by a computer, and has a function of managing a dedicated site for the authentication service identified by the above URL, receives an input password from the mobile wireless communication terminal 220 that accesses the above URL, and inputs a password set in advance. It is provided with an authentication service function, etc., which determines whether the password is correct by comparing it with the password, and notifies the portable wireless communication terminal 220 of the authentication result. The server device 240 constitutes an authentication means in the present invention.

FIG. 148 is a flowchart showing an example of a setting change/confirmation history process in the pachinko gaming machine 1A that constitutes the gaming system 210 according to the third modification. This setting change/confirmation history process is performed by selecting "Setting change/confirmation" from among the multiple hall menu items displayed on the hall menu screen (for example, see FIG. 109) displayed in the display area of the display device 16A of the pachinko gaming machine 1A. The process is started on the condition that the main button 662 is pressed while "Confirmation History" is selected and "Setting Change/Confirmation History" is highlighted on the hall menu screen (for example, see FIG. 111).

In addition, in the setting change/confirmation history processing described above with reference to FIGS. 117 and 118, if no processing is performed within a predetermined time (for example, 30 seconds), the hall menu screen (for example, see FIG. 110) It has been explained that the timing process (see step S3052 in FIG. 117, etc.) is performed in order to display the . In this modification 3 as well, when a time measurement process is performed in the same way as the setting change/confirmation history process described above with reference to FIGS. 117 and 118, and no process is performed within a predetermined time (for example, 30 seconds), Although the hall menu screen may be displayed on the screen, the description of the third modification omits the description of the timekeeping process.

When this setting change/confirmation history process starts, the sub CPU reads the setting change/confirmation history information from the work RAM, and creates a two-dimensional code containing this setting change/confirmation history information and the URL of the dedicated site for the authentication service. 161a (see FIG. 150) is performed (step S3301). Next, the host control circuit 2100 performs a two-dimensional code display process to display the setting change/confirmation history information read in step S3301 and the generated two-dimensional code 161a in the display area of the display device 16A in the manner shown in FIG. 150, for example. (Step S3302).

After executing the two-dimensional code display process in step S3302, the host control circuit 2100 accepts a data clear request, a cursor movement (page break) request, and a process return request based on the operation of the main button 662 and select button 664. Transition to possible state. The main button 662 is a button for requesting processing return. The select button 664 is a button for requesting cursor movement (page change). Furthermore, by operating the main button 662 and the select button 664 together, a data clear request can be issued.

After transitioning to the receivable state, the host control circuit 2100 performs steps S3303 to S3305. Note that in FIG. 148, the processes from step S3056 to step S3064 shown in FIG. 117 are omitted, but in order to perform these processes, the process shown in FIG. The processing of steps S3056 to S3064 shown in FIG.

In FIG. 148, after the two-dimensional code display process in step S3302, the host control circuit 2100 determines in step S3303 whether "clear" has been determined. When the operator presses the main button 662 with "Clear" selected (highlighted) on the setting change/confirmation history screen displayed in the display area of the display device 16 (for example, see FIG. 150), The host control circuit 2100 determines that "clear" has been determined.

When the host control circuit 2100 determines that "clear" has been determined (YES in step S3303), the host control circuit 2100 executes a setting change/confirmation history data clearing process (step S3304), and moves to step S3306. The setting change/confirmation history data clearing process described above is a process for erasing the setting change history, setting confirmation history, and viewing history data stored in the subwork RAM 2100a. When the setting change/confirmation history data clearing process is executed, all the history data displayed in the setting change/confirmation history display area of the display area of the display device 16 is erased (see FIG. 123). On the other hand, if "clear" is not determined (NO in step S3303), the process moves to step S3305.

In step S3305, the host control circuit 2100 determines whether "return" has been determined. When the operator presses the main button 662 with "Back" selected (highlighted) on the setting change/confirmation history screen displayed in the display area of the display device 16 (for example, see FIG. 150), , the host control circuit 2100 determines that "return" has been determined.

When the host control circuit 2100 determines that "return" has been determined (YES in step S3305), it executes the hall menu screen display process (step S3306), and ends the setting change/confirmation history process. On the other hand, if "return" is not determined (NO in step S3305), the process moves to step S3303 and continues the processing from step S3303 onwards.

As described above, in this embodiment, when the host control circuit 2100 determines that "clear" has been determined (YES in step S3303), the setting change/confirmation history displayed together with the two-dimensional code 161a (see FIG. 150) The information may also be cleared. In this case, the pachinko gaming machine 1A is displaying the two-dimensional code 161a, but since the authentication result has not been obtained, the setting change/confirmation history information cannot be cleared regardless of whether the authentication result is OK or NG. It is now possible to do so.

FIG. 149 is a flowchart showing an example of setting change/confirmation history processing in the portable wireless communication terminal 220 and the server device 240 of the gaming system 210 according to the third modification. This process is started on the condition that the two-dimensional code 161a displayed on the display area of the display device 16A (for example, a liquid crystal display device) of the pachinko game machine 1A is photographed with the portable wireless communication terminal 220.

When the two-dimensional code 161a is photographed with the portable wireless communication terminal 220, the control section 221 reads the image data obtained by the photographing, and displays two images on the display operation section 222 based on the image data in the manner shown in FIG. 152, for example. Two-dimensional code reading and display processing for displaying the dimensional code 222a is performed (step S3401).

Subsequently, in the mobile wireless communication terminal 220, the control unit 221 analyzes the read two-dimensional code, extracts the setting change/confirmation history information and URL contained therein, and temporarily stores the information in a predetermined storage area in the RAM, for example. A two-dimensional code acquisition process to be held in a specific manner is executed (step S3402). Next, the control unit 221 accesses the dedicated site of the authentication service based on the above URL, displays a password input screen (see FIG. 153), and executes a password input display process to accept a password (step S3403).

After executing the password input display process in step S3403, the control unit 221 of the portable wireless communication terminal 220 cooperates with the server device 240 and performs the password authentication process through the following steps S3404 and S3405.

In the password authentication process, the control unit 221 of the mobile wireless communication terminal 220 first monitors whether a password has been entered in the password display field 222c (see FIG. 153) (step S3404), and then presses the button from the numeric keypad 222b. Performs processing to accept password input. Here, if a password is input (YES in step S3404), control unit 221 transmits the input password to server device 240.

The server device 240 compares the password sent from the portable wireless communication terminal 220 with a registered password registered in advance, and determines whether the authentication is OK or not depending on whether the two match. The server device 240 notifies the mobile radio communication terminal 220 of the above determination result. In this way, in this embodiment, only the authentication is performed by the server device 240. In other words, the server device 240 returns only the authentication result to the mobile wireless communication terminal 220.

In response, after transmitting the input password accepted in step S3404, the control unit 221 of the mobile wireless communication terminal 220 waits for notification of the authentication result from the server device 240, and determines whether the notified authentication result is OK or NG. Depending on whether the password is correct or not, it is determined whether the password is correct (step S3405).

Here, if it is determined that the password is incorrect (NO in step S3405), the control unit 221 performs authentication NG display processing to display a message etc. indicating that the password is NG on the display operation unit 222 ( Step S3410), and then the process ends. In the authentication NG display process, a message such as "Your password is incorrect. Please try again from the beginning" is displayed in the message field 222d.

On the other hand, if it is determined that the password is correct (YES in step S3405), the control unit 221 sets the setting change/confirmation history information temporarily held in step S3402 to be displayed on the display operation unit 222. Change/confirmation history display processing is performed (step S3406). In this setting change/confirmation history display process, the control unit 221 displays information for display in which the setting change/confirmation history information held in step S3402 is embedded (arranged) in accordance with a preset display format. Based on this display information, setting change/confirmation history information is displayed on the display operation unit 222 (see FIG. 154).

FIG. 150 is a diagram showing an example of a setting change/confirmation history screen including a two-dimensional code in the pachinko gaming machine 1A of the gaming system 210 according to modification 3.

As shown in FIG. 150, in the pachinko gaming machine 1A, the host control circuit 2100 displays the setting change/confirmation history in the display area of the display device 16A of the pachinko gaming machine 1A in the two-dimensional code display process (step S3302) of FIG. 148. A setting change/confirmation history screen including information and the two-dimensional code 161a is displayed. As described above, the two-dimensional code 161a displayed on the setting change/confirmation history screen includes the setting change/confirmation history information being displayed in the display area of the display device 16A and the URL of the dedicated site for the authentication service. There is.

Note that when displaying the two-dimensional code 161a in the two-dimensional code display process of step S3302 (see FIG. 148), the host control circuit 2100 displays, for example, "*Two-dimensional code on a mobile terminal" in the display area of the display device 16A. It may also be configured to display a message prompting the user to switch to the authentication service, such as "Please scan and access the authentication service."

FIG. 151 is a flow diagram illustrating an example of a setting value confirmation procedure for setting change/confirmation history information in the gaming system 210 according to modification 3. This setting value confirmation procedure will be explained at the end of this embodiment for convenience.

FIG. 152 is a diagram showing an example of a two-dimensional code display screen on the mobile wireless communication terminal 220 of the gaming system 210 according to the third modification. The portable wireless communication terminal 220 displays a two-dimensional code 222a as shown in FIG. 152 on the display operation unit 222 in the two-dimensional code reading and displaying process of S1101.

FIG. 153 is a diagram showing an example of a password input screen on the mobile wireless communication terminal 220 of the gaming system 210 according to the third modification. In the password input display process in step S3403 (see FIG. 149), the mobile wireless communication terminal 220 accesses the URL and displays the password input screen shown in FIG. 153 on the display operation unit 222.

As shown in FIG. 153, the password input screen includes a numeric keypad 222b having keys "0" to "9", "*", and "#", and a password display field 222c that displays the password input using the numeric keypad 222b. A message field 222d is displayed. The message field 222d displays a message prompting the user to enter a password, such as "*Please enter your password. After entering the password, the setting value will be displayed." In the portable wireless communication terminal 220, on the password input screen shown in FIG. 153, a password converted to hidden characters "*" can be displayed in the password display field 222c in which the password has been entered by operating the numeric keypad 222b.

FIG. 154 is a diagram showing an example of a setting change/confirmation history screen 222g in the mobile wireless communication terminal 220 of the gaming system 210 according to Modification 3. As shown in FIG. 154, the setting change/confirmation history screen 222g displays the setting change/confirmation history information temporarily held in S1102, for example, the same as the setting change/confirmation history screen shown in FIG. It is displayed in the format. That is, in FIG. 154, in the setting change/confirmation history information, setting values are displayed in correspondence with the setting change/confirmation date and time.

In the portable wireless communication terminal 220, the dedicated application installed in advance has the above-mentioned display format, the display format of the setting change/confirmation history screen 222g shown in FIG. Supported. As a result, during the setting change/confirmation history processing in FIG. The page transitions to a receptive state in which a page update request based on the operation of the button 222e and the select button 222f can be accepted.

After transitioning to the receivable state, the control unit 221 of the mobile wireless communication terminal 220 determines whether a page update operation has been performed (step S3407). To determine whether or not a page update operation has been performed, when it is determined that the select button 222f has been operated and the last row has been reached, it is determined that a page update operation has been performed (YES in step S3407), and the page update operation is determined to have been performed. Update processing is executed (step S3408). Here, as long as it is determined that the select button 222f has been operated and a page update operation has been performed (that is, as long as it is determined that the select button 222f has been operated and the last line has been reached), the page scrolling continues. A page update process is performed to update the page (step S3408).

If the control unit 222 determines that the page update operation has been stopped (NO in step S3407), that is, if it determines that the operation of the select button 222f has been stopped and the determination button 222e has not been pressed, the process moves to step S3409. If it is determined in this step S3409 that "return" has been determined (YES in step S3071), the control unit 222 executes the hall menu screen display process (step S3410) and ends the setting change/confirmation history process. On the other hand, if it is determined that "return" has not been determined (NO in step S3409), the control unit 222 returns to step S340.

In addition, in the gaming system 210 according to this embodiment, the pachinko gaming machine 1A converts the setting change/confirmation history information as so-called raw data into a two-dimensional code and displays it in the display area of the display device 16A (Fig. 148 (see steps S3301 and S3302), a process of photographing the two-dimensional code displayed in the display area of the display device 16A of the pachinko gaming machine 1A on the mobile wireless communication terminal 220 side and returning the setting change/confirmation history information to raw data. (See steps S3401 and S3402 in FIG. 149).

On the other hand, many mobile communication terminals in recent years are equipped with a function to read and analyze two-dimensional codes as standard equipment.

Regarding this point, in the gaming system 210 according to the present embodiment, a dedicated application is installed on the mobile wireless communication terminal 220, and this dedicated application enables display in the same display format as the pachinko gaming machine 1A side.

In other words, on a mobile communication terminal that does not have a dedicated application installed, even if the setting change/confirmation history information can be viewed as raw data, it cannot be viewed in the same display format as on the pachinko machine 1A side. Therefore, it is difficult to recognize setting change/confirmation history information.

Therefore, in this embodiment, by installing and using a dedicated application on the mobile wireless communication terminal 220, sufficient confidentiality is achieved such that only authorized persons can view setting change/confirmation history information with setting values. can be ensured.

As described above, in this embodiment, when the two-dimensional code is read, all the data obtained is imported into the mobile wireless communication terminal 220, but the data is displayed as shown in FIG. 154 according to the display format of the dedicated application. will be displayed. Therefore, unless you have a dedicated application that has the display format, even if you read it with a general-purpose barcode reader, you will not be able to understand what kind of display the character string read from the two-dimensional code is. A certain level of confidentiality can be ensured. The application is distributed at the time of delivery of the pachinko gaming machine 1A, and can only be obtained by authorized persons.

In the present embodiment, the password is authenticated by receiving a notification of the authentication result from the server device 240, and determining whether the password is correct or not depending on whether the notified authentication result is OK or NG. However, the present invention is not limited to this. , the portable wireless communication terminal 220 may receive the password from the server device 240 and determine whether the input password is correct by determining whether the input password matches the password received from the server device 240, or If you want to further ensure confidentiality, the pachinko gaming machine 1A encrypts the setting change/confirmation history information and then generates and displays a two-dimensional code, and the dedicated application installed on the mobile wireless communication terminal 220 encrypts the setting change/confirmation history information. A configuration may also be adopted in which a decryption function for setting change/confirmation history information corresponding to the above encryption is added.

Next, a procedure for confirming the setting value of the setting change/confirmation history information in the gaming system 210 according to this embodiment will be explained with reference to the flowchart of FIG. 151.

As shown in FIG. 151, as a first procedure for confirming the setting value of the setting change/confirmation history information in the gaming system 210 according to the present embodiment, the pachinko gaming machine 1A executes a setting change process or a setting confirmation process. Display the hall menu screen when As described above, the setting change process can be executed by turning on the setting key 328, pressing the backup clear switch 330, and turning on the power switch 35 while the power is not turned on. Further, the setting confirmation process can be executed by turning on the setting key 328 while the power is not turned on. The setting key switch signal can be turned on by turning the setting key 328 in one direction, and the setting key switch signal can be turned off by turning it in the opposite direction (returning to the original position). It is configured to allow.

As a second step, the pachinko gaming machine 1A selects and determines "setting change/confirmation history" in the hall menu on the hall menu screen (for example, see FIG. 111). ” is highlighted, and a preview of the settings change/confirmation history screen containing the settings change/confirmation history information with only the date/time data and operation type (corresponding operation type among settings change, confirmation, and viewing) displayed. Display the screen (see Figure 111) (setting values are not displayed).

As the third step, the pachinko gaming machine 1A is operated as the main machine with "setting change/confirmation history" selected (highlighted) on the preview screen of the setting change/confirmation history screen (see Figure 111). When the button 662 is pressed, a two-dimensional code containing the setting change/confirmation history information and URL held in the sub-work RAM 2100a is generated, and the two-dimensional code is displayed together with the setting change/confirmation history information (Fig. 150 reference).

As a fourth step, the mobile wireless communication terminal 220 photographs the two-dimensional code displayed on the pachinko gaming machine 1A (see FIG. 152). After photographing the two-dimensional code, the mobile wireless communication terminal 220 extracts the setting change/confirmation history information and URL included in the two-dimensional code.

As a fifth step, the mobile wireless communication terminal 220 accesses a dedicated site for the authentication service based on the URL extracted in the third step, and enters a password from the password input screen (see FIG. 153) provided by this dedicated site. Make input.

This password is, for example, a password disclosed in an instruction manual or the like by the manufacturer of the gaming system 210 and registered in association with the gaming system 210 or each pachinko gaming machine 1A. At the dedicated site, the server device 240 receives the input password from the mobile wireless communication terminal 220, and performs password authentication by comparing it with the registered password. Here, if the authentication is OK, the server device 240 notifies the portable wireless communication terminal 220 to that effect.

As a sixth step, if the authentication is OK in the fifth step, the mobile wireless communication terminal 220 displays the setting change/confirmation history information extracted in the fourth step on a screen in a predetermined display format (Fig. 154). (Reference) is displayed on the display operation section 222 with the contents including the set value. Thereby, the administrator who has entered the password can confirm this setting change/confirmation history information along with the setting values on the screen displayed on the display/operation unit 222 of the mobile wireless communication terminal 220.

As described above, the pachinko game machine 1A according to the present embodiment includes a display device 16A that displays various images, a main button 662 and a select button 664 that are operation units that accept various operations, and a control unit that performs controls related to the game. The host control circuit 2100 is a display control unit that controls the display of the display device 16A, and the control unit can change or confirm setting values (for example, settings 1 to 6). a setting switch 332 to enable the data to be sent to the display controller, and a data transmitter for transmitting various data to the display controller. The main CPU 101 is equipped with a sub-work RAM 2100a capable of storing and retaining information, and an RTC 209 that measures date and time. When the data received by the data receiving means is a setting change or setting confirmation, the host control circuit 2100 stores the setting change or setting confirmation, setting value, and date and time data from the RTC 209 in the subwork RAM 2100a as setting change/confirmation history information. and has a setting display function that displays setting change/confirmation history information stored in the sub-work RAM 2100a in the display area of the display device 16A, and a state in which setting changes or setting confirmation and date and time data are displayed by the setting display function. It has a configuration in which setting change/confirmation history information is displayed as a two-dimensional code when the main button 662, which is the operation section, is operated.

With this configuration, setting changes or setting confirmations, setting values, and date and time data from the sundial and time means are stored in the subwork RAM 2100a as setting change/confirmation history information, so that setting changes or setting confirmations and date and time data are displayed. When the main button 662 is operated, the setting change/confirmation history information stored in the sub-work RAM 2100a can be displayed as a two-dimensional code. Therefore, if the portable wireless communication terminal 220 reads the two-dimensional code and allows display after password authentication, only the authorized person who knows the predetermined password can save and display the setting change/confirmation history information. Therefore, it is not only possible to determine whether or not an unnatural operation regarding the setting value has been performed, but also whether or not there is an opportunity to investigate fraudulent activity.

In addition, in the pachinko gaming machine 1A according to the present embodiment, when setting change/confirmation history information of the sub-work RAM 2100a is displayed by the setting display function, the host control circuit 2100 uses the displayed date and time data as the viewing history. The browsing history may be stored in the sub-work RAM 2100a and displayed in the display area of the display device 16A.

With this configuration, when setting change/confirmation history information of the subwork RAM 2100a is displayed, the displayed date and time data is stored in the subwork RAM 2100a as a viewing history, and the viewing history is displayed in the display area of the display device 16A. be able to. Therefore, it is not only possible to determine whether an unnatural operation has been performed, but also whether it is an opportunity to investigate fraudulent activity.

Further, the pachinko gaming machine 1A according to the present embodiment performs mobile wireless communication based on information from a predetermined server device 240 when the two-dimensional code displayed by the display control function is read by the mobile wireless communication terminal 220. A configuration may be adopted in which setting change/confirmation history information is displayed on the terminal 220.

With this configuration, when the two-dimensional code displayed by the display control function is read by the mobile wireless communication terminal 220, information from the predetermined server device 240, for example, a predetermined password, is sent to the mobile wireless communication terminal 220. Setting change/confirmation history information can be displayed on the portable wireless communication terminal 220 on the condition that the input password matches the password. Therefore, since authentication can be performed using a password known only to an authorized person, there is no need to add input means for identifying an authorized person to the pachinko gaming machine 1A, and costs can be reduced. Note that this password is shown when the pachinko gaming machine 1A is delivered to the hall, and is used only by authorized persons when changing or confirming the settings.

Furthermore, the gaming system 210 according to the present embodiment includes the pachinko gaming machine 1A described above and a server device 240 that is connected to the network 230 and manages a site for authentication. The server device 240 further has a generation function that generates a two-dimensional code for the setting change/confirmation history information and the site URL stored in the work RAM 2100a, and the server device 240 combines the password from the mobile wireless communication terminal 220 with a preset password. The portable radio communication terminal 220 includes a display operation section 222 having display and operation functions, and a display area of the display device 16A. A camera unit that captures an image of the displayed two-dimensional code, an extraction unit that analyzes the captured two-dimensional code and extracts setting change/confirmation history information and URL, and an input screen that displays a password input screen for entering a password. a display control unit, an authentication result acquisition unit that transmits the password entered on the password input screen to the server device 240 based on the URL and acquires the authentication result notified from the server device 240, and when the acquired authentication result is correct, This configuration includes a history information display control section that displays setting change/confirmation history information on the display operation section 222.

With this configuration, the gaming system according to the present embodiment reads a two-dimensional code displayed by the display control function of the pachinko gaming machine 1A with the portable wireless communication terminal 220, and after authentication by the server device 240, the two-dimensional code is sent to the portable wireless communication terminal 220. Setting change/confirmation history information can be displayed. Therefore, only an authorized person who knows the specified password can save and display the setting change confirmation information, which not only makes it possible to determine whether or not an unnatural operation regarding the setting value has been performed, but also allows unauthorized persons to You will be able to judge whether or not there is an opportunity to investigate the act.

With the above-described configuration, in this embodiment, only an authorized person can save and display the setting change/confirmation history information, so it is possible to determine whether or not an unnatural operation regarding the setting value has been performed. It is possible to provide a pachinko gaming machine 1A and a gaming system 210 that can determine whether or not it is an opportunity to investigate fraudulent activity.

The gaming machines according to each embodiment of the present invention have been described above, including their functions and effects. However, it goes without saying that the present invention is not limited to the embodiments described here, and includes various embodiments without departing from the gist of the present invention as described in the claims.

[10-25. Example of application to pachislot]
For example, the invention according to this embodiment can also be applied to pachi-slot. When the invention according to this embodiment is applied to a pachislot machine, the procedure for executing the setting change process and the setting confirmation process is different from that of the pachinko gaming machine 1.

In the pachislot machine, when the setting key is operated from OFF to ON while the power is OFF, the setting change process is started and the setting value can be changed. Then, when the operation of the start lever is detected or the setting key is turned from ON to OFF, the setting change is finalized.

In order to be able to display the history of setting changes, the main CPU of the pachislot machine inputs the signal generated from the setting switch by operating the setting key when the above-mentioned setting change has been made, and then inputs the signal generated by the setting switch when the start lever is operated. When the sub CPU receives a signal indicating that the setting has been changed, it transmits data indicating that the setting has been changed and a command indicating the current setting value to the sub CPU. Note that the main CPU of the pachi-slot machine constitutes a control section that performs control related to the progress of the game. The main CPU also constitutes data transmitting means for transmitting various data to the display control section.

On the other hand, if the data received from the main CPU is an initialization command indicating that a setting change has been made, the sub CPU receives operation type information indicating a setting change (information indicating a setting change) and an RTC. The date and time data that is currently being clocked, that is, the date and time data when the initialization command was received, is stored in the subwork RAM 2100a as setting change confirmation history information. The pachi-slot sub CPU constitutes a display control section that controls the display on the display section. Further, the sub CPU constitutes a receiving means that receives various data from the data transmitting means.

In Pachislot, checking the setting value means operating the setting key (rotating it to the right) and displaying the current setting value on the 7-segment display based on the signal generated from the setting key type switch. . In this way, the pachi-slot machine moves to a setting confirmation process on the condition that the setting key is operated from OFF to ON while the power is ON, and the setting value is displayed on the 7-segment display. The pachi-slot setting switch constitutes a setting means that allows setting values to be changed or confirmed together with the main CPU.

In order to be able to display the history of confirmation of setting values, the main CPU confirms the setting values by the above-mentioned operation, and when the signal generated from the setting switch is input by operating the setting key, the main CPU confirms that the setting values have been confirmed. data representing the current setting value and a setting confirmation command that is the current setting value are sent to the sub CPU.

On the other hand, if the data received from the main CPU is a setting confirmation command indicating that the setting value has been confirmed, the sub CPU receives operation type information (information indicating setting confirmation) indicating that the setting value is confirmed; The date and time data currently measured by the RTC, that is, the date and time data at which the setting confirmation command representing confirmation of the setting value was received, is stored as setting change confirmation history information in the subwork RAM 2100a functioning as a backup memory. This sub-work RAM 2100a is capable of storing and retaining written information even in a non-energized state.

The sub CPU that receives the setting change start command or the setting confirmation command determines that the setting key has changed from OFF to ON. When the sub CPU determines that the setting key has been turned from OFF to ON, the sub CPU performs a hall menu display process to display a hall menu screen on the main screen of the liquid crystal display device included in the pachislot machine. The hole menu screen displayed in the pachislot machine is replaced with the ``prize ball information'' displayed on the hole menu screen (for example, see FIG. 110) displayed on the display device 16 of the pachinko gaming machine 1 of this embodiment. Although there are some minor differences such as the display of "medal information," the screen is basically the same as the hole menu screen displayed on the display device 16 of the pachinko game machine 1 of this embodiment.

In Pachislot, viewing refers to operating the settings key (turning to the right) and selecting (highlighting) "Setting change/confirmation history" in the hall menu screen displayed on the main screen of the LCD device. On the condition that the main button is pressed while the main button is pressed, setting change confirmation history information stored in the sub-work RAM 2100a is displayed, for example, as a setting change/confirmation history screen.

Note that the pachislot sub CPU executes the same processes as those executed by the host control circuit 2100 of the pachinko gaming machine 1 of this embodiment, such as hall menu processing, setting change/confirmation history processing, maintenance processing, and authentication processing. can do. In addition, when the embodiment of the pachinko game machine 1 is applied to a pachislot, the hole menu screen, setting change/confirmation history screen, error information history screen, guide menu screen, and password request screen described in the embodiment of the pachinko game machine 1 are also available. , a screen similar to the screen displayed when the entered password is inappropriate, the screen displayed on the mobile wireless communication terminal, etc. is displayed on the main screen of the pachi-slot liquid crystal display device or the mobile wireless communication terminal.

Note that in pachislot, when a "bonus win" is determined by a bonus lottery, one of "SBB", "BB", and "RB" is determined by a bonus distribution lottery. However, in the gaming machine of the present invention, either "SBB or BB" or "RB" is determined by a bonus allocation lottery, and either "SBB" or "BB" is determined at the end of the precursor game. You can.

Furthermore, in pachislot, when a precursor game of "SBB" or "BB" is being played, a "BB precursor flag" is turned on. In other words, the "SBB" and "BB" precursor games are managed by the "BB precursor flag." However, the gaming machine of the present invention may have a configuration in which a precursor flag for "SBB" and a precursor flag for "BB" are provided. In this case, the effect of the precursor game corresponding to "SBB" may be different from the effect of the precursor game corresponding to "BB".

In addition, in pachislot, the first ART ("SBB", "BB", "RB") and the second ART end on the condition that the number of stay games has been played, but the first ART The second ART may be configured to end on the condition that navigation (notification of display auxiliary information) has been performed a predetermined number of times.

In addition, in pachislot, the number of staying games for "SBB" in the first ART may be fixed to, for example, "100", and similarly to "BB", the number of games added to the number of staying games during "SBB" may be fixed. A configuration in which the values are added (added) may also be used.

Furthermore, in pachi-slot, the number of games in which additional effects A, B, and C that may occur in BR may be fixed to, for example, "2". That is, when the effects of additional add-ons A, B, and C are determined, the additional add-on game number counter may be set to "2." However, the number of games in which the additional effects A, B, and C are performed may be made variable. For example, the value set in the additional bonus game counter may be set differently depending on the type of additional bonus effect (additional bonus A, B, C).

In addition, in pachislot, the number of games the second ART stays in may be determined to be a fixed number of games, such as "50", or alternatively, a predetermined number of games may be set as one set (for example, , 1 set "50 games"), the number of games of the second ART may be set as a plurality of sets determined by a lottery. For example, the number of staying games for the second ART may be set to two sets of "50" games per set, that is, a total of "100" games. Further, in this case, a predetermined period may be provided between sets in which the stop order is not notified and the value of the ART game number counter is not subtracted for each game. Further, a lottery for the number of additional games may be performed for each game in this predetermined period. Then, before this predetermined period ends (if this predetermined period is to end when the number of games reaches a predetermined number of games, before this predetermined number of games is reached), the stop order other than the order of If a stop operation (irregular press) is performed in , the predetermined period is forcibly ended, and the value of the ART game number counter is subtracted by 1 for each game from the game following the game in which the irregular press was performed. You may.

Furthermore, in the case of pachislot, the rotating accessory unit 122 having the rotating accessory 123 rotated by the driving of a stepping motor has been described as an example of an accessory provided in the pachinko game machine 1. However, the present invention is not limited to this, and the pachinko game machine 1 may be provided with an accessory that moves in the left-right direction, up-down direction, or front-back direction by driving, for example, a stepping motor or a solenoid.

[11. Additional notes]
According to the pachinko gaming machine of the embodiment described above, the following gaming machine can be provided.

[11-1. Each gaming machine from Appendix 1-1 to Appendix 1-8]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a predetermined condition is met, and an effect image is displayed on, for example, a liquid crystal display based on the result of the lottery. If the lottery result is a jackpot, a jackpot game is started and the jackpot opens and closes in a predetermined opening and closing pattern. If the above-mentioned jackpot is a variable probability jackpot, after the jackpot game ends, the game is controlled to a high probability gaming state.

As this type of gaming machine, game setting values are input in advance by a predetermined setting input means to determine the state of gaming elements (structural elements and control elements) that affect the rate of balls entering the entrance and the tendency of balls to come out. A pachinko game machine that is set to a state corresponding to the above has been disclosed (for example, see Japanese Patent Laid-Open No. 2015-065977).

According to the gaming machine described in JP-A No. 2015-065977, the ball payout tendency for each gaming machine can be arbitrarily set, making it impossible to adjust or maintain the gaming board configuration such as game nails and accessories. Even if this is the case, it is possible to prevent the ball payout tendency from becoming uniform from game to game parlor or from game to game machine to game machine.

(First issue)
However, according to the gaming machine described in JP-A No. 2015-065977, although the tendency of balls to come out can be set arbitrarily for each gaming machine, there are structural factors that affect the rate of balls entering the ball opening and the tendency of balls to come out. Alternatively, it is only possible to change the state of a control element according to a set value, but it cannot necessarily be said that the degree of contribution to improving gaming interest is large.

The present invention has been made in view of such points, and its purpose is to provide a gaming machine that can suitably change the state of gaming elements according to settings while improving the enjoyment. be.

In order to solve the first problem described above, a gaming machine as set forth in Appendix 1-1 having the following configuration is provided.

(1) The gaming machines listed in Appendix 1-1 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
A lottery means (for example, the main CPU 101 that can execute the processes of step S73, step S83, and step S118) that can execute a lottery based on the establishment of predetermined conditions;
Display means (e.g., first special symbol display section 73, second special symbol display section 74) that displays symbols (e.g., special symbols) in a predetermined variation pattern over a predetermined variation time;
a fluctuation pattern determining means (for example, a main CPU 101 capable of executing the process of step S78) that determines a fluctuation pattern to be performed on the display means based on the result of the lottery;
fluctuation pattern table storage means (for example, main ROM 102) for storing a fluctuation pattern table used for determining the fluctuation pattern;
A symbol display control means (for example, a fluctuating display of a special symbol) of the symbols for a varying period of time corresponding to the fluctuation pattern determined by the fluctuation pattern determining means, and that stops displaying the symbols in a manner indicating the result of the lottery. For example, a main CPU 101) capable of executing the process of step S93,
Equipped with
The fluctuation pattern table storage means includes:
A variation pattern table (for example, in FIG. 23) is stored.

According to the gaming machine of (1) above, the higher the setting value set by the setting change control means, the shorter the fluctuation time, so the higher the setting value, the more the number of drawings per unit time, and the more the result of the drawing The level of expectation is increased, and it becomes possible to improve the interest in the game.

(2) In the gaming machine described in (1) above,
Further comprising a lottery number counting means (for example, main CPU 101) that counts the number of times the lottery has been executed from a specific time, and
The fluctuation pattern table storage means includes:
Another variation pattern table (for example, as shown in FIG. It further stores a special symbol fluctuation time determination table when the number of fluctuations shown is 1001 or more,
The fluctuation pattern determining means includes:
When the number of times the lottery has been executed as counted by the number-of-lotteries counting means satisfies a predetermined condition (for example, when a special symbol jackpot lottery has been held 1001 or more times since the end of the jackpot game state), The variation pattern may be determined using the other variation pattern table.

According to the gaming machine described in (2) above, when the number of lottery executions counted by the lottery frequency counting means satisfies a predetermined condition, a variable pattern can be determined using another variable pattern table. Therefore, the higher the setting value, the more significantly the number of drawings per unit time, and when the number of drawings is executed a certain number of times, the player's expectation level is increased, and it is possible to improve the interest in the game. Note that the "predetermined condition" corresponds to, for example, when a special symbol jackpot lottery is held a predetermined number or more (for example, 1001 or more times) after the jackpot game state ends, but is not limited to this.

(3) In the gaming machine described in (2) above,
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable displays, and setting values). Possible game information storage means (for example, RWM (main RAM 103)),
Appropriateness determining means (main CPU 101 that performs the processing of steps S72 and S82) for determining whether the game information stored in the game information storage means is appropriate or inappropriate at a predetermined timing;
If the game information stored in the game information storage means is determined to be inappropriate by the suitability determination means while the symbols are being displayed in a variable manner, a lottery for the variable display of the symbols is held. A game control means (for example, the main CPU 101 that executes the process of step S722) that controls the game so that the game cannot proceed even if the symbols are not stopped and displayed in a manner that indicates the result;
It is characterized by having the following.

According to the gaming machine of (3) above, when the variable display of symbols (for example, the variable display of special symbols) is performed, it is determined whether the gaming information stored in the gaming information storage means is appropriate or inappropriate. It may be done. In this case, even if the symbol is not stopped and displayed in a manner that indicates the result of the lottery regarding the fluctuating symbol display, if it is determined to be inappropriate in determining whether the game information is appropriate or not, The game is configured so that the game cannot be played. This makes it possible to ensure security.

In order to solve the first problem described above, a gaming machine according to appendix 1-2 having the following configuration is provided.

(1) The gaming machines listed in Appendix 1-2 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
A lottery means (for example, the main CPU 101 that can execute the processes of step S73, step S83, and step S118) that can execute a lottery based on the establishment of predetermined conditions;
A display means (for example, a display device 16) on which a pattern effect using a predetermined pattern (for example, a variable effect of a decorative pattern) is performed, and the result of the lottery can be shown depending on the stopping state of the pattern;
A stop mode determining means (for example, a host control circuit 2100 capable of executing the process of step S205) that determines a stop mode of the symbol that can be shown on the display means based on the result of the lottery;
Stop mode table storage means (for example, sub-main ROM 2050) that stores a stop mode table (for example, the decorative pattern determination table of FIG. 24) used for determining the stop mode of the symbol by the stop mode determination means;
a symbol production control means (for example, a host control circuit 2100 capable of executing the process of step S207) that controls the symbol to be stopped in the stop manner determined by the stop manner determining means;
When the symbol is displayed in a manner (for example, first aspect, second aspect, specific aspect) indicating that the result of the lottery is a specific result (for example, a jackpot), multiple benefits advantageous to the player may be generated. (For example, 4R normal jackpot, 4R probability variable jackpot, 10R normal jackpot, 10R probability variable jackpot) Profit giving means (for example, main CPU 101 that executes jackpot game control in FIG. 20);
Equipped with
The profit giving means is
When the symbol is displayed in a stopping mode indicating that the result of the lottery is the specific result (for example, a jackpot), and the stopping mode is a specific stopping mode (for example, a specific mode), the plurality of profits are It is configured to be able to grant specific profits that are relatively advantageous (for example, 10R guaranteed variable jackpot),
The stop mode determining means includes:
When the result of the lottery is the specific result (for example, a jackpot), as the setting value set by the setting change control means becomes higher, the probability that the pattern stops in the specific stopping pattern increases. The present invention is characterized in that it is configured such that the manner in which the symbol stops can be determined so as to increase the height of the symbol.

According to the gaming machine of (1) above, the higher the set value set by the setting change control means, the more the symbols are stopped in a specific stopping mode that is relatively more advantageous among multiple profits. It becomes possible to increase the probability that the game will occur, and it becomes possible to improve the interest in the game.

(2) In the gaming machine described in (1) above,
The stop mode determining means includes:
When the result of the lottery is the specific result (for example, a jackpot), the setting value set by the setting change control means even though the probability of receiving the specific profit is the same regardless of the setting value. The present invention is characterized in that the stopping manner of the symbol can be determined so that the probability that the symbol will be stopped in the specific stopping manner increases as the symbol becomes higher.

According to the gaming machine of (2) above, when the result of the lottery is the specific result (for example, a jackpot), the probability of receiving a specific profit is the same regardless of the setting, but the setting is changed. As the setting value set by the control means becomes higher, the probability that the game will be stopped in a specific stopping manner increases, so that it is possible to improve the interest in the game.

(3) In the gaming machine described in (1) or (2) above,
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable display, and setting values). Possible game information storage means (for example, RWM (main RAM 103)),
Appropriateness determining means (main CPU 101 that performs the processing of steps S72 and S82) for determining whether the game information stored in the game information storage means is appropriate or inappropriate at a predetermined timing;
When the game information stored in the game information storage means is determined to be inappropriate by the suitability determination means while the symbol production is being performed, the result of the lottery may be determined to be the specific result. Even if the stopping mode determining means determines that the symbol is stopped in the specific stopping mode, the game controlling means (for example, executing the process of step S722) controls the game so that the game cannot proceed. main CPU 101),
It is characterized by having the following.

According to the gaming machine of (3) above, when a symbol presentation (for example, a variation presentation of decorative symbols) is being performed, it is determined whether the gaming information stored in the gaming information storage means is appropriate or inappropriate. Sometimes. In this case, even if the lottery result is a specific result and it is determined that the pattern stops in a specific stopping manner, it is inappropriate to determine whether the game information is suitable or not. If it is determined that this is the case, the game is configured such that the game cannot proceed. This makes it possible to ensure security.

In order to solve the first problem described above, a gaming machine according to appendix 1-3 having the following configuration is provided.

(1) The gaming machines listed in Appendix 1-3 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
A lottery means capable of executing a lottery based on the establishment of predetermined conditions (for example, a main CPU 101 capable of executing the processes of steps S73, S83, and S118, including both a jackpot lottery and a main symbol determination lottery);
a lottery table storage means for storing a lottery table used in the lottery (for example, a table showing the selection rate of the main symbol when the result of the jackpot determination of the special symbol in FIG. 26 or 27 is a jackpot);
A display means (for example, a first special symbol display section 73, a second special symbol display section 74) that displays at least a variable symbol;
A symbol display control means (for example, a main CPU 101 capable of executing the process of step S93) that displays the symbols in a variable manner and stops displaying them in a manner that indicates the result of the lottery;
The above-mentioned symbols are displayed in a manner (for example, Tokuzu 1-1 to Tokuzu 1-8, Tokuzu 2-1 to Tokuzu 2-4) that indicates that the result of the lottery is a specific result (for example, a jackpot). When displayed, a benefit giving means (for example, the profit giving means shown in FIG. A main CPU 101) that executes jackpot game control;
Equipped with
The lottery table storage means includes:
A plurality of lottery tables are stored in which lottery probabilities for relatively highly advantageous specific profits (for example, 10R variable jackpot) among the plurality of profits differ according to set values,
The lottery means is
The present invention is characterized in that it is configured such that the lottery can be performed using a lottery table according to the setting values set by the setting change control means.

According to the gaming machine of (1) above, since the lottery is performed using a plurality of lottery tables with different lottery probabilities for specific profits that are relatively advantageous depending on the setting value, the lottery is set by the setting change control means. It becomes possible to vary the degree of profit given to the player according to the set value set, and it becomes possible to improve the interest in the game.

(2) In the gaming machine described in (1) above,
The profit giving means is
As the specific profit, at least a special gaming state that is advantageous to the player and a high probability gaming state in which the profit is provided with a relatively high probability in the gaming state after the special gaming state ends are provided. and
The lottery table storage means includes:
The gaming machine is characterized in that a plurality of tables are stored in which the probability of being controlled to the high probability gaming state differs depending on a set value.

According to the gaming machine of (2) above, the probability of being controlled to a high probability gaming state varies depending on the set value, so it is possible to improve gaming interest.

(3) In the gaming machine described in (1) or (2) above,
The profit giving means are:
As the specific benefit, a specific gaming state (for example, a time-saving gaming state) in which the lottery is promoted is further provided,
The lottery table storage means includes:
The gaming machine is characterized in that a plurality of tables are stored in which the probability of being controlled to the specific gaming state differs depending on a set value.

According to the gaming machine (2) above, since the probability of being controlled to a specific gaming state varies depending on the set value, it is possible to improve gaming interest.

(4) In the gaming machine described in any one of (1) to (3) above,
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable display, and setting values). Possible game information storage means (for example, RWM (main RAM 103)),
Appropriateness determining means (main CPU 101 that performs the processing of steps S72 and S82) for determining whether the game information stored in the game information storage means is appropriate or inappropriate at a predetermined timing;
If the game information stored in the game information storage means is determined by the suitability determining means to be inappropriate while the symbols are being displayed in a variable manner, the lottery related to the variable display of the symbols is determined to be inappropriate. A game control means (for example, the main CPU 101 that executes the process of step S722) that controls the game so that the game cannot proceed even if the result is that the specific profit is granted;
It is characterized by

According to the gaming machine of (4) above, when the symbols are displayed in a variable manner, it may be determined whether the gaming information stored in the gaming information storage means is appropriate or inappropriate. In this case, the game is configured so that the game cannot proceed even if the result of the lottery based on the variable display of symbols is that a specific profit will be awarded. This makes it possible to ensure security.

In order to solve the first problem described above, a gaming machine according to appendix 1-4 having the following configuration is provided.

(1) The gaming machines listed in Appendix 1-4 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
a plurality of starting ports including a first starting port and a second starting port provided in the gaming area;
A special lottery means (for example, a main unit capable of executing the processes of step S73, step S83, and step S118 CPU101) and
A special game execution means (for example, the main CPU 101 that executes the jackpot game control in FIG. 20) that can execute a special game that operates based on the result of the special lottery being a special result (for example, a jackpot);
A specific game execution means (for example, main CPU 101) that can execute a specific game with a lower advantage than the special game based on the result of the special lottery being a specific result (for example, a small win);
Equipped with
The special lottery means is
When performing the special lottery based on the entry (for example, acceptance) of a game ball into the starting slot, the probability of the special lottery resulting in the specific result is determined according to a setting value set by the setting change control means. It is possible to do it differently depending on the
The specific game execution means is
Regardless of the set value set by the setting change control means, when a game ball enters the second starting port more frequently than when the game ball enters the first starting port. It is characterized in that it is configured to be able to execute the specific game.

According to the gaming machine of (1) above, the probability of a particular outcome can vary depending on the setting value set by the setting change control means, and the probability of a specific result can vary depending on the setting value set by the setting change control means. A specific game is executed more frequently when a game ball enters the second starting port than when the game ball enters the first starting port. In other words, when a game ball is placed in the second starting hole, on the premise that a specific game will be executed with high frequency, it becomes possible to vary the execution frequency of the specific game according to the set value, and the game It becomes possible to improve interest.

In addition, "the specific game can be executed more frequently when the game ball enters the second starting port than when the game ball enters the first starting port" means that the first When the game ball enters the second starting port, a winning/losing judgment is made for a specific result (including a probability of 0), but the probability of a specific result in the winning/losing judgment is that the gaming ball enters the second starting port. This includes not only a mode in which the game ball enters the first starting port, but also a mode in which a win/loss determination situation regarding a specific result is not performed.

(2) In the gaming machine described in (1) above,
A normal starting port (for example, passage gate 49) provided in the gaming area;
A normal lottery means (for example, the main CPU 101 that performs a normal winning determination in the normal game of FIG. 20) that performs a normal lottery based on the entry (for example, passage) of a game ball into the normal starting port;
Based on the result of the normal lottery being a predetermined result (e.g., normal win), variable start control means (e.g., variable start control means) capable of facilitating entry (e.g., acceptance) of game balls into the start opening; , main CPU 101) and
A first special symbol is displayed variably based on the entry of the game ball into the first starting port (first starting port 420), and the game ball enters the second starting port (first starting port 440). A special symbol variation display control means (for example, main CPU 101) that displays a variation of the second special symbol based on the entry;
A first game state in which the period of variable display of the second special symbol (for example, an average time of 1000 seconds) is long enough to affect the progress of the game (for example, a normal game in which both the probability change flag and the time saving flag are set to OFF) state), or a second gaming state (e.g., in which the fluctuating display time of the second special symbol (for example, an average time of 1 sec) is shorter than the fluctuating display time of the first special symbol (for example, an average time of 10 sec) A gaming state control means (for example, the main CPU 101) capable of controlling an advantageous gaming state in which the probability change flag is set to ON and the time saving flag is set to OFF;
It is characterized by further comprising:

According to the gaming machine of (2) above, in the second gaming state, the variable display time of the second special symbol is shorter than the variable display time of the first special symbol, so that the specific game can be executed with high frequency. , it becomes possible to vary the execution frequency of a specific game according to the set value without increasing the execution frequency of the normal lottery.

(3) In the gaming machine described in (1) or (2) above,
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable display, and setting values). Possible game information storage means (for example, RWM (main RAM 103)),
Display means (for example, a first special symbol display section 73, a second special symbol display section 74) for displaying the results of the special lottery;
Appropriateness determining means (main CPU 101 that performs the processing of steps S72 and S82) for determining whether the game information stored in the game information storage means is appropriate or inappropriate at a predetermined timing;
Although a game ball enters the starting port (for example, the second starting port), before the result of the special lottery is displayed, the suitability determination means determines that the game information stored in the game information storage means is inappropriate. If it is determined that, even if the result of the special lottery (for example, the second special lottery) is the specific result, the game cannot be played without executing the specific game by the specific game execution means. A game control means (for example, the main CPU 101 that executes the process of step S722),
It is characterized by having the following.

According to the gaming machine of (3) above, even if a game ball enters the starting port (for example, the second starting port), a special lottery (for example, Before the result of the second special lottery is shown (for example, during the variable display of special symbols), it may be determined whether the game information stored in the game information storage means is suitable or not. In this case, even if the result of the special lottery (for example, the second special lottery) based on the entry of the game ball into the starting hole (for example, the second starting hole) is a specific result (for example, a small hit), Even so, if it is determined that the game information is inappropriate in determining whether it is appropriate or inappropriate, the game is configured such that the game cannot proceed before a specific game (for example, a small winning game) is executed. This makes it possible to ensure security.

In order to solve the above first problem, we provide a gaming machine according to appendix 1-5 having the following configuration.

(1) The gaming machines listed in Appendix 1-5 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
A starting port provided in the gaming area;
special lottery means for performing a special lottery based on entry (for example, acceptance) of game balls into the starting port;
a first special game execution means capable of executing a first special game that operates based on the result of the special lottery being a special result (for example, a jackpot);
A normal starting port (for example, passage gate 49) provided in the gaming area;
A normal lottery means (for example, the main CPU 101 that performs a normal winning determination in the normal game of FIG. 20) that performs a normal lottery based on the entry (for example, passage) of a game ball into the normal starting port;
Based on the result of the normal lottery being a predetermined result (e.g., normal win), variable start control means (e.g., variable start control means) capable of facilitating entry (e.g., acceptance) of game balls into the start opening; , main CPU 101) and
Within a specific area where a specific opening is provided based on the result of the special lottery conducted based on the entry (for example, acceptance) of a game ball into the starting opening being a specific result (for example, a small win). a specific area variable control means (for example, the main CPU 101) capable of operating a predetermined movable piece to facilitate the entry (for example, reception) of a game ball into the game ball;
a second special game execution means capable of executing a second special game that operates based on a game ball being received in the specific opening provided in the specific area;
Equipped with
The specific area variable control means
The predetermined movable piece is configured to be able to be operated so that the ease of entry of the game ball into the specific area may vary depending on the setting value set by the setting change control means. Features.

According to the gaming machine of (1) above, since the probability of a particular result can vary depending on the setting value set by the setting change control means, the predetermined result is changed according to the set setting value. It becomes possible to vary the operating frequency of the movable piece and, in turn, to vary the opportunity to receive a benefit depending on the set value, thereby making it possible to improve the interest in the game.

(2) In the gaming machine described in (1) above,
The operation of the predetermined movable piece by the specific area variable control means is as follows:
The ease of entry (for example, acceptance) of the game ball into the starting hole is varied according to the setting value set by the setting change control means (for example, by changing the probability of a normal hit, By making the execution frequency of the special lottery different depending on the set value (such as shortening the variation time), the ease of entry of game balls into the specific area can be increased by the set value. It is characterized by being carried out differently depending on the situation.

According to the game machine of (2) above, the ease with which the game ball enters the starting port (for example, the second starting port 440) is normally controlled so that it can vary depending on the setting value set by the setting change control means. Since a lottery is held, the amount of benefits awarded based on the entry of the game ball into a specific area will vary depending on the set value, making it possible to improve the interest in the game.

(3) In the gaming machine described in (1) or (2) above,
The operation of the predetermined movable piece by the specific area variable control means is as follows:
By varying the probability of the specific result (for example, a small win) in the special lottery depending on the setting value set by the setting change control means, it is possible to make it easier for the game ball to enter the specific area. The method is characterized in that the process is performed in such a way that it can vary depending on the set value.

According to the game machine of (3) above, the ease with which the game ball enters the starting port (for example, the second starting port 440) is normally controlled so that it can vary depending on the setting value set by the setting change control means. Since a lottery is held, the amount of benefits awarded based on the entry of a game ball into a specific area will vary depending on the set value, making it possible to improve the interest in the game.

(4) In the gaming machine described in any one of (1) to (3) above,
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable displays, and setting values). Possible game information storage means (for example, RWM (main RAM 103)),
Display means for displaying the results of the special lottery (for example, a first special symbol display section 73, a second special symbol display section 74);
Appropriateness determining means (main CPU 101 that performs the processing of steps S72 and S82) for determining whether the game information stored in the game information storage means is appropriate or inappropriate at a predetermined timing;
When a game ball enters the starting port but before the result of the special lottery is displayed, the suitability determining means determines that the game information stored in the game information storage means is inappropriate; Even if the result of the special lottery is a specific result, the game control means (for example, the process of step S722) controls the specific area variable control means so that the game cannot be played without operating the predetermined movable piece. The main CPU 101) that executes
It is characterized by having the following.

According to the gaming machine of (4) above, even if a game ball enters the starting port, the result of the special lottery conducted based on the entry of the game ball into the starting port is not displayed (for example, the special symbol (during the variable display), it may be determined whether the gaming information stored in the gaming information storage means is appropriate or inappropriate. In this case, even if the result of the special lottery held based on the entry of the game ball into the starting slot is a specific result, if it is determined to be inappropriate in determining whether the game information is appropriate or inappropriate. The game is configured such that the game cannot proceed until a predetermined movable piece is activated. This makes it possible to ensure security.

In order to solve the above first problem, we provide a gaming machine according to appendix 1-6 having the following configuration.

(1) The gaming machines listed in Appendix 1-6 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
A lottery means (for example, the main CPU 101 that can execute the processes of step S73, step S83, and step S118) that can execute a lottery based on the establishment of predetermined conditions;
A special game state control means capable of controlling a special game state (for example, a jackpot game state) based on the result of the lottery being a special result (for example, a jackpot) (for example, executing the jackpot game control of FIG. 20 main CPU101) and
Game state control means (for example, probability change in step S169) that can control the game state after the special game state is ended to an advantageous game state (for example, a high probability game state) that is more advantageous to the player than the normal game state. a main CPU 101) that proceeds with the game after setting the flag;
After being controlled to the special gaming state, the special gaming state and the advantageous gaming state are repeated (for example, the number of loops) without being controlled to the normal gaming state. CPU101) and
Equipped with
The gaming state control means includes:
Even when the result of the lottery in the advantageous gaming state is the special result, it is configured to be controllable to the special gaming state, and
When the number of times counted by the counting means reaches a specified number of times, controlling the gaming state after the special gaming state ends to the normal gaming state,
The prescribed number of times is
It is characterized in that it is configured to be able to vary depending on the setting value set by the setting change control means.

According to the gaming machine of (1) above, it is possible to repeat the special gaming state and the advantageous gaming state up to a predetermined number of times, and this predetermined number of times varies depending on the setting value set by the setting change control means. It becomes possible to improve the interest in the game.

(2) In the gaming machine described in (1) above,
Further comprising a prescribed number of times determination means (for example, a main CPU 101 that performs a limiter number of lottery) that determines the prescribed number of times by lottery,
The prescribed number of times determining means includes:
The invention is characterized in that the lottery for determining the prescribed number of times is performed such that an expected value for the prescribed number of times is different depending on a set value set by the setting change control means.

According to the gaming machine of (2) above, the prescribed number of times that the special gaming state and the advantageous gaming state can be repeated is determined by lottery, and the expected value for this prescribed number of times is a set value set by the setting change control means. Since it differs depending on the game, it is possible to improve the interest in the game.

(3) In the gaming machine described in (1) or (2) above,
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable displays, and setting values). Possible game information storage means (for example, RWM (main RAM 103)),
Appropriateness determining means (main CPU 101 that performs the processing of steps S72 and S82) for determining whether the game information stored in the game information storage means is appropriate or inappropriate at a predetermined timing;
When the suitability determining means determines that the game information stored in the game information storage means is inappropriate, even if the number of times counted by the counting means is less than the specified number of times, the counting means a game control means (for example, the main CPU 101 that executes the process of step S722) that controls the game so that the game cannot be played unless the number of times counted by the number reaches the specified number of times;
It is characterized by having the following.

According to the gaming machine of (3) above, when the number of times the special gaming state and the advantageous gaming state are repeated without being controlled to the normal gaming state (i.e., the number of loops) does not reach the specified number of times (i.e., during the loop ), it may be determined whether the gaming information stored in the gaming information storage means is appropriate or inappropriate. In this case, even if the game information is in a loop, if the game information is determined to be inappropriate, the game is configured so that the number of loops does not reach the specified number of times and the game cannot proceed. There is. This makes it possible to ensure security.

In order to solve the above first problem, we provide a gaming machine according to appendix 1-7 having the following configuration.

(1) The gaming machines listed in Appendix 1-7 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
A lottery means (for example, the main CPU 101 that can execute the processes of step S73, step S83, and step S118) that can execute a lottery based on the establishment of a predetermined condition (for example, acceptance of a game ball into the first starting port 440); ,
A game control means capable of controlling the progress of the game (for example, the jackpot game control shown in FIG. The main CPU 101) that executes
performance control means (for example, host control circuit 2100 (display control circuit 2300)) capable of executing at least an opening performance performed at the start of the special game state and an ending performance performed at the end of the special game state;
Equipped with
The lottery means is
Performing the lottery in such a manner that the higher the setting value set by the setting change control means, the higher the advantage.
The performance control means is
The opening performance and the ending performance are executed such that at least one of the time required for the opening performance and the time required for the ending performance becomes longer as a setting value set by the setting change control means is higher. It is characterized by being configured to

According to the gaming machine of (1) above, the lottery is conducted in such a manner that the higher the setting value is, the higher the advantage is, and at least one of the time required for the opening performance and the time required for the ending performance. can become longer as the set value is higher. Therefore, at a high setting, it is possible to suppress the number of prize balls paid out per unit time while improving the game's interest.

(2) In the gaming machine described in (1) above,
A symbol variation display control means (for example, a main CPU 101 capable of executing the process of step S93) that displays a symbol variation based on the result of the lottery;
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable displays, and setting values). Possible game information storage means (for example, RWM (main RAM 103)),
Appropriateness determining means (main CPU 101 that performs the processing of steps S72 and S82) for determining whether the game information stored in the game information storage means is appropriate or inappropriate at a predetermined timing;
Furthermore,
The lottery means is
It is possible to extract a random number based on the winning of a game ball in the starting hole regardless of whether or not it is controlled in the special gaming state, and
The appropriateness determination means is
Even when controlled in the special gaming state, it is configured to be able to determine whether the gaming information is appropriate or inappropriate;
The game control means is
When the suitability determining means determines that the game information stored in the game information storage means is inappropriate, game progress disallowance is controlled so that the game cannot be played even if the game is controlled to the special game state. It is characterized by having a means (for example, the main CPU 101 that executes the process of step S722).

According to the gaming machine of (2) above, even when the gaming machine is controlled to be in a special gaming state, determination as to whether gaming information is appropriate or inappropriate may be executed. In such a case, if the game information stored in the game information storage means is determined to be inappropriate, the game will not be able to proceed even if it is controlled to a special game state, so security is ensured. At the same time, it is possible to improve the player's interest in the game.

In order to solve the first problem described above, a gaming machine according to appendix 1-8 is provided having the following configuration.

(1) The gaming machines listed in Appendix 1-8 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
a plurality of entrances having at least a first entrance (e.g., accessory continuous operation left gate 1100) and a second entrance (e.g., accessory continuous operation right gate 1110);
Entry allowing means (for example, sorting device 1120) configured to allow a game ball to enter any one of the plurality of entrances;
There are different profits depending on when the game ball enters the first entrance and when the game ball enters the second entrance (for example, if the number of rounds is different, or if there is a starting opening below the entrance, the lottery will be held) A profit granting means (for example, the main CPU 101 that executes the jackpot game control in FIG. 20) that can give the player a profit (such as whether or not it is executed),
Equipped with
The entry permitting means is
The game ball is configured such that the ease with which the game ball enters the first entrance port and the second entrance port can vary depending on a setting value set by the setting change control means. do.

According to the gaming machine of (1) above, there is a possibility that the benefit given to the player is different when the game ball enters the first entrance and when the game ball enters the second entrance. The ease of entry of game balls into the first entry port and the second entry port is configured to be different depending on the set value set by the setting change control means. Moreover, since the player can aim at which of the first entrance and the second entrance the game ball will enter, the state of the game elements can be adjusted according to the settings while improving the enjoyment of the game. It becomes possible to suitably change.

In addition, "a different profit can be given to the player when a game ball enters the first entrance port and when a game ball enters the second entrance port" means, for example, when a game ball enters the first entrance port. In addition to the case where the number of rounds in the jackpot game state is different when the ball enters and when the game ball enters the second entrance, one entrance is a starting entrance that triggers a lottery, and the other entrance is a lottery trigger. This corresponds to the case where it is a general winning opening that does not serve as an opportunity.

(2) In the gaming machine described in (1) above,
A starting port provided in the gaming area (for example, a first starting port 420, a second starting port 440),
A lottery means (for example, a main CPU 101 capable of executing the processes of step S73, step S83, and step S118) that performs a lottery based on the game ball being received in the starting slot;
Display means (for example, a first special symbol display section 73, a second special symbol display section 74) for displaying symbols in a variable manner based on the result of the lottery;
Game information related to the progress of the game, including information on the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results for pending memories and variable displays, and setting values) A game information storage means (for example, RWM (main RAM 103)) capable of storing
Appropriateness determination means (for example, main CPU 101 that performs the processing of steps S72 and S82) that determines whether the game information stored in the game information storage means is appropriate or inappropriate at a predetermined timing;
If the game information stored in the game information storage means is determined to be inappropriate by the suitability determining means, even if a game ball enters the first entrance or the second entrance, the player cannot A game control means (for example, the main CPU 101 that executes the process of step S722) that controls the game so that the game cannot be played without giving a profit,
It is characterized by having the following.

According to the gaming machine of (2) above, when the game ball enters the first entry port or the second entry port but no profit has been awarded yet while the symbols are being displayed in a variable manner, the game information is stored in the gaming information storage means. The appropriateness or inappropriateness of game information provided may be determined in some cases. In this case, even though there is a possibility that a profit may be given to the player, if the game information is determined to be inappropriate in determining whether it is suitable or not, the game is continued without giving any profit to the player. It is configured so that it is not possible. This makes it possible to ensure security.

(3) In the gaming machine described in (2) above,
Based on the result of the lottery being a special result, entry enabling means (for example, a main unit that operates a condition device further equipped with a CPU101),
The profit giving means are:
When the game ball enters the first entrance, a predetermined profit (for example, 8R jackpot game state) can be given to the player, and
The present invention is characterized in that when a game ball enters the second entrance, a specific profit (for example, a 16R jackpot game state) having a higher profit than the predetermined profit can be given to the player.

According to the gaming machine described in (3) above, the player plays the game aiming at the second entrance where there is a possibility of being awarded a specific profit with a larger profit, and it is possible to improve the player's interest in the game. becomes.

According to each of the gaming machines of Supplementary Notes 1-1 to 1-8 having the above configuration, it is possible to suitably change the state of the gaming elements according to the settings while improving interest.

[11-2. Gaming machines in Appendix 2]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a predetermined condition is met, and an effect image is displayed on, for example, a liquid crystal display based on the result of the lottery. If the result of the lottery is a jackpot, a jackpot game is started and the jackpot opens and closes in a predetermined opening and closing pattern. If the above-mentioned jackpot is a variable probability jackpot, after the jackpot game ends, the game is controlled to a high probability gaming state.

As this type of gaming machine, game setting values are input in advance by a predetermined setting input means to determine the state of gaming elements (structural elements and control elements) that affect the rate of balls entering the entrance and the tendency of balls to come out. A pachinko game machine that is set to a state corresponding to the above has been disclosed (for example, see Japanese Patent Laid-Open No. 2015-065977).

According to the gaming machine described in JP-A No. 2015-065977, the ball payout tendency for each gaming machine can be arbitrarily set, making it impossible to adjust or maintain the gaming board configuration such as game nails and accessories. Even if this is the case, it is possible to prevent the ball payout tendency from becoming uniform from game to game parlor or from game to game machine to game machine.

(Second issue)
However, according to the gaming machine described in Japanese Unexamined Patent Application Publication No. 2015-065977, although it is possible to arbitrarily set the ball payout tendency for each gaming machine, for example, an abnormality may occur in the gaming setting value, etc., and security cannot be ensured. It's hard to say.

The present invention has been made in view of such points, and its purpose is to provide a gaming machine that can change the state of gaming elements according to settings while improving security.

In order to solve the second problem described above, a gaming machine according to appendix 2 having the following configuration is provided.

(1) The gaming machines mentioned in Appendix 2 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable displays, and setting values). a game information storage means (for example, RWM (main RAM 103)),
A lottery means (for example, the main CPU 101 capable of executing the processes of step S73, step S83, and step S118) that performs a lottery based on the establishment of a predetermined condition (for example, acceptance of a game ball into the first starting port 440);
A symbol variation display control means (for example, a main CPU 101 capable of executing the process of step S93) that displays a symbol variation based on the result of the lottery;
Appropriateness determination means (for example, the main CPU 101 that performs the processing of steps S72 and S82) that determines whether the game information is appropriate or inappropriate at a predetermined timing (for example, the timing of receiving a game ball into the first starting port 440); ,
If the game information stored in the game information is determined by the suitability determination means to be inappropriate while the symbols are being displayed in a variable manner, it is assumed that the symbol is being displayed in a variable manner. a game control means (for example, the main CPU 101 that executes the process of step S722) that controls the game so that the game cannot proceed;
It is characterized by having the following.

According to the gaming machine of (1) above, when the symbols are being displayed in a variable manner, it may be determined whether the gaming information is appropriate or inappropriate. In such a case, if it is determined that the game information stored in the game information storage means is inappropriate, the game will not be allowed to proceed even if the symbols are displayed in a variable manner, so it is important to ensure security. It becomes possible to improve.

According to the gaming machine of appendix 2 having the above configuration, it is possible to change the state of the gaming elements according to the settings while improving security.

[11-3. Gaming machines in Appendix 3]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a predetermined condition is met, and an effect image is displayed on, for example, a liquid crystal display based on the result of the lottery. If the lottery result is a jackpot, a jackpot game is started and the jackpot opens and closes in a predetermined opening and closing pattern. If the above-mentioned jackpot is a variable probability jackpot, after the jackpot game ends, the game is controlled to a high probability gaming state.

As this type of gaming machine, game setting values are input in advance by a predetermined setting input means to determine the state of gaming elements (structural elements and control elements) that affect the rate of balls entering the entrance and the tendency of balls to come out. A pachinko game machine that is set to a state corresponding to the above has been disclosed (for example, see Japanese Patent Laid-Open No. 2015-065977).

According to the gaming machine described in JP-A No. 2015-065977, the ball payout tendency for each gaming machine can be arbitrarily set, making it impossible to adjust or maintain the gaming board configuration such as game nails and accessories. Even if this is the case, it is possible to prevent the ball payout tendency from becoming uniform from game to game parlor or from game to game machine to game machine.

(Third issue)
However, according to the gaming machine described in JP-A No. 2015-065977, although it is possible to arbitrarily set the ball output tendency for each game machine, changing the ball output tendency according to the set value does not necessarily require a light design load. It's hard to say.

The present invention has been made in view of such points, and its purpose is to provide a game machine that can suitably change the state of game elements according to settings while reducing the design load. It is in.

In order to solve the third problem above, a gaming machine according to appendix 3 having the following configuration is provided.

(1) The gaming machines mentioned in Appendix 3 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
Random number generation means that generates random numbers in a predetermined width (for example, the main CPU 101 that generates random numbers by executing a program);
Random number extraction means (for example, main CPU 101 that executes the process of step S73) that extracts random numbers based on the establishment of a predetermined condition;
Table storage means (for example, main RAM 103) that stores a lottery table (for example, jackpot random number determination table) that defines total random numbers (for example, range of random numbers for jackpot determination) and specific random numbers (for example, jackpot determination value data); ,
A lottery is performed using the random numbers extracted by the random number extraction means (for example, the process of step S118), and when the extracted random numbers are specific random numbers (for example, jackpot determination value data), control is performed to a special gaming state. possible special game state control means;
Equipped with
The table storage means includes:
storing a lottery table in which at least the total random number differs according to the setting value set by the setting change control means,
The random number generating means is
It is characterized in that it is configured to generate a total random number of the number specified in the lottery table according to the setting value set by the setting change control means.

According to the gaming machine of (1) above, by changing the denominator (range of random numbers for jackpot judgment) that has more digits than the numerator (number of jackpot judgment value data), the probability of being controlled to a special gaming state (i.e. Compared to a method where the range of random numbers for jackpot judgment is a fixed value and the number of jackpot judgment value data is changed according to the set value, it is easier to set the jackpot probability for each set value in detail. It becomes possible.

(2) In the gaming machine described in (1) above,
A symbol variation display control means (for example, a main CPU 101 capable of executing the process of step S93) that displays a symbol variation based on the result of the lottery;
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable displays, and setting values). Possible game information storage means (for example, RWM (main RAM 103)),
When the random numbers are extracted based on the establishment of the predetermined conditions, before the fluctuating display of the symbols is started, appropriateness determining means (step A main CPU 101) that performs the processing of S72 and S82,
A game control means (for example, the main CPU 101 that executes the process of step S722) that controls the game so that the game cannot proceed if the total random number generated by the random number generation means is determined to be inappropriate by the suitability determination means;
It is characterized by having the following.

According to the gaming machine described in (2) above, when it is determined that the total random number generated by the random number generating means is inappropriate, the game cannot be played, so the set value can be set while ensuring security. It becomes possible to set the jackpot probability for each game in detail.

According to the gaming machine of appendix 3 having the above configuration, it is possible to suitably change the state of the gaming elements according to the settings while reducing the design load.

[11-4. Each gaming machine in Appendix 4-1 and Appendix 4-2]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a predetermined condition is met, and an effect image is displayed on, for example, a liquid crystal display based on the result of the lottery. If the lottery result is a jackpot, a jackpot game is started and the jackpot opens and closes in a predetermined opening and closing pattern. If the above-mentioned jackpot is a variable probability jackpot, after the jackpot game ends, the game is controlled to a high probability gaming state.

As this type of gaming machine, game setting values are input in advance by a predetermined setting input means to determine the state of gaming elements (structural elements and control elements) that affect the rate of balls entering the entrance and the tendency of balls to come out. A pachinko game machine that is set to a state corresponding to the above has been disclosed (for example, see Japanese Patent Laid-Open No. 2015-065977).

According to the gaming machine described in JP-A No. 2015-065977, the ball payout tendency for each gaming machine can be arbitrarily set, making it impossible to adjust or maintain the gaming board configuration such as game nails and accessories. Even if this is the case, it is possible to prevent the ball payout tendency from becoming uniform from game to game parlor or from game to game machine to game machine.

(Fourth issue)
However, according to the gaming machine described in Japanese Unexamined Patent Publication No. 2015-065977, while it is possible to arbitrarily set the ball payout tendency for each gaming machine, players may become suspicious due to the ability to arbitrarily set the ball payout tendency. , there is a risk that interest will decrease.

The present invention has been made in view of such points, and its purpose is to provide a gaming machine that can suitably suppress a decline in interest while changing the state of gaming elements according to settings. There is a particular thing.

In order to solve the fourth problem described above, a gaming machine according to appendix 4-1 having the following configuration is provided.

(1) The gaming machines listed in Appendix 4-1 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
A plurality of winning holes provided in the gaming area and including a starting hole (for example, a first starting hole 420, a second starting hole 440, general winning holes 53 to 56),
A benefit granting means (for example, payout device 350) that grants a benefit (for example, a prize ball) based on a game ball being accepted into one of the plurality of winning holes;
A lottery means (for example, a main CPU 101 capable of executing the processes of step S73, step S83, and step S118) that can execute a lottery based on the game ball being received in the starting slot;
a display means (for example, display device 16) on which at least a variation effect of symbols is performed based on the result of the lottery;
When the fluctuation effect of the symbol is performed in a specific manner (for example, reach effect) indicating that the result of the lottery may be a specific result, a specific winning hole among the plurality of winning holes a setting suggestion means (for example, host control circuit 2100) capable of suggesting setting value information regarding the setting value set by the setting change control means based on the acceptance of the game ball;
It is characterized by

According to the gaming machine of (1) above, the setting change control is performed based on the fact that a game ball is received in a specific winning hole when a variation effect of symbols is performed in a specific mode (for example, reach effect). Since setting value information regarding the setting value set by the means may be suggested, it is possible to reduce doubts on the part of the player. Furthermore, if a variation effect of the symbols is performed in a specific manner, there is a risk that the player will stop shooting the game ball, but such a situation can also be suppressed.

(2) In the gaming machine described in (1) above,
Further comprising a prescribed number of times determination means (for example, a main CPU 101 that performs a limiter number of lottery) that determines the prescribed number of times by lottery,
A specific mode determining means (for example, the main CPU 101 that executes the process of step S78) that determines whether or not to perform the variation effect of the symbol in the specific mode (for example, reach effect);
When the specific mode determining means determines that the variation effect of the symbol is to be performed in the specific mode, specific winning hole determining means randomly determines one of the plurality of winning holes to be the specific winning hole. (For example, main CPU 101) and
It is characterized by further comprising:

According to the gaming machine of (2) above, the specific winning hole is not a fixed winning hole but is randomly determined to be one of a plurality of winning holes, so it is possible to increase the interest in the game. In addition, it is preferable that the randomly determined specific winning hole is kept secret without being disclosed. This makes it more interesting for the player to decide which winning opening to aim for.

(3) In the gaming machine described in (1) or (2) above,
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable display, and setting values). Possible game information storage means (for example, RWM (main RAM 103)),
Appropriateness determining means (main CPU 101 that performs the processing of steps S72 and S82) for determining whether the game information stored in the game information storage means is appropriate or inappropriate at a predetermined timing;
If the game information stored in the game information storage means is determined to be inappropriate by the suitability determination means, even if a game ball is accepted in the specific winning hole, the setting change control means may cause the game ball to be set. A game control means (for example, the main CPU 101 that executes the process of step S722) that controls the game so that the game cannot proceed without suggesting setting value information about the set value that has been set;
It is characterized by having the following.

According to the gaming machine of (3) above, when a variation effect of symbols is being performed or when a gaming ball is accepted into a specific winning hole but no set value information has been suggested yet, the gaming information is stored. It may be determined whether game information stored in the means is appropriate or inappropriate. In this case, even if there is a possibility that setting value information may be suggested, if it is determined that the game information is inappropriate in determining whether it is appropriate or inappropriate, the setting value set by the setting change control means will be changed. The game is configured so that the game cannot proceed without suggesting setting value information. This makes it possible to ensure security.

In order to solve the fourth problem described above, a gaming machine according to appendix 4-2 having the following configuration is provided.

(1) The gaming machines listed in Appendix 4-2 are:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
A starting port provided in the gaming area (for example, a first starting port 420, a second starting port 440),
A lottery means (for example, a main CPU 101 capable of executing the processes of step S73, step S83, and step S118) that performs a lottery based on the game ball being received in the starting slot;
Display means (for example, a first special symbol display section 73, a second special symbol display section 74) for displaying symbols in a variable manner based on the result of the lottery;
A game control means capable of controlling the progress of the game (for example, the jackpot game control shown in FIG. The main CPU 101) that executes
Settings for setting values set by the setting change control means based on the fulfillment of a predetermined condition related to acceptance of game balls into the starting port (for example, the overflow point has reached a predetermined point, etc.) a setting suggestion means (for example, host control circuit 2100) capable of suggesting value information;
It is characterized by having the following.

According to the gaming machine of (1) above, the current setting value (the setting value set by the setting change control means) is determined based on the fulfillment of the predetermined conditions related to the acceptance of the game ball into the starting port. Since setting value information can be suggested, it is possible to reduce doubts on the part of the player. In addition, execution of the game is encouraged so that the game ball is received in the starting hole. In addition, "meeting the predetermined conditions related to the acceptance of game balls into the starting slot" means, for example, that even though the gaming balls were accepted at the starting slot, they were held because the holding limit was reached. It is assumed that there are cases where the game balls are accepted at the starting slot but are not held because the holding limit has been reached and the points are accumulated and the points reach a predetermined point. However, it is not limited to these.

(2) In the gaming machine described in (1) above,
Stores game information related to the progress of the game including the setting values set by the setting change control means (for example, the number of pending memories stored in the pending storage means, lottery results regarding pending memories and variable displays, and setting values). Possible game information storage means (for example, RWM (main RAM 103)),
Appropriateness determining means (main CPU 101 that performs the processing of steps S72 and S82) for determining whether the game information stored in the game information storage means is appropriate or inappropriate at a predetermined timing;
Furthermore,
The game control means is
If the game information stored in the game information storage means is determined to be inappropriate by the suitability determining means, there is a possibility that the predetermined condition will be satisfied when the game ball is received in the starting port ( For example, even if the overflow point reaches a predetermined point, etc.), the game progress disallowing means (for example, , a main CPU 101) that executes the process of step S722.

According to the gaming machine of (2) above, when the symbols are displayed in a variable manner, it may be determined whether the gaming information stored in the gaming information storage means is appropriate or inappropriate. In this case, even if there is a possibility that the predetermined conditions will be met if the game ball is accepted into the starting port, in determining whether the game information is appropriate or not based on the game ball being received into the starting port, If it is determined that the setting value is inappropriate, the game is not allowed to proceed without suggesting setting value information regarding the setting value set by the setting change control means. This makes it possible to ensure security.

According to the gaming machine of appendix 4-1 and the gaming machine of appendix 4-2 having the above configurations, it is possible to suitably suppress a decrease in interest while changing the state of the gaming elements according to the settings.

[11-5. Gaming machines in Appendix 5]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a predetermined condition is met, and an effect image is displayed on, for example, a liquid crystal display based on the result of the lottery. If the lottery result is a jackpot, a jackpot game is started and the jackpot opens and closes in a predetermined opening and closing pattern. If the above-mentioned jackpot is a variable probability jackpot, after the jackpot game ends, the game is controlled to a high probability gaming state.

As this type of gaming machine, game setting values are input in advance by a predetermined setting input means to determine the state of gaming elements (structural elements and control elements) that affect the rate of balls entering the entrance and the tendency of balls to come out. A pachinko game machine that is set to a state corresponding to the above has been disclosed (for example, see Japanese Patent Laid-Open No. 2015-065977).

According to the gaming machine described in JP-A No. 2015-065977, the ball payout tendency for each gaming machine can be arbitrarily set, making it impossible to adjust or maintain the gaming board configuration such as game nails and accessories. Even if this is the case, it is possible to prevent the ball payout tendency from becoming uniform from game to game parlor or from game to game machine to game machine.

(Fifth issue)
However, according to the gaming machine described in Japanese Unexamined Patent Publication No. 2015-065977, although it is possible to arbitrarily set the ball payout tendency for each gaming machine, there is a risk that ball payout management will not be easy.

The present invention has been made in view of such points, and its purpose is to provide a gaming machine that can easily manage ball output.

In order to solve the fifth problem described above, a gaming machine according to appendix 5 having the following configuration is provided.

(1) The gaming machine set forth in Appendix 5 is:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), data related to the progress of the game is a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can be set to any one of a plurality of different setting values (for example, six levels of setting values from setting 1 to setting 6);
a game control means (for example, main CPU 101) that controls the progress of the game based on the setting values set by the setting change control means;
A payout means (for example, payout device 350) that pays out game media based on winnings as a result of the game;
A special game execution means (for example, a special game execution means (for example, A main CPU 101) that executes the jackpot game control in FIG. 20,
a data aggregation means (for example, a payout/launch control circuit 300) capable of aggregating data related to game media paid out by the payout means;
data display control means (main CPU 101) for displaying data aggregated by the data aggregation means in a predetermined display area (performance display monitor 334);
Equipped with
The data aggregation means is
All history aggregation means for aggregating the data based on all gaming history;
a setting value-specific history aggregation means for aggregating the data based on the gaming history for each setting value;
The data display control means includes:
It is characterized in that it is configured to be able to display the data compiled by the total history totaling means and/or the data compiled by the setting value-by-setting history totaling means.

According to the gaming machine of (1) above, it is possible to display either or both of the data aggregated by the total history aggregation means and the data aggregated by the setting value-specific history aggregation means. It becomes possible to manage balls easily.

According to the gaming machine of appendix 5 having the above configuration, it is an object of the present invention to provide a gaming machine that can easily manage the ball output.

[11-6. Gaming machines in Appendix 6]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a predetermined condition is met, and an effect image is displayed on, for example, a liquid crystal display based on the result of the lottery. If the lottery result is a jackpot, a jackpot game is started and the jackpot opens and closes in a predetermined opening and closing pattern. If the above-mentioned jackpot is a variable probability jackpot, after the jackpot game ends, the game is controlled to a high probability gaming state.

As this type of gaming machine, a gaming machine whose specifications can be changed has been disclosed (for example, see Japanese Patent Laid-Open No. 2011-010833).

According to the gaming machine described in JP-A No. 2011-010833, the specifications of the gaming machine can be easily changed, so it is possible to easily change the storage means that stores the performance data necessary for executing the performance. is no longer necessary, and it is possible to eliminate waste.

(Sixth issue)
However, although it is possible to eliminate waste according to the gaming machine described in Japanese Patent Application Laid-open No. 2011-010833, there is a risk that the game will lack interest if only the specifications are changed.

The present invention has been made in view of such points, and its purpose is to provide a gaming machine that can suppress a decline in interest.

In order to solve the above-mentioned sixth problem, a gaming machine according to appendix 6 having the following configuration is provided.
(1) The gaming machine set forth in Appendix 6 is:
Based on a predetermined operation (for example, pressing the backup clear switch 330 and turning on the power switch 35 while the setting key 328 is turned on when the power is not turned on), the game quality is adjusted according to the set value. a setting change control means (for example, the main CPU 101 capable of executing the process of step S24) that can set any one of a plurality of different setting values (for example, six setting values of setting 1 to setting 6);
a game control means (for example, main CPU 101) that controls the progress of the game based on the setting values set by the setting change control means;
Equipped with
The game control means is
a lottery means capable of executing a lottery (for example, the processes of step S73, step S83, and step S118) based on the game nature according to the setting value set by the setting change control means;
A special game execution means capable of executing a special game (for example, jackpot game control in FIG. 20) in which a benefit is given according to the setting value set by the setting change control means based on the result of the lottery;
It is characterized by having at least the following.

According to the gaming machine described in (1) above, it becomes possible to execute games with different game characteristics based on the setting values set by the setting change control means, and the game machine management manager etc. It becomes possible to have more flexibility in how the gaming machine is utilized.

(2) In the gaming machine described in (1) above,
The game control means is
When set to the first setting value among the plurality of setting values, in a high probability state where the lottery is held with a relatively high probability, if the lottery is not won within a predetermined period, the high probability state is set. a first game control means (for example, the main CPU 101) that executes the game under a game characteristic (for example, ST specification) that ends the game;
When set to the second setting value among the plurality of setting values, in a high probability state in which the lottery is held with a relatively high probability, the high probability state does not end until the lottery is won. a second game control device (for example, the main CPU 101) that executes the game under a continuous game nature (for example, a variable loop specification);
It is characterized by having at least the following.

According to the gaming machine of (2) above, although both the game characteristics by the first game control means and the game characteristics by the second game control means are controlled to a high probability game state, the first game control means In the game style by the second game control means, the high probability game state may end midway without continuing until the next jackpot game state, and in the game style by the second game control means, the high probability game state is controlled to the next special game state. The major difference is that it continues to run until the end. In this way, by making it possible to switch between two seemingly similar but substantially different game features, it is possible to increase the flexibility in how pachinko machines can be used by game machine managers and others. It is possible to provide a gaming machine that can improve interest.

According to the gaming machine of appendix 6 having the above configuration, it is possible to provide a gaming machine that can suppress a decline in interest.

[11-7. Each gaming machine in Appendix 7-1 to Appendix 7-12]
Conventionally, gaming machines have been known that perform a lottery when a predetermined condition is met, and display symbols variably based on the results of the lottery. Then, when a specific display result indicating that the lottery result is a specific result is displayed, the gaming state is controlled to be advantageous to the player.

In this type of gaming machine, any one of a plurality of setting values indicating the probability related to the advantage or disadvantage of the player in the game, such as the probability that the result of the lottery will be a specific result, is set, and from then on, A gaming machine in which the progress of a game is controlled based on set values is known (see, for example, paragraph [0063] of Japanese Patent Laid-Open No. 2011-206588). The above setting values can be set by an authorized person, such as a gaming machine manager of a hall, for example.

(Seventh issue)
However, in gaming machines where the progress of the game is controlled based on the set values, for example, the set values may be changed or checked illegally by an unauthorized person, or the set values may be changed due to noise etc. There are concerns that various problems may occur, such as changes in the

Further, since the above setting values are important factors for both the hall and the players, they should be strictly managed by an authorized person, and convenience is also required for the management.

The present invention has been made in view of such points, and its purpose is to provide a highly convenient gaming machine that can deal with problems related to setting values.

In order to solve the seventh problem described above, a gaming machine according to appendix 7-1 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-1 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being operated (for example, the setting key is in the ON state), setting state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
A transmitting means (for example, , a command output port 106 and a main CPU 101 capable of executing the process of step S55,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) and a second storage means (for example, sub-work RAM 2100a) capable of storing the information as historical information;
The present invention is characterized by comprising display control means (for example, display control circuit 2300) capable of displaying an information screen (for example, a setting change/confirmation history screen) on which the history information is shown based on a predetermined operation.

According to the gaming machine of (1) above, by performing a predetermined operation, it is possible to view the information screen in which setting operation information and time information related to the setting operation information are shown as history information. It becomes possible to deal with various problems related to values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

Note that the setting operation information is setting value change information that indicates that the setting value has been changed when the setting value has been changed, and is setting value change information that indicates that the setting value has been changed. This is setting value confirmation information indicating that the setting value has been set. Further, when the setting operation information is setting value change information, the setting value information is setting value information regarding one setting value after the change. When the setting operation information is setting value confirmation information, setting value information regarding the first setting value that has been set may be sent to the second control means, but the first setting value has not been changed. Therefore, it is not essential to transmit the setting value information to the second control means.

Further, "time information related to the setting operation information" may be time information when the setting operation information was transmitted from the first control means to the second control means, or time information when the setting operation information was received by the second control means. It may be time.

(2) In the gaming machine described in (1) above,
The display control means includes:
an information screen that is capable of displaying the information screen when the power is turned on while the setting operation means is operated, and that restricts display of the information screen even if the predetermined operation is performed during the execution of the game; A restriction means (for example, the host control circuit 2100 that terminates the hall menu task when the determination is NO in step S301, and the host control circuit 2100 that executes the process of step S317 when the determination is YES in step S316). Features.

According to the gaming machine described in (2) above, the information screen is a screen that is displayed when the power is turned on while the setting operation means is operated, and during the execution of the game, it is assumed that a predetermined operation has been performed. This is also a screen whose display is restricted. That is, unless the power is turned on while the setting operation means is being operated (for example, the setting key is in the ON state), the information screen will not be displayed. Therefore, it is difficult for an unauthorized third party to easily view the information screen for fraudulent purposes, and security can be ensured.

In order to solve the seventh problem described above, a gaming machine according to appendix 7-2 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-2 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being operated (for example, the setting key is in the ON state), setting state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
Various information can be transmitted to the second control means, and at least setting operation information (for example, a setting operation command) indicating that the one setting value has been changed or confirmed, and regarding the one setting value. and a transmitting means (for example, the command output port 106 and the main CPU 101 capable of executing the process of step S55) that can transmit the setting value information,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) and a second storage means (for example, sub-work RAM 2100a) capable of storing the set value information as history information;
a display control means (for example, display control circuit 2300) capable of displaying an information screen in which the history information is shown based on a predetermined operation;
The display control means includes:
a first screen display control means for displaying a first screen (for example, the setting change/confirmation history screen of FIG. 124) on which history information that does not include the setting value information among the history information is shown based on the predetermined operation; (For example, the host control circuit 2100 that displays the setting change/confirmation history screen in FIG. 124);
a second screen display control means for displaying a second screen (for example, the setting change/confirmation history screen of FIG. 126) on which history information including at least the setting value information is shown, on the condition that the first screen is displayed; (For example, a host control circuit 2100 that displays a setting change/confirmation history screen in FIG. 126).

According to the gaming machine of (1) above, by performing a predetermined operation, it is possible to view an information screen in which setting operation information, time information related to the setting operation information, and setting value information are shown as history information. This makes it possible to deal with various problems related to setting values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

Moreover, when a predetermined operation is performed, a first screen (for example, the setting change/confirmation history screen in FIG. 124) is displayed that shows history information that does not include setting value information among the history information, and The configuration is such that, on the condition that the screen is displayed, a second screen (for example, the setting change/confirmation history screen in FIG. 126) showing history information including setting value information is displayed.

Note that the transmitting means capable of transmitting various information to the second control means may transmit the setting operation information and the setting value information together or separately. Setting operation information is setting value change information that indicates that the setting value has been changed when the setting value has been changed, and setting value change information that indicates that the setting value has been confirmed when the setting value has been confirmed. This is setting value confirmation information indicating that the Further, when the setting operation information is setting value change information, the setting value information is setting value information regarding one setting value after the change. When the setting operation information is setting value confirmation information, setting value information regarding the first setting value that has been set may be sent to the second control means, but the first setting value has not been changed. Therefore, it is not essential to transmit the setting value information to the second control means.

Further, "time information related to the setting operation information" may be time information when the setting operation information was transmitted from the first control means to the second control means, or time information when the setting operation information was received by the second control means. It may be time.

(2) In the gaming machine described in (1) above,
The second screen display control means includes:
The second screen is characterized in that it is configured to be displayed only when specific conditions are met.

According to the gaming machine described in (2) above, the second screen showing history information including setting value information is displayed only when specific conditions are met, so that setting value information can be easily viewed. This prevents setting value information from being viewed for fraudulent purposes. Note that the specific condition is, for example, a case where a proper password is input.

(3) In the gaming machine of (1) or (2) above,
The display control means includes:
Information that allows the information screen to be displayed when the power is turned on while the setting operation means is operated, and that restricts the display of the information screen during game play even if the predetermined operation is performed. It is characterized by having a screen restriction means.

According to the gaming machine (3) above, the information screen is a screen that is displayed when the power is turned on while the setting operation means is being operated, and during the execution of the game, it is assumed that a predetermined operation has been performed. This is also a screen whose display is restricted. That is, unless the power is turned on while the setting operation means is being operated (for example, the setting key is in the ON state), the information screen will not be displayed. Therefore, it is difficult for an unauthorized third party to easily view the information screen for fraudulent purposes, and security can be ensured.

In order to solve the seventh problem described above, a gaming machine according to appendix 7-3 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-3 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being operated (for example, the setting key is in the ON state), setting state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
A transmitting means (for example, , a command output port 106 and a main CPU 101 capable of executing the process of step S55,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) are a second storage means (for example, sub-work RAM 2100a) capable of storing as history information;
a display control means capable of displaying an information screen (for example, a setting change/confirmation history screen) on which the history information is shown based on a predetermined operation;
After the information screen is displayed, the information screen can be displayed until a predetermined condition is met (for example, until a command to generate a production control object is received); however, when the predetermined condition is met, the information The present invention is characterized in that it has an information screen display restriction means (for example, the host control circuit 2100 that executes the hall menu display prohibition process in step S318) that restricts the display of the screen.

According to the gaming machine of (1) above, by performing a predetermined operation, it is possible to view the information screen in which setting operation information and time information related to the setting operation information are shown as history information. It becomes possible to deal with various problems related to values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

Furthermore, although the displayed information screen can be displayed until a predetermined condition is met, the display is restricted when the predetermined condition is met. Therefore, once the predetermined conditions are met, the information screen cannot be viewed, so even if an unauthorized person attempts to do so, it will not be possible to do so, ensuring security. becomes.

Note that the setting operation information is setting value change information that indicates that the setting value has been changed when the setting value has been changed, and is setting value change information that indicates that the setting value has been changed. This is setting value confirmation information indicating that the setting value has been set. Further, when the setting operation information is setting value change information, the setting value information is setting value information regarding one setting value after the change. When the setting operation information is setting value confirmation information, setting value information regarding the first setting value that has been set may be sent to the second control means, but the first setting value has not been changed. Therefore, it is not essential to transmit the setting value information to the second control means.

Further, "time information related to the setting operation information" may be time information when the setting operation information was transmitted from the first control means to the second control means, or time information when the setting operation information was received by the second control means. It may be time.

In order to solve the seventh problem described above, a gaming machine according to appendix 7-4 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-4 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being operated (for example, the setting key is in the ON state), setting state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
A transmitting means (for example, , a command output port 106 and a main CPU 101 capable of executing the process of step S55,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) and a second storage means (for example, sub-work RAM 2100a) capable of storing the information as historical information;
A normal screen (e.g., initial guide image) that can be viewed by unspecified persons (e.g., the player), and a normal screen (e.g., the initial guide image) that can be viewed by unspecified persons (e.g., the gaming machine administrator); Display control means (e.g., display control circuit 2300) capable of displaying any one of a plurality of screens including an information screen (e.g., setting change/confirmation history screen) on which history information is shown on the display means; , has
The display control means includes:
The normal screen can be displayed as long as the power is turned on, while the information screen can be displayed at least when the power is turned on while the setting operation means is being operated (for example, the setting key is in the ON state). It is characterized by being configured to be displayed on the screen.

According to the gaming machine of (1) above, the predetermined display means includes a normal screen that can be viewed by an unspecified person (for example, a player) and a normal screen that can be viewed by an unspecified person (for example, a gaming machine administrator). An information screen that can only be viewed is displayed. While the normal screen can be displayed as long as the power is turned on, the information screen will not be displayed just when the power is turned on, but at least when the power is turned on while the setting operation means is being operated. It is configured so that it will not be displayed if it is not available. Therefore, the information screen cannot be easily viewed by unspecified persons without authority, and unauthorized viewing can be prevented.

By the way, the above normal screen may not be interpreted as being viewable by unspecified persons if, for example, only players who have registered as members can view it, but as long as they register as members, Since anyone can view the screen (that is, as long as there is an intention to view it), it can be said that it is a normal screen that can be viewed by an unspecified person. On the other hand, the information screen cannot be viewed even if there is an intention to view it, and is a screen that can only be viewed by a person with authority, such as a gaming machine administrator, for example.

Furthermore, on the information screen that can only be viewed by a specific person, setting operation information and time information related to the setting operation information are shown as history information, making it possible to deal with various problems related to setting values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

Note that the setting operation information is setting value change information that indicates that the setting value has been changed when the setting value has been changed, and is setting value change information that indicates that the setting value has been changed. This is setting value confirmation information indicating that the setting value has been set. Further, when the setting operation information is setting value change information, the setting value information is setting value information regarding one setting value after the change. When the setting operation information is setting value confirmation information, setting value information regarding the first setting value that has been set may be sent to the second control means, but the first setting value has not been changed. Therefore, it is not essential to transmit the setting value information to the second control means.

Further, "time information related to the setting operation information" may be time information when the setting operation information was transmitted from the first control means to the second control means, or time information when the setting operation information was received by the second control means. It may be time.

(2) In the gaming machine described in (1) above,
The display control means includes:
When the power is turned on while the setting operation means is operated, the information screen can be displayed, and the information screen restriction means (for example, if NO is selected in step S301) that restricts the display of the information screen while the game is being played. The host control circuit 2100 terminates the hall menu task when the determination is made, and the host control circuit 2100 executes the process of step S317 when the determination is YES in step S316.

According to the gaming machine described in (2) above, the information screen is a screen that is displayed when the power is turned on while the setting operation means is operated, and during the execution of the game, it is assumed that a predetermined operation has been performed. This is also a screen whose display is restricted. That is, unless the power is turned on while the setting operation means is being operated (for example, the setting key is in the ON state), the information screen will not be displayed. Therefore, it is difficult for an unauthorized third party to easily view the information screen for fraudulent purposes, and security can be ensured.

In order to solve the above seventh problem, a gaming machine according to appendix 7-5 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-5 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being operated (for example, the setting key is in the ON state), setting state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
A transmitting means (for example, , a command output port 106 and a main CPU 101 capable of executing the process of step S55,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) and a second storage means (for example, sub-work RAM 2100a) capable of storing the information as historical information;
Display control means (for example, display control circuit 2300) capable of displaying an information screen (for example, a setting change/confirmation history screen) on which the history information is shown based on a predetermined operation;
information erasing means (for example, a host control circuit 2100 that executes processes such as step S3066 and step S3160) that erases the history information from the second storage means when a specific operation is received;
The information erasing means is
The device is characterized in that it is configured to accept the specific operation only when specific conditions are met.

According to the gaming machine of (1) above, by performing a predetermined operation, it is possible to view the information screen in which setting operation information and time information related to the setting operation information are shown as history information. It becomes possible to deal with various problems related to values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

Moreover, when a specific operation (for example, pressing the main button 662 after selecting the "Clear" item) is accepted, the history information is erased. Acceptance is possible only when conditions are met (for example, when the entered password is correct). Therefore, for example, even if an unauthorized person tries to erase the history of changing, checking, or viewing setting values for fraudulent purposes, such erasure will not be possible unless certain conditions are met. Therefore, it is possible to prevent fraudulent history from being intentionally deleted. Further, for those who have authority, the history information can be deleted, which increases convenience.

Note that the setting operation information is setting value change information that indicates that the setting value has been changed when the setting value has been changed, and is setting value change information that indicates that the setting value has been changed. This is setting value confirmation information indicating that the setting value has been set. Further, when the setting operation information is setting value change information, the setting value information is setting value information regarding one setting value after the change. When the setting operation information is setting value confirmation information, setting value information regarding the first setting value that has been set may be sent to the second control means, but the first setting value has not been changed. Therefore, it is not essential to transmit the setting value information to the second control means.

Further, "time information related to the setting operation information" may be time information when the setting operation information was transmitted from the first control means to the second control means, or time information when the setting operation information was received by the second control means. It may be time.

(2) In the gaming machine described in (1) above,
The transmitting means includes:
It is further possible to transmit setting value information regarding the first setting value,
The second storage means is
The setting value information can also be stored as the history information, and
The display control means includes:
It is possible to display an information screen in which the setting value information is included in the history information (for example, the setting change/confirmation history screen in FIG. 126);
The information erasing means is
It is characterized in that it is configured to delete history information including the setting value information from the second storage means.

According to the gaming machine (2) above, when the information screen is displayed, it becomes possible to view more useful information such as setting value information. Moreover, since such useful information can be deleted by an authorized person, convenience can be improved.

Note that the transmitting means may transmit the setting operation information and the setting value information together or separately.

(3) In the gaming machine described in (1) or (2) above,
The information erasing means is
In erasing the history information from the second storage means, only a part of the history information stored in the second storage means as history information can be deleted.

According to the gaming machine of (3) above, convenience is improved because an authorized person can select which historical information to delete from among the historical information stored in the second storage means. For example, in the history information, one setting operation information, one date and time information, and one setting value information are displayed in association with each other (for example, see FIG. 126). The information erasing means may erase the associated history information (for example, for each No. shown in FIG. 126), or may erase each item among multiple items of information included in the history information ( For example, all of the date and time items, operation type items, and setting value items shown in FIG. 126 may be deleted.

In order to solve the seventh problem described above, a gaming machine according to appendix 7-6 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-6 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being operated (for example, the setting key is in the ON state), setting state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
A transmitting means (for example, , a command output port 106 and a main CPU 101 capable of executing the process of step S55,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) and a second storage means (for example, sub-work RAM 2100a) capable of storing the information as historical information;
a display control means (for example, display control circuit 2300) capable of displaying an information screen in which the history information is shown based on a predetermined operation;
The setting operation information is
The information is information that can distinguish the type of operation, such as information indicating that the first setting value has been changed or information indicating that the first setting value has been confirmed. ,
The display control means includes:
a list information screen (for example, a list screen) in which all of the setting operation information, the time information, and the setting value information are shown as history information, regardless of the type of the setting operation information;
It is possible to selectively display a specific information screen (for example, a narrowing screen) in which the setting operation information, the time information, and the setting value information corresponding to a specific type of the setting operation information are shown as history information. It is characterized by being composed of the following.

According to the gaming machine of (1) above, by performing a predetermined operation, it is possible to view the information screen in which setting operation information and time information related to the setting operation information are shown as history information. It becomes possible to deal with various problems related to values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

Moreover, regardless of the type of setting operation information, an information screen with a list showing all of the setting operation information, the time information, and the setting value information as history information, and a screen corresponding to a specific type of setting operation information, Since the setting operation information, the time information, and the setting value information can be selectively displayed on a specific information screen in which the setting value information is shown as history information, convenience for the operator (for example, a gaming machine manager) can be improved. Can be done.

Note that the setting operation information is setting value change information that indicates that the setting value has been changed when the setting value has been changed, and is setting value change information that indicates that the setting value has been changed. This is setting value confirmation information indicating that the setting value has been set. Further, when the setting operation information is setting value change information, the setting value information is setting value information regarding one setting value after the change. When the setting operation information is setting value confirmation information, setting value information regarding the first setting value that has been set may be sent to the second control means, but the first setting value has not been changed. Therefore, it is not essential to transmit the setting value information to the second control means.

Further, "time information related to the setting operation information" may be time information when the setting operation information was transmitted from the first control means to the second control means, or time information when the setting operation information was received by the second control means. It may be time.

(2) In the gaming machine described in (1) above,
The display control means includes:
The present invention is characterized in that the information screen in the list and the specific information screen can be selectively displayed only when specific conditions are met.

According to the gaming machine described in (2) above, the list information screen and the specific information screen can be selectively displayed only when specific conditions are met, so history information cannot be viewed for fraudulent purposes. This can be suppressed. Note that the specific condition is, for example, a case where a proper password is input.

(3) In the gaming machine of (1) or (2) above,
The transmitting means includes:
It is further possible to transmit setting value information regarding the first setting value,
The second storage means is
The setting value information can also be stored as the history information, and
The display control means includes:
The present invention is characterized in that it is configured to be able to display an information screen in which the setting value information is included in the history information.

According to the gaming machine (3) above, when the information screen is displayed, it becomes possible to view more useful information such as setting value information. Moreover, since such useful information can be deleted by an authorized person, convenience can be improved.

Note that the transmitting means may transmit the setting operation information and the setting value information together or separately.

In order to solve the above seventh problem, a gaming machine according to appendix 7-7 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-7 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being operated (for example, the setting key is in the ON state), setting state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
A transmitting means (for example, , a command output port 106 and a main CPU 101 capable of executing the process of step S55,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) and a second storage means (for example, sub-work RAM 2100a) capable of storing the information as historical information;
Based on a predetermined operation, a normal screen (for example, a hall menu screen) on which the history information is not displayed can be displayed, and when a predetermined operation is performed on the normal screen, an information screen (for example, a hall menu screen) on which the history information is displayed can be displayed. For example, display control means (for example, display control circuit 2300) capable of displaying a setting change/confirmation history screen);
Although the information screen can be displayed until a predetermined condition is met (for example, until YES is determined in step S314, step S315, or step S316), when the predetermined condition is met, the display of the information screen is restricted. information screen display restriction means (for example, a host control circuit 2100 that executes the process of step S317 when the determination is YES in step S314, step S315, or step S316);
The second storage means is
When the information screen is displayed by performing the predetermined operation on the normal screen, a viewing history indicating that the information screen was viewed can be stored as one of the history information,
Even if the information screen is displayed multiple times by performing the predetermined operation on the normal screen until the display of the information screen is restricted, it will be treated as one viewing history. It is characterized by being configured to memorize.

According to the gaming machine of (1) above, by performing a predetermined operation, it is possible to view the information screen in which setting operation information and time information related to the setting operation information are shown as history information. It becomes possible to deal with various problems related to values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

Further, although the information screen can be displayed until a predetermined condition is met, the display is restricted when the predetermined condition is met. Therefore, it is difficult for an unauthorized third party to easily view the information screen for fraudulent purposes, and security can be ensured.

Further, the information screen is displayed by performing a predetermined operation on the normal screen. At this time, the viewing history is stored in the second storage means. However, even if the information screen is displayed multiple times by performing certain operations on the normal screen until the information screen display is restricted, it will be recorded as one setting history information. be done. This makes it difficult for a person who has changed settings, confirmed settings, viewed information screens, etc. for fraudulent purposes to intentionally create a large number of viewing histories. In particular, in the case of viewing history, unlike changing or checking setting values, it can be viewed multiple times without going through the process of turning on the power while the setting operation means is operated (for example, the setting key is in the ON state). The effect is great because it is possible to create a large number of histories intentionally.

Note that the setting operation information is setting value change information that indicates that the setting value has been changed when the setting value has been changed, and is setting value change information that indicates that the setting value has been changed. This is setting value confirmation information indicating that the setting value has been set. Further, when the setting operation information is setting value change information, the setting value information is setting value information regarding one setting value after the change. When the setting operation information is setting value confirmation information, setting value information regarding the first setting value that has been set may be sent to the second control means, but the first setting value has not been changed. Therefore, it is not essential to transmit the setting value information to the second control means.

Further, "time information related to the setting operation information" may be time information when the setting operation information was transmitted from the first control means to the second control means, or time information when the setting operation information was received by the second control means. It may be time.

In order to solve the seventh problem described above, a gaming machine according to appendix 7-8 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-8 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being operated (for example, the setting key is in the ON state), setting state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
Various information can be transmitted to the second control means, and at least setting operation information (for example, a transmission means (for example, a command output port 106 or a main CPU 101 capable of executing the process of step S55) capable of transmitting a setting operation command);
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) a second storage means (for example, sub-work RAM 2100a) capable of storing the information as history information including setting change history information or setting confirmation history information;
Based on a predetermined operation, a normal screen (for example, a hall menu screen) on which the history information is not displayed can be displayed, and when a predetermined operation is performed on the normal screen, an information screen (for example, a hall menu screen) on which the history information is displayed can be displayed. For example, a display control means (for example, a display control circuit 2300) capable of displaying a setting change/confirmation history screen);
The second storage means is
When the information screen is displayed by performing the predetermined operation on the normal screen, viewing history information indicating that the information screen has been viewed can be stored as one of the history information,
Furthermore, when the power is turned on with the setting operation means being operated,
When the first setting value is confirmed and the information screen is viewed, both the setting confirmation history information and the viewing history information are displayed;
When the first setting value is changed and the information screen is viewed, only the viewing history information of the setting change history information and the viewing history information is displayed. Features.

According to the gaming machine of (1) above, by performing a predetermined operation, it is possible to view the information screen in which setting operation information and time information related to the setting operation information are shown as history information. It becomes possible to deal with various problems related to values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

By the way, when fraud involving setting changes is committed, it is possible to detect the possibility of fraud based on the setting change history that is not remembered by the gaming machine manager. It is difficult to detect the possibility of fraud just by looking at the configuration confirmation history. Furthermore, it is thought that those who commit fraud mainly view the site after confirming the settings, rather than viewing the site after changing the settings. Therefore, when the power is turned on with the setting operation means being operated and the first setting value is confirmed and the information screen is viewed, both the setting confirmation history information and the viewing history information is displayed, and when one setting value is changed and the information screen is viewed, only the viewing history information of the setting change history information and viewing history information is displayed. This makes it possible to minimize the amount of history information displayed on the display means, and prevents the total number of histories from increasing unnecessarily and making it difficult to discover fraud.

Note that "When the first setting value is changed and the information screen is viewed, only the viewing history information of the setting change history information and the viewing history information is displayed" means " By storing only the browsing history information of the setting change history information and the browsing history information in the second storage means, it is possible to display a mode in which only the browsing history information is displayed and a mode in which both the setting change history information and the browsing history information are displayed. Although it is stored in the second storage means, only the viewing history information among these pieces of information is displayed under the control of the display control means. However, from the viewpoint of reducing the load on the second storage means Therefore, the former is preferable.

Further, "time information related to the setting operation information" may be time information when the setting operation information was transmitted from the first control means to the second control means, or time information when the setting operation information was received by the second control means. It may be time.

In order to solve the above seventh problem, a gaming machine according to appendix 7-9 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-9 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being operated (for example, the setting key is in the ON state), setting state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
A transmitting means (for example, , a command output port 106 and a main CPU 101 capable of executing the process of step S55,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) and a second storage means (for example, sub-work RAM 2100a) capable of storing the information as historical information;
Display control means (for example, display control circuit 2300) capable of displaying an information screen (for example, a setting change/confirmation history screen) on which the history information is shown based on a predetermined operation;
When the amount of history information stored in the second storage means exceeds a predetermined amount, history deletion means (for example, , a host control circuit 2100) that executes the process of step S306.

According to the gaming machine of (1) above, by performing a predetermined operation, it is possible to view the information screen in which setting operation information and time information related to the setting operation information are shown as history information. It becomes possible to deal with various problems related to values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

By the way, the above history information is stored in the second storage means (for example, sub-work RAM 2100a), but since there is an upper limit to the amount of history information that can be stored in the second storage means, the history information is not stored in the second storage means. If the amount of history information stored increases, there is a risk that a situation may occur in which history information cannot be recorded in the second storage means when it is desired to be recorded. Therefore, when the history information stored in the second storage means exceeds a predetermined amount, new history information is recorded by erasing at least a part of the history information stored in the second storage means. This prevents situations in which it is not possible to do so.

Note that "when the amount of history information stored in the second storage means exceeds a predetermined amount, at least a part of the history information stored in the second storage means is erased" refers to the second storage means. The history information may be erased as a result by overwriting the history information already stored in the storage means with new history information, or the new history information may be stored in the second storage means. If there is a possibility that the predetermined amount will be exceeded, at least a part of the history information stored in the second storage means may be erased before storing the history information. Further, even if new history information is not stored in the second storage means, when there is a risk that the upper limit will be exceeded if more history information is stored in the second storage means, the new history information is stored in the second storage means. At least a portion of the historical information may be deleted.

In addition, the setting operation information is setting value change information indicating that the setting value has been changed when the setting value has been changed, and setting value change information that indicates that the setting value has been changed when the setting value has been confirmed. This is setting value confirmation information indicating that the setting value has been set. Further, when the setting operation information is setting value change information, the setting value information is setting value information regarding one setting value after the change. When the setting operation information is setting value confirmation information, setting value information regarding the first setting value that has been set may be sent to the second control means, but the first setting value has not been changed. Therefore, it is not essential to transmit the setting value information to the second control means.

Further, "time information related to the setting operation information" may be time information when the setting operation information was transmitted from the first control means to the second control means, or time information when the setting operation information was received by the second control means. It may be time.

(2) In the gaming machine described in (1) above,
The display control means includes:
Information that allows the information screen to be displayed when the power is turned on while the setting operation means is operated, and that restricts display of the information screen during game play even if the predetermined operation is performed. It has a screen restriction means (for example, the host control circuit 2100 that terminates the hall menu task when the determination is NO in step S301, and the host control circuit 2100 that executes the process of step S317 when the determination is YES in step S316). It is characterized by

According to the gaming machine described in (2) above, the information screen is a screen that is displayed when the power is turned on while the setting operation means is operated, and during the execution of the game, it is assumed that a predetermined operation has been performed. This is also a screen whose display is restricted. That is, unless the power is turned on while the setting operation means is being operated (for example, the setting key is in the ON state), the information screen will not be displayed. Therefore, it is difficult for an unauthorized third party to easily view the information screen for fraudulent purposes, and security can be ensured.

In order to solve the seventh problem described above, a gaming machine according to appendix 7-10 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-10 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on while at least the setting operation means is operated (for example, the setting key is in the ON state), the setting change state in which the first set value can be changed or the first set value is confirmed. a setting state control means (for example, the main CPU 101 capable of executing the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
a transmitting means (e.g., It has a command output port 106 and a main CPU 101 that can execute the process of step S55,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) and a second storage means (for example, sub-work RAM 2100a) capable of storing the information as historical information;
An information screen (for example, a settings change/confirmation history screen) in which the history information is shown in the settings change state and/or the settings confirmation state can be displayed on the display means, and the settings change state and/or the settings a display control means (for example, a display control circuit 2300) capable of restricting the display of the information screen so that the information screen is not displayed when the confirmation state ends;
The display control means includes:
At least when the setting change state ends, the information screen can be displayed without restricting the display of the information screen until a predetermined period of time has passed even if the setting change state ends (for example, step S312, step S313 ), and
Even if the setting change state ends, as long as a predetermined operation related to the information screen is performed on the information screen displayed after the setting change state ends, the display of the information screen can be controlled so as not to be restricted ( The process is characterized in that the processing from step S313 to step S316 can be repeated).

According to the gaming machine of (1) above, it is possible to view at least an information screen in which setting operation information and time information related to the setting operation information are shown as history information, so various problems related to setting values can be solved. It becomes possible to correspond to In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

Further, since the above information screen is displayed in a setting change state and/or a setting confirmation state, security is ensured such that, for example, an unauthorized third party cannot easily view the information screen. Moreover, at least when controlled to change the settings state, the display of the information screen is not restricted until a predetermined period of time has elapsed after the end of the settings change state, as long as a predetermined operation on the information screen is performed. , it is also possible to improve convenience for the operator.

(2) In the gaming machine described in (1) above,
The transmitting means includes:
When at least the one setting value is changed, setting value information regarding the one setting value can also be transmitted;
The display control means includes:
In the setting change state and/or the setting confirmation state, an information screen in which setting value information regarding the one setting value is included in the history information can be displayed on the display means.

According to the gaming machine described in (2) above, when displaying the history screen, setting value information regarding the first setting value is also displayed, allowing an authorized person to view more detailed history information. . In particular, since the setting value information regarding the first setting value is useful information for business, it can be useful for hall management.

(3) In the gaming machine described in (1) or (2) above,
The display control means includes:
Even if a predetermined operation related to the information screen is performed on the information screen displayed after the setting change state ends, when specific information related to the progress of the game is received by the receiving means, the information screen The present invention is characterized in that it has a forced termination means (for example, the host control circuit 2100 executes the process of step S317 when the determination in step S316 is YES).

According to the gaming machine described in (3) above, even if a predetermined operation related to the information screen is performed on the information screen, when specific information related to the progress of the game is received by the receiving means, the information screen is forced to be displayed. Since the game ends automatically, the execution of the game is not hindered. Therefore, while ensuring the state in which games can be played, it is possible to ensure the convenience of operations by authorized persons and to suppress fraud by unauthorized third parties.

(4) In the gaming machine described in any of (1) to (3) above,
The information screen displayed after the setting change state is completed is configured so that it can be recognized that the game can be executed without interfering with the predetermined operation on the information screen (e.g. , while the LED 25 is fully lit in white while changing or confirming the settings, the LED 25 is fully lit in red when changing or confirming the settings is completed)
It is characterized by

According to the gaming machine of (4) above, on the information screen displayed after the setting change state is finished, the game can be executed without hindering the predetermined operation on the information screen. Since it is possible to understand that the game is executed, it is possible to prevent the occurrence of a problem in which the game is not executed because the player is unable to grasp it even though the game can be executed.

In order to solve the above seventh problem, a gaming machine according to appendix 7-11 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-11 are:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being operated (for example, the setting key is in the ON state), setting state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute the process of step S24 or step S26),
a first storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
a transmitting means (e.g., It has a command output port 106 and a main CPU 101 that can execute the process of step S55,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) and a second storage means (for example, sub-work RAM 2100a) capable of storing the information as historical information;
Display control means (for example, display control circuit 2300) capable of displaying on the display means an information screen on which various information can be shown (for example, a hall menu screen, a hall menu item screen) in the setting state. death,
The information screen is
A history screen where the history information is shown (for example, a setting change/confirmation history screen), and a non-history screen where the history information is not shown but is displayed by performing a predetermined operation (for example, a hall screen). a plurality of information screens including at least a menu screen);
The display control means includes:
Screen updating means (for example, step A host control circuit 2100) that executes processes such as S3051, S3057, and S3073;
In the setting state, when the non-history screen is displayed, the non-history screen is continuously displayed even if the predetermined operation is not performed (for example, if the hall menu display process in step S302 is executed), the non-history screen is displayed. (If no item is selected in the process of step S303, the hall menu screen continues to be displayed.) On the other hand, when the history screen is displayed, the predetermined operation must be performed for a predetermined period of time or more. For example, the present invention is characterized by having a specific display control means (for example, a host control circuit 2100 that executes the process of step S317 when the determination is YES in step S3072) for controlling the display of the history screen to be terminated. .

According to the gaming machine described in (1) above, it is possible to view at least a history screen in which setting operation information and time information related to the setting operation information are displayed as history information, so that various problems related to setting values can be solved. It becomes possible to correspond to In particular, if there is a possibility that a setting value has been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the history screen can confirm whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

Additionally, non-history screens that do not display history information will continue to be displayed even if no specific operations are performed, but history screens that display historical information will end if a specific operation is not performed for a predetermined period of time. do. Therefore, it is possible to prevent history information from being continuously displayed and being viewed by an unauthorized third party. Note that the above-mentioned "continuous display" includes temporarily terminating the display and re-displaying it. That is, it is important whether the display is displayed or not displayed even if a predetermined operation is not performed for a predetermined period of time or more.

(2) In the gaming machine described in (1) above,
The transmitting means includes:
When at least the one setting value is changed, setting value information regarding the one setting value can also be transmitted;
The display control means includes:
When the history screen is displayed on the display means in the setting state, setting value information regarding the one setting value is also displayed.

According to the gaming machine described in (2) above, when displaying the history screen, setting value information regarding the first setting value is also displayed, allowing an authorized person to view more detailed history information. . In particular, since the setting value information regarding the first setting value is useful information for business, it can be useful for hall management.

In order to solve the seventh problem described above, a gaming machine according to appendix 7-12 having the following configuration is provided.

(1) The gaming machines listed in Appendix 7-12 are:
A controller capable of executing control related to the progress of the game based on any one of the plurality of setting values, and capable of storing information related to the progress of the game including setting value information regarding the one setting value. a first control means (for example, main control circuit 100) having one storage means;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a specific operation means (for example, backup clear switch 330) used to erase information stored in the first storage means;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the specific operation means is operated and the power is turned on while the setting operation means is being operated (for example, a setting key is in the ON state), the setting change state is entered in which the first setting value can be changed. a setting change state control means (for example, the main CPU 101 capable of executing the process of step S24);
Various information can be transmitted to the second control means, and at least setting change information (for example, a setting change start command) indicating that the one setting value is to be changed, and a setting value for the one setting value. When an erasing process for erasing information (for example, setting value information after changing the setting value) and information stored in the first storage means is executed, the erasing process is executed. a transmitting means (for example, the command output port 106 and the main CPU 101 capable of executing the process of step S55) capable of transmitting information indicating that the
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting change information is received by the receiving means, at least the setting change information received by the receiving means and time information related to the setting change information (for example, time information when an initialization command or a power failure recovery command was received) and a second storage means (for example, sub-work RAM 2100a) capable of storing the information as historical information;
information display control means (for example, display control circuit 2300) capable of displaying on the display means an information screen in which the history information is shown at least in the setting change state;
An erasure execution information informing means capable of informing that the erasure process has been executed (for example, a display control circuit 2300, an audio/LED control circuit 2200 that controls the audio output of the speaker 24, and an audio/LED that controls the lighting mode of the LED 25) control circuit 2200);
The erasure execution information notification means includes:
When the erasing process (for example, backup clearing process) is executed without being controlled by the setting change state, a first aspect (for example, within the display area of the display device 16) in which it can be recognized that the erasing process has been executed a first notification means (host control circuit 2100) that provides notification by text display such as "RAM has been cleared", audio output such as "RAM has been cleared", and all red lights of the LED 25;
When the erasing process is executed as a result of being controlled to the setting change state, the second aspect is such that when the erasing process is executed as a result of being controlled to the setting change state, it is more difficult to recognize that the erasing process has been executed than the first aspect so as not to obstruct the visibility of the information screen. A second notification means (for example, without displaying on the display device 16, only with an audio output such as "Settings have been changed. RAM has been initialized" and with the LED 25 all lit in red) A control circuit 2100).

According to the gaming machine described in (1) above, it is possible to view at least an information screen in which setting change information and time information related to the setting change information are displayed as history information, so that various problems related to setting values can be solved. It becomes possible to correspond to In particular, if there is a possibility that settings have been changed for the purpose of fraud by an unauthorized third party, it is possible to trace whether or not the fraud has occurred by viewing the information screen. It becomes possible to do so. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

Furthermore, erasing processing (for example, backup clearing processing) for erasing information stored in the first storage means may be executed without being controlled by the setting change state, or when it is controlled by the setting change state. There are cases where it is executed. When the erasing process is executed without being controlled by the setting change state, it is notified in the first mode that allows you to understand that the erasing process has been executed, so for example, the erasing process is executed by a third party without authority. This makes it possible to prevent this from happening. On the other hand, when the erasing process is executed in response to being controlled to change settings, the main purpose is to change the first setting value, and the erasing process is only executed in conjunction with that. Therefore, the notification is made in the second mode, which is more difficult to understand than the first mode. Furthermore, when the erasing process is executed as a result of being controlled to change settings, an information screen showing history information is displayed, but in the second aspect, the information screen is designed so that visibility of the information screen is not obstructed. Since execution of the erasing process is notified, convenience can also be ensured.

(2) In the gaming machine described in (1) above,
Further comprising an audio output means (for example, a speaker 24) capable of outputting a predetermined audio,
The second control means
further comprising a voice control means (for example, a voice/LED control circuit 2200) capable of controlling the voice output from the voice output means,
The first notification means includes:
Notifying that the erasing process has been executed using both the display means and the audio output means;
The second notification means includes:
It is characterized in that it is configured to notify that the erasure process has been executed using only the voice output means of the display means and the voice output means.

According to the gaming machine of (2) above, when the erasing process (for example, backup clearing process) is executed without being controlled by the setting change state, it is notified using both the display means and the audio output means. Therefore, it becomes possible to clearly understand that the erasing process has been executed. On the other hand, when the erasing process is executed as a result of being controlled to a setting change state, only the audio output means of the display means and audio output means is used for notification, which obstructs the visibility of the information screen. This makes it possible to understand the execution of the erasing process while preventing the user from performing the erasing process, thereby making it possible to prevent the erasing process from being executed by, for example, a third party who does not have the authority, while increasing convenience.

According to each of the gaming machines of appendices 7-1 to 7-12 having the above configuration, it is possible to provide a highly convenient gaming machine that can deal with problems related to setting values.

[11-8. Gaming machines in Appendix 8]
Conventionally, gaming machines have been known that perform a lottery when a predetermined condition is met, and display symbols variably based on the results of the lottery. Then, when a specific display result indicating that the lottery result is a specific result is displayed, the gaming state is controlled to be advantageous to the player.

In this type of gaming machine, any one of a plurality of setting values indicating the probability related to the advantage or disadvantage of the player in the game, such as the probability that the result of the lottery will be a specific result, is set, and from then on, A gaming machine in which the progress of a game is controlled based on set values is known (see, for example, paragraph [0063] of Japanese Patent Laid-Open No. 2011-206588). The above setting values can be set by an authorized person, such as a gaming machine manager of a hall, for example.

(Eighth issue)
However, in gaming machines where the progress of the game is controlled based on the set values, for example, the set values may be changed or checked illegally by an unauthorized person, or the set values may be changed due to noise etc. There are concerns that various problems may occur, such as the control board being changed or the control board being illegally replaced.

Furthermore, the above set values are important elements for both the hall and the players, and therefore should be strictly managed by a person with authority.

The present invention has been made in view of such points, and its purpose is to provide a gaming machine that can deal with problems related to setting values.

In order to solve the above-mentioned eighth problem, a gaming machine according to appendix 8 having the following configuration is provided.

(1) The gaming machine set forth in Appendix 8 is:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
Equipped with
The first control means includes:
When at least the setting operation means is operated, the setting state control means (for example, the main CPU 101 capable of executing the process of step S24 or step S26 )and,
a storage means (for example, main RAM 103) capable of storing setting value information regarding at least the one setting value;
Transmitting means capable of transmitting various information to the second control means, and capable of transmitting setting value information regarding at least the one setting value (for example, the command output port 106 and the main CPU 101 capable of executing the process of step S55) and,
The second control means
receiving means (for example, relay board 2010) capable of receiving the setting value information transmitted from the transmitting means;
Based on the reception of the setting value information by the receiving means, determining the suitability of the one setting value using the received setting value information and the setting value information received prior to the setting value information. a setting determination means (for example, a host control circuit 2100 that determines whether or not the previous setting value and the current setting value match);
an abnormality processing execution means (for example, a host control circuit 2100 that executes a setting value abnormality processing) that executes an abnormality processing when the one setting value is determined to be inappropriate by the setting determination means; It is characterized by

According to the gaming machine of (1) above, the second control means determines the suitability of the one setting value using the setting value information about the one setting value transmitted multiple times from the first control means. becomes possible. That is, even if it is possible to determine the suitability of one set value in the first control means, if the first control means is illegally replaced, for example, one set value may be normal. Regardless of whether the first set value is abnormal or not, the first control means determines that the first set value is normal. Therefore, by making it possible for the second control means to determine the suitability of one set value, even if the first control means is illegally replaced, This makes it possible to immediately discover suitability.

(2) In the gaming machine described in (1) above,
The transmitting means includes:
It is also possible to send setting operation information (for example, a setting operation command) indicating that the first setting value has been changed or confirmed,
The second control means
When the setting operation information is received by the receiving means, a storage separate from the storage means capable of storing at least the setting operation information received by the receiving means and time information related to the setting operation information as history information. means (for example, sub-work RAM 2100a);
and display control means (e.g., display control circuit 2300) capable of displaying an information screen (e.g., setting change/confirmation history screen) on which the history information is shown on a predetermined display means based on a predetermined operation. It is characterized by

According to the gaming machine of (2) above, by performing a predetermined operation, it is possible to view the information screen in which setting operation information and time information related to the setting operation information are shown as history information. It becomes possible to deal with various problems related to values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved.

In addition, when transmitting both setting operation information and setting value information, the transmitting means capable of transmitting various information to the second control means may transmit these information together or separately. Setting operation information is setting value change information that indicates that the setting value has been changed when the setting value has been changed, and setting value change information that indicates that the setting value has been confirmed when the setting value has been confirmed. This is setting value confirmation information indicating that the Further, when the setting operation information is setting value change information, the setting value information is setting value information regarding one setting value after the change. When the setting operation information is setting value confirmation information, setting value information regarding the first setting value that has been set may be sent to the second control means, but the first setting value has not been changed. Therefore, it is not essential to transmit the setting value information to the second control means.

Further, "time information related to the setting operation information" may be time information when the setting operation information was transmitted from the first control means to the second control means, or time information when the setting operation information was received by the second control means. It may be time.

According to the gaming machine of appendix 8 having the above configuration, it is possible to provide a gaming machine that can deal with problems related to setting values.

[11-9. Gaming machines in Appendix 9]
Conventionally, gaming machines have been known in which a lottery is drawn based on the establishment of predetermined conditions, and a game advantageous to the player is executed based on the result of the lottery.

As this type of gaming machine, a gaming machine that has multiple functions in one device has been proposed. For example, Japanese Patent Laid-Open No. 2012-170505 discloses that when pressed by a player, the device jumps out to a position that greatly protrudes from the main body of the gaming machine, regardless of the player's operation, in order to give an impact to the player. A push button is disclosed.

(9th issue)

By the way, when checking the operation of accessories, various sensors, etc., the maintainability of devices that have multiple functions in one device, such as the push button described in Japanese Patent Application Laid-open No. 2012-170505, decreases. There are concerns that this may occur.

The present invention has been made in view of such points, and its purpose is to provide a gaming machine that can improve the maintainability of a device that has multiple functions in one device. be.

In order to solve the above-mentioned ninth problem, a gaming machine according to appendix 9 is provided having the following configuration.

(1) The gaming machine set forth in Appendix 9 is:
A gaming machine that can perform a lottery (for example, a special lottery) based on the establishment of predetermined conditions and execute a game advantageous to the player based on the result of the lottery,
An accessory that can be operated based on the result of the lottery (for example, accessory group 1000);
A composite means having multiple functions (for example, a production button 62);
Various sensors used for the progress of the game (for example, first starting port switch 421, etc.),
Predetermined display means (for example, display device 16),
At least maintenance item determining means (for example, the process of step S3084 executable host control circuit 2100);
In determining the maintenance items, a selection screen (for example, the selection screen shown in FIG. maintenance screen display control means (for example, a host control circuit 2100 capable of executing the process of step S3083);
Equipped with
The maintenance item determining means includes:
a maintenance item selected on the selection screen displayed by the maintenance screen display control means;
The maintenance screen display control means includes:
The composite means, which is one but has multiple functions, is configured so that it can be displayed on the selection screen so that items can be selected for each function (for example, the item "Production Button 1" in FIG. 132 and Displayed so that you can select one of the items in "Production Button 2")
It is characterized by

According to the gaming machine described in (1) above, for complex means that have one but multiple functions, items can be selected for each function on the selection screen where one of multiple maintenance items can be selected. Since the information is displayed, it is possible to improve maintainability.

(2) In the gaming machine described in (1) above,
The composite means is
It has at least an operation function and a performance function that can be executed based on the result of the lottery,
The maintenance item determining means includes:
On the selection screen, when the operation function item (for example, production button 1) is selected, it is determined as a maintenance item related to the operation function, and when the production function item (for example, production button 2) is selected. The present invention is characterized in that it is configured to be able to determine maintenance items related to the performance function.

According to the gaming machine of (2) above, when an operation function item is selected, the maintenance item related to the operation function is determined, and when the production function item is selected, the maintenance item related to the production function is determined. Since it is configured to be determinable, it is possible to appropriately maintain both the operation function and the presentation function.

According to the gaming machine of appendix 9 having the above-described configuration, it is possible to provide a gaming machine that can improve the maintainability of a single device having multiple functions.

[11-10. Gaming machines in Appendix 10]
Conventionally, in gaming machines that execute games advantageous to players based on the results of a lottery conducted based on the establishment of predetermined conditions, gaming machines equipped with movable accessories that operate based on the results of the lottery have been known. There is.

As a gaming machine of this type, a gaming machine is disclosed that includes a first movable accessory and a second movable accessory each having a different driving source as a movable accessory that operates based on the result of a lottery (for example, (Refer to Publication No. 2018-15273).

(Tenth issue)
By the way, in the game machine described in, for example, Japanese Patent Laid-Open No. 2018-15273, which includes a plurality of movable accessories with different drive sources, maintenance work may be complicated and troublesome. This is particularly noticeable when there is a possibility that a plurality of movable accessories having different driving sources may interfere with each other.

The present invention has been made in view of such points, and its purpose is to reduce the troublesomeness of maintenance work even when a plurality of movable accessories with different drive sources are provided. Our goal is to provide gaming machines.

In order to solve the above-mentioned tenth problem, a gaming machine according to supplementary note 10 having the following configuration is provided.

(1) The gaming machine set forth in Appendix 10 is:
A gaming machine that can perform a lottery (for example, a special lottery) based on the establishment of predetermined conditions and execute a game advantageous to the player based on the result of the lottery,
A first accessory and a second accessory that can be operated based on the result of the lottery and have different driving sources,
Various sensors used for the progress of the game (for example, first starting port switch 421, etc.),
Predetermined display means (for example, display device 16),
Maintenance item determining means (for example, step a host control circuit 2100) capable of executing the process of S3084;
In determining the maintenance items, a selection screen (for example, , a maintenance screen display control means (for example, a host control circuit 2100 capable of executing the process of step S3083) that displays at least the maintenance screen shown in FIG. 132;
Equipped with
The maintenance item determining means includes:
a maintenance item selected on the selection screen displayed by the maintenance screen display control means;
The maintenance screen display control means includes:
Not only can you check the operation of the first accessory and the second accessory, but also check the operation when both the first accessory and the second accessory are operated by selecting on the selection screen. (For example, items such as "performance accessories 1+2" in FIG. 132 are displayed)
It is characterized by

According to the gaming machine of (1) above, not only can the first accessory object and the second accessory object be checked individually, but also the operation can be checked when both the first accessory object and the second accessory object are operated. can also be selected on the selection screen, making it possible to reduce the hassle of maintenance work.

(2) In the gaming machine described in (1) above,
The maintenance screen display control means includes:
The screen is configured such that an operation confirmation when the second accessory is operated after the first accessory is activated can be selected on the selection screen (for example, "performance accessory 1→2" in FIG. 132). items, etc. will be displayed)
It is characterized by

According to the gaming machine of (2) above, even if the start timing of the operation of the first accessory and the start timing of the operation of the second accessory may be different, the second accessory is activated after the first accessory is activated. Since it is possible to select on the selection screen whether to check the operation when the system is operated, it is possible to reduce the troublesomeness of maintenance work and further improve maintainability.

(3) In the gaming machine described in (1) or (2) above,
further comprising a third accessory that can be operated based on the result of the lottery and has a different driving source from both the first accessory and the second accessory,
The maintenance screen display control means includes:
If there is a possibility that the first accessory object and/or the second accessory object and the third accessory object may interfere with each other when both operate, the first accessory object and/or the second accessory object may interfere with each other. The selection screen is configured to be able to be displayed in such a manner that it is impossible to operate any of the items ``performance accessory 1+3'' in FIG. 132. )
It is characterized by

According to the gaming machine of (3) above, if there is a possibility that the first accessory and/or the second accessory and the third accessory may interfere with each other when they operate, the Since it is not possible to select the manner in which any of the first role object and/or the second role object and the third role object are operated, it is possible to improve maintainability.

According to the gaming machine of appendix 10 having the above configuration, it is possible to provide a gaming machine that can improve the maintainability of a single device having multiple functions.

[11-11. Gaming machines listed in Appendix 11-1 and Appendix 11-2]
Conventionally, gaming machines have been known that perform a lottery when a predetermined condition is met, and display symbols variably based on the results of the lottery. Then, when a specific display result indicating that the lottery result is a specific result is displayed, the gaming state is controlled to be advantageous to the player.

In this type of gaming machine, any one of a plurality of setting values indicating the probability related to the advantage or disadvantage of the player in the game, such as the probability that the result of the lottery will be a specific result, is set, and from then on, A gaming machine in which the progress of a game is controlled based on set values is known (see, for example, paragraph [0063] of Japanese Patent Laid-Open No. 2011-206588). The above setting values can be set by an authorized person, such as a gaming machine manager of a hall, for example.

(Eleventh issue)

By the way, in a gaming machine where the progress of the game is controlled based on the set value, the set value is an important element for both the hole and the players, since it is related to the ball output. However, there is a possibility that an abnormality may occur in the set value due to the occurrence of, for example, a power outage.

The present invention has been made in view of such points, and its purpose is to provide a gaming machine in which set values can be maintained appropriately.

In order to solve the above-mentioned eleventh problem, a gaming machine according to appendix 11-1 having the following configuration is provided.

(1) The gaming machines listed in Appendix 11-1 are:
A memory capable of executing control related to the progress of the game based on any one of a plurality of setting values, and capable of storing information related to the progress of the game including setting value information regarding the one setting value. A control means (e.g., main control circuit 100) having means (e.g., main RAM 103);
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a specific operation means (for example, backup clear switch 330) used to erase information stored in the storage means;
power supply means (for example, power supply circuit 338) capable of supplying power to the control means when the power is turned on;
Equipped with
The control means includes:
When the specific operation means is turned on and the power is turned on while the setting operation means is turned on, the state control means (for example, , has a main CPU 101) capable of executing the process of step S24,
The state control means includes:
When the power supply is stopped in the setting change state, even if the power is turned on without turning on the setting operation means and/or the specific operation means, the control remains in the setting change state. Possible or power can be restored in the setting change state when the power supply was stopped (for example, when the determination in step S21 is NO, the process in step S24 is executed)
It is characterized by

According to the gaming machine of (1) above, even if, for example, a power outage occurs while the gaming machine is being controlled to the settings changing state, when the power is turned on afterwards, the gaming machine will be controlled to the settings changing state or the power supply will be turned off. Since the power is restored in the changed setting state when the supply was stopped, the set value is always set and the set value is maintained appropriately. That is, for example, it is possible to prevent the occurrence of a situation in which a setting value is not set due to an unintended power outage or the like in a setting change state.

(2) In the gaming machine described in (1) above,
The control means includes:
When the setting operation means is turned off after the first setting value has been changed in the setting change state, setting value determining means (for example, , further includes a main CPU 101) that executes the process of step S2480,
The set value determining means includes:
When the setting operation means is controlled to the setting change state without being turned on, or when the power is restored in the setting change state when the power supply was stopped, the setting operation means is turned on. The device is characterized in that the first set value is fixed to the changed set value when the OFF operation is performed after the change.

According to the gaming machine of (2) above, if the setting operation means is controlled to the setting change state without being turned on, or if the power is restored in the setting change state when the power supply was stopped, the setting Although it is necessary to turn on the operating means once, it is possible to confirm one set value by performing the same operation as usual, such as turning off the setting operating means. As a result, even if the setting operation means is controlled to the setting change state without being turned on or the power is restored in the setting change state when the power supply was stopped, complicated operations can be performed. Therefore, it is possible to suitably prevent the occurrence of a situation where a set value is not set.

In order to solve the above-mentioned eleventh problem, a gaming machine according to appendix 11-2 having the following configuration is provided.

(1) The gaming machines listed in Appendix 11-2 are:
A memory capable of executing control related to the progress of the game based on any one of a plurality of setting values, and capable of storing information related to the progress of the game including setting value information regarding the one setting value. A control means (for example, main control circuit 100) having means,
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a specific operation means (for example, backup clear switch 330) used to erase information stored in the storage means;
power supply means (for example, power supply circuit 338) capable of supplying power to the control means when the power is turned on;
Equipped with
The control means includes:
A setting change state in which the first set value can be changed to a state after the power is turned on, and the first setting, depending on the operating state of the setting operating means and the operating state of the specific operating means. Equipped with a state control means (for example, a main CPU 101 capable of executing processes such as step S24, step S26, step S28, etc.) capable of controlling any one of a plurality of states including a setting confirmation state in which the value can be confirmed. death,
The state control means includes:
When the power supply is stopped in the setting confirmation state and then the power is turned on, control is performed to any one of the plurality of states depending on the operating state of the setting operating means and the operating state of the specific operating means. (for example, by executing the processes from step S22 to step S28),
When the power supply is stopped in the setting change state and then the power is turned on, control is possible or the power supply is stopped in the setting change state regardless of the operation state of the setting operation means and the specific operation means. Power can be restored in the current setting change state (for example, when the determination in step S21 is NO, the process in step S24 is executed)
It is characterized by

According to the gaming machine of (1) above, it is possible to prevent the occurrence of a situation where a set value is not set due to an occurrence of a power outage, etc., while ensuring operator convenience. In other words, the setting confirmation state is a state where you can only check the set value but cannot change the set value, so even if an unintended power outage occurs, the set value will not be changed. It is unlikely that this would affect the On the other hand, since the setting change state is a state in which one set value can be changed, for example, if an unintended power outage or the like occurs, there is a possibility that the one set value will be affected. Therefore, when the power supply is stopped in the setting confirmation state, when the power is turned on afterwards, it will be in one of multiple states depending on the operating state of the setting operating means and the operating state of the specific operating means. If the power supply is stopped in the setting change state, when the power is turned on afterwards, the control will be in the setting change state or in the setting change state when the power supply was stopped. By ensuring that the power is restored, the operator's convenience is ensured while preventing the occurrence of a situation in which a set value is not set due to an unintended power outage or the like.

(2) In the gaming machine described in (1) above,
The state control means includes:
When the specific operation means is turned on and the power is turned on while the setting operation means is turned on, the setting change state is controlled;
The control means includes:
further comprising set value determining means for determining the first set value to the changed set value when the setting operation means is turned off after the first set value is changed in the setting change state; have,
The set value determining means includes:
When the setting operation means is controlled to the setting change state without being turned on, or when the power is restored in the setting change state when the power supply was stopped, the setting operation means is turned on. The device is characterized in that the first set value is determined to be the changed set value when the OFF operation is performed after the first set value has been changed.

According to the gaming machine of (2) above, if the setting operation means is controlled to the setting change state without being turned on, or if the power is restored in the setting change state when the power supply was stopped, the setting Although it is necessary to turn on the operating means once, it is possible to confirm one set value by performing the same operation as usual, such as turning off the setting operating means. As a result, even if the setting operation means is controlled to the setting change state without being turned on or the power is restored in the setting change state when the power supply was stopped, complicated operations can be performed. Therefore, it is possible to suitably prevent the occurrence of a situation where a set value is not set.

According to each of the gaming machines of appendix 11-1 and appendix 11-2 having the above configuration, it is possible to provide a gaming machine in which the set value can be maintained appropriately.

[11-12. Gaming machines in Appendix 12]
Conventionally, gaming machines have been known that perform a lottery when a predetermined condition is met, and display symbols variably based on the results of the lottery. Then, when a specific display result indicating that the lottery result is a specific result is displayed, the gaming state is controlled to be advantageous to the player.

In this type of gaming machine, any one of a plurality of setting values indicating the probability related to the advantage or disadvantage of the player in the game, such as the probability that the result of the lottery will be a specific result, is set, and from then on, A gaming machine in which the progress of a game is controlled based on set values is known (see, for example, paragraph [0063] of Japanese Patent Laid-Open No. 2011-206588). The above setting values can be set by an authorized person, such as a gaming machine manager of a hall, for example.

(Twelfth issue)
By the way, in a gaming machine where the progress of the game is controlled based on the set value, the set value is an important element for both the hole and the players, since it is related to the ball output. However, there is a possibility that an abnormality may occur in the set value due to, for example, noise generation or fraudulent activity.

The present invention has been made in view of such points, and its purpose is to provide a gaming machine in which set values can be maintained appropriately.

In order to solve the above-mentioned twelfth problem, a gaming machine according to appendix 12 having the following configuration is provided.

(1) The gaming machine mentioned in Appendix 12 is:
A memory capable of executing control related to the progress of the game based on any one of a plurality of setting values, and capable of storing information related to the progress of the game including setting value information regarding the one setting value. A control means (e.g., main control circuit 100) having means (e.g., main RAM 103);
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a specific operation means (for example, backup clear switch 330) used to erase information stored in the storage means;
power supply means (for example, power supply circuit 338) capable of supplying power to the control means when the power is turned on;
Equipped with
The control means includes:
Setting change state control means for controlling to a setting change state in which the one setting value can be changed when the specific operation means is turned ON and the power is turned on while the setting operation means is turned ON; (For example, the main CPU 101 that can execute the process of step S24),
Appropriateness determining means (for example, main CPU 101 capable of executing the process of step S721) for determining whether the information stored in the storage means is appropriate or not;
If it is determined that the information stored in the storage means is inappropriate, an abnormality control means (processing from step S722 to step S727) that controls to an abnormal state (for example, a state in which the processing from step S722 to step S727 is executed) a main CPU 101) that executes
In the case where the power supply is stopped in the abnormal state, if the setting change state is not controlled after the power is turned on, the game is executed even if the operation to erase the information stored in the storage means is performed. On the other hand, control is performed so that the game cannot be played (for example, when the determination in step S1770 is NO, the process in step S1790 is not executed), and when the setting change state is controlled after the power is turned on, the game can be executed (for example, the process in step S1790 is not executed). The game execution means (for example, the main CPU 101 that executes the process of step S17) executes the process of step S1790 when the determination is YES in S1770 and YES in step S1780.

According to the gaming machine described in (1) above, if an abnormal state occurs due to the occurrence of noise or fraudulent activity, etc., and the power supply is stopped in such abnormal state, the machine will not be controlled to the setting change state after the power is turned on. In this case, even if an operation is performed to erase information stored in the storage means, the game cannot be played, and the game can be played only when the power is turned on and the settings are changed. . When an abnormal state occurs, there is a high possibility that the first set value information stored in the storage means is abnormal, so only when the first set value information is controlled to be changed so that the first set value is always changed. This allows games to be played and set values to be maintained appropriately.

According to the gaming machine of appendix 12 having the above configuration, it is possible to provide a gaming machine in which setting values can be maintained appropriately.

[11-13. Gaming machines in Appendix 13]
Conventionally, gaming machines have been known that perform a lottery when a predetermined condition is met, and display symbols variably based on the results of the lottery. Then, when a specific display result indicating that the lottery result is a specific result is displayed, the gaming state is controlled to be advantageous to the player.

In this type of gaming machine, any one of a plurality of setting values indicating the probability related to the advantage or disadvantage of the player in the game, such as the probability that the result of the lottery will be a specific result, is set, and from then on, A gaming machine in which the progress of a game is controlled based on set values is known (see, for example, paragraph [0063] of Japanese Patent Laid-Open No. 2011-206588). The above setting values can be set by an authorized person, such as a gaming machine manager of a hall, for example.

(Thirteenth issue)
However, in gaming machines where the progress of the game is controlled based on the set values, for example, the set values may be changed or checked illegally by an unauthorized person, or the set values may be changed due to noise etc. There are concerns that various problems may occur, such as changes in the

Furthermore, the above set values are important elements for both the hall and the players, and therefore should be strictly managed by a person with authority.

The present invention has been made in view of such points, and its purpose is to provide a gaming machine that can deal with problems related to setting values.

In order to solve the thirteenth problem described above, a gaming machine according to appendix 13 having the following configuration is provided.

(1) The gaming machine set forth in Appendix 13 is:
a first control means (for example, main control circuit 100) capable of executing control related to the progress of the game based on any one of the plurality of setting values;
Predetermined display means (for example, display device 16),
a second control means (for example, sub-control circuit 200) capable of at least controlling the display of images displayed on the display means;
a setting operation means (for example, setting key 328) used for operations related to the one setting value;
a power supply means (for example, a power supply circuit 338) capable of supplying power to the first control means and the second control means when the power is turned on;
Equipped with
The first control means includes:
When the power is turned on with at least the setting operation means being turned on (for example, the setting key is in the ON state), a state control means for controlling the setting state to a setting state in which the first setting value can be changed or confirmed. (For example, the main CPU 101 that can execute processes such as step S24, step S26, and step S28),
Although the game cannot be executed in the setting state, the game execution means is controllable so that the game can be executed when the setting state ends (for example, the game is executed in the setting process of step S20 when the game return process of step S30 has not been executed yet). A main CPU 101) that executes a power-on process that enables the game to be played by executing the game return process of step S30 when the setting process of step S20 is completed even though the setting process of step S20 is not possible;
A transmitting means (e.g., It has a command output port 106 and a main CPU 101 that can execute the process of step S55,
The second control means
receiving means (for example, relay board 2010) capable of receiving information transmitted from the transmitting means;
When the setting operation information is received by the receiving means, the setting operation effect execution means (for example, , a host control circuit 2100) that executes control to fully light up the LEDs 25 in red via the audio/LED control circuit 2200,
The setting operation performance execution means is
Even if the setting state ends and the game can be played, the game device is configured to be able to perform an effect indicating that the first setting value has been changed or confirmed until a predetermined period of time has elapsed. It is characterized by

According to the gaming machine of (1) above, when the receiving means receives the setting operation information, an effect indicating that one setting value is to be changed or confirmed is executed in a setting state in which a game cannot be executed. Furthermore, even if the setting state is completed and the game can be played, an effect indicating that one set value has been changed or confirmed is performed until a predetermined period of time has elapsed. Therefore, it is possible to easily discover fraud in cases where setting values are changed or checked in an unauthorized manner, and it is also possible to suppress the fraud itself.

(2) In the gaming machine described in (1) above,
The setting operation performance execution means is
After the setting state is completed and the game can be played, an effect indicating that the first set value has been changed or confirmed is displayed so that it can be visually understood that the game can be played. It is characterized by being configured to be executable.

According to the gaming machine described in (2) above, an effect indicating that the first set value has been changed or confirmed is executed in a manner that allows the user to visually understand that the game is ready for execution. It is possible to prevent the progress of the game from being hindered even though the effect indicating that the set value has been changed or confirmed is executed.

(3) In the gaming machine described in (1) or (2) above,
The state control means includes:
a setting change state control means (for example, a main CPU 101 capable of executing the process of step S24) that controls the setting change state in which the one setting value can be changed;
The second control means
When the setting operation information is received by the receiving means, at least the setting operation information received by the receiving means and time information related to the setting operation information (for example, time information when an initialization command or a power failure recovery command was received) and a storage means (for example, sub-work RAM 2100a) capable of storing the information as historical information;
An information screen in which the history information is shown in the setting state (for example, a setting change/confirmation history screen) can be displayed on the display means, and the information screen is arranged so that the information screen is not displayed when the setting state ends. further comprising display control means (for example, display control circuit 2300) capable of restricting display;
The display control means includes:
When the receiving means receives setting operation information indicating that the setting change state has ended, the display of the information screen is not restricted until a predetermined period of time has passed even if the setting change state has ended. It is characterized in that it is configured to be able to display an information screen (for example, to be able to execute the processes from step S312 to step S316).

According to the gaming machine (3) above, in the setting state, an information screen showing history information can be displayed on the display means, and when the setting state ends, the display of the information screen is restricted. Therefore, in the setting state, by viewing the information screen showing history information, it is possible to deal with various problems related to the setting values. In particular, if there is a possibility that setting values have been changed or confirmed for the purpose of fraud by an unauthorized third party, viewing the information screen will show whether or not the above fraud has occurred. This makes it possible to track the following. Furthermore, by viewing past history information, it can be used for hall sales, for example, and convenience can be improved. Furthermore, when the display of the information screen is restricted when the setting state ends, if setting operation information indicating that the setting change state has ended is received, even if the setting change state ends, the display of the information screen will be restricted. can display an information screen. Therefore, even if fraud is committed, it is possible to easily discover such fraud, and it is also possible to suppress the fraud itself.

According to the gaming machine of appendix 13 having the above configuration, it is possible to provide a gaming machine that can deal with problems related to setting values.

[11-14. Gaming machines in Appendix 14]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a game ball enters a starting slot, and if the result of the lottery is a jackpot, a jackpot game is played.

This type of gaming machine performs a long-press effect that changes the execution mode of a specific game effect on the condition that the player performs a predetermined long-press operation on the operating means. A gaming machine is known that makes it possible to execute a continuous hit effect on the condition that a continuous hit operation in which a push operation is performed multiple times is performed (for example, see Japanese Patent Laid-Open No. 2015-065977). In the gaming machine disclosed in JP-A-2015-065977, if a long press operation is performed within the long press operation acceptance valid period for determining whether a long press operation has been performed, a long press effect is executed.

(14th issue)
As in the game machine described in Japanese Patent Application Laid-open No. 2015-065977, if the control is controlled by determining whether a long press operation is performed on the operating means or a continuous hit effect is performed, the control load increases, which is not preferable. .

However, in recent years, there has been a demand for gaming machines that can increase interest by providing performances that can give an even greater visual impact.

In order to solve the fourteenth problem described above, a gaming machine according to supplementary note 14 having the following configuration is provided.

(1) The gaming machine mentioned in Appendix 14 is:
A gaming machine capable of executing main processing (e.g., main loop processing) in which various processing (e.g., various request control processing) is performed every predetermined time (e.g., 33.3 msec),
a predetermined operating means (for example, a main button);
Control capable of performing interrupt processing every time shorter than the predetermined time (for example, 1 msec) and generating input information in the main processing based on the input state of the operating means detected by the interrupt processing. means (e.g., host control circuit 2100);
Equipped with
The control means includes:
As the input information, after the input state of the operating means changes from an OFF state to an ON state,
As the input information, after the input state of the operating means changes from the OFF state to the ON state, it is determined that the ON state has continued for a certain period of time (for example, 10 frames), and then the input state of the operating means changes from the OFF state to the ON state. Input information that generates information (for example, ON edge information with a repeat function) that allows it to be determined that an ON state has occurred periodically as long as the ON state continues for a period shorter than a certain period of time (for example, 4 frames) a generating means (for example, the host control circuit 2100 that executes the process of step S1309);
and device control means (e.g., host control circuit 2100) capable of controlling a predetermined device based on the information generated by the input information generation means (e.g., the ON edge information with repeat function). Features.

According to the gaming machine of (1) above, after the input state of the operating means changes from the OFF state to the ON state based on the input state of the operating means (for example, input information of a sub-device), the ON state remains constant. As long as the input state of the operating means continues to be ON for a period shorter than a certain time after it is determined that the ON state has continued for a certain period of time, information that can be periodically determined to be generated is generated. It becomes possible to easily control the sub-device's repeated hit effects, long-press effect, and the like.

Further, according to the gaming machine of appendix 14, it is possible to execute control according to the mode of the operating means while reducing the control load.

[11-15. Each gaming machine in Appendix 15-2]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, when a game ball enters a starting slot, a lottery is held, and based on the result of the lottery, an effect image is displayed on, for example, a liquid crystal display.

As this type of gaming machine, a gaming machine including a display device that emits light by a backlight has been disclosed (for example, see Japanese Patent Application Laid-Open No. 2016-159026).

(15th issue)
However, if the luminance of the light emitting means of the backlight is unstable, for example, the display of the effect image on the display device may become unstable, which is not preferable.

In order to solve the fifteenth problem described above, we provide the gaming machine of appendix 15-1 and the gaming machine of appendix 15-2 having the following configurations.

(1) The gaming machine specified in Supplementary Note 15-1 is
A light emitting means (for example, a backlight) capable of emitting light in a predetermined manner;
data storage means (for example, a FIFO data area) for storing drive data (for example, luminance data) corresponding to a light emission mode emitted by the light emission means in a predetermined area;
a light emitting drive means (for example, an LSI) that outputs a control signal based on the drive data stored in the data storage means to the light emitting means;
data setting means (for example, host control circuit 2100 that executes the process of step S1346) for setting the drive data in a predetermined area of the data storage means;
Equipped with
The data setting means includes:
The drive data set in the predetermined area of the data storage means is configured to set new drive data when the number of drive data that can be set in the predetermined area reaches a reference number of data. shall be.

According to the gaming machine described in Appendix 15-1 of (1) above, when the number of drive data set in a predetermined data area that can be stored in the predetermined area reaches the reference data number, new drive data is is set, it is possible to output a control signal output by the light emitting drive means (for example, a signal equivalent to PWM that is continuously output from the SPI serial data output terminal), and the light emitting means can be controlled via the driver. This makes it possible to emit light stably without any problems.

Note that the above-mentioned "standard number of data" corresponds to 1 to 64 if the number of data that can be set in a predetermined area of the data storage means (for example, FIFO data area) is up to 64, but Considering that it is necessary to prevent the number of data set in a predetermined area of the storage means from becoming zero, it is preferable that the number is two or more. Further, the number of luminance data that can be set in the FIFO data area is not limited to 64, but it is sufficient that at least two or more luminance data can be set. In this way, when the number of brightness data that can be set in the FIFO data area is, for example, two or more, if the brightness data set in the FIFO data area is less than the first number (for example, two), the second number (For example, one piece of brightness data) may be supplemented.

(1) The gaming machines listed in Appendix 15-2 are:
A light emitting means (for example, a backlight) capable of emitting light in a predetermined manner;
data storage means (e.g., FIFO data area) for storing drive data (e.g., brightness data) corresponding to the light emission mode emitted by the light emitting means in a predetermined area (e.g., FIFO data area);
a light emitting drive means (for example, an LSI) that outputs a control signal based on the drive data stored in a predetermined area of the data storage means to the light emitting means;
data setting means (for example, host control circuit 2100 that executes the process of step S1346) for setting the drive data in a predetermined area of the data storage means;
a timer (e.g., host control circuit 2100 that executes the process of step S1356) capable of measuring the elapsed time since the drive data was set in a predetermined area of the data storage means;
Equipped with
The data setting means includes:
The drive data can be set in a predetermined area of the data storage means (the process of step S1354 can be executed) based on the elapse of a predetermined time or more as measured by the timer. shall be.

According to the gaming machine set forth in Supplementary note 15-2 of (1) above, the drive data is changed to It is set in a predetermined area of the storage means. For example, if some processing takes time, the drive data set in the predetermined area of the data storage means will run out by the time the drive data is set in the predetermined area of the data storage means. There is a risk that this may occur. In this respect, according to this gaming machine, even if it is not the timing to set the drive data in the predetermined area of the data storage means, the drive data is set in the predetermined area of the data storage means based on the elapse of the above-mentioned time period or more. Therefore, it is possible to prevent the drive data set in the predetermined data area from becoming empty. Therefore, it is possible to output the control signal outputted by the light emitting drive means (for example, a signal equivalent to PWM that is continuously outputted from the SPI serial data output terminal), and the light emitting means can be stably output without using a driver. It becomes possible to emit light.

Further, according to the gaming machine of appendix 15-1 and the gaming machine of appendix 15-2, it is possible to suppress the light emission of the light emitting means from becoming unstable.

[11-16. Each gaming machine in Appendix 16-2]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a game ball enters a starting slot, and an effect image is displayed on a liquid crystal display or the like based on the result of the lottery.

As a gaming machine of this type, a gaming machine is known that is used for performances and decorations by emitting light in a predetermined manner from a light-emitting device consisting of a plurality of light-emitting bodies such as LEDs provided on the front side. . Further, a game machine has been disclosed in which a player or the like can adjust the brightness of these light emitting devices within a preset range (see, for example, Japanese Patent Laid-Open No. 2008-295551).

(16th issue)
Incidentally, in recent years, displays have become more flashy, including light-emitting devices made up of light-emitting bodies such as a plurality of LEDs provided on the front side. Therefore, if the brightness of the light emitting device is high, some players may find it stressful. If a player or the like can operate the brightness of the light emitting device, the player can adjust the brightness to a desired level, but this alone may not be sufficient.

In order to solve the above-mentioned 16th problem, we provide a gaming machine according to appendix 16-1 and a gaming machine according to blowing 16-2 having the following configurations.

(1) The gaming machine described in Supplementary Note 16-1 is
a first light emitting means (for example, a backlight) capable of emitting light in a predetermined manner;
an operation means (for example, a brightness setting screen displayed on a liquid crystal display device used as the display device 16) that can change the brightness of the first light emitting means to one of a plurality of levels;
A first light emission control means that can change the brightness of the first light emission means to one of a plurality of levels based on the operation of the operation means (for example, a host control circuit that executes the process of step S1384) 2100) and
a second light emitting means provided separately from the first light emitting means (for example, a panel side LED or a frame side LED);
a second light emission control means (for example, a host control circuit 2100 that executes the process of step S1385) capable of changing the brightness of the second light emission means;
Equipped with
The second light emission control means
Based on the operation of the operating means, the brightness of the second light emitting means is changed to one of the plurality of levels at a timing different from the timing at which the brightness of the first light emitting means is changed. It is characterized by being configured to allow

According to the game machine of (1) above, when the operating means capable of changing the brightness of the first light emitting means is operated, the second light emitting means is changed at a timing different from the timing at which the brightness of the first light emitting means is changed. While the brightness of the light emitting means is also changed, the brightness of the second light emitting means is also changed to one of a plurality of levels, making it possible to further increase the degree of freedom in changing the brightness by the player. .

(2) In the gaming machine described in (1) above,
data storage means (for example, a FIFO data area) for storing drive data corresponding to a light emission mode emitted by the first light emitting means in a predetermined area;
a light emitting drive means (for example, an LSI) that outputs a control signal based on the drive data stored in the data storage means to the first light emitting means;
data setting means (for example, host control circuit 2100 that executes the process of step S1346) for setting the drive data in a predetermined area of the data storage means;
Equipped with
The data setting means includes:
When the number of drive data set in the predetermined area of the data storage means that can be stored in the predetermined area reaches a reference number of data, new drive data is set;
It is characterized in that, when the operating means is operated, drive data whose brightness has been changed is set as the new drive data.

According to the gaming machine of (2) above, when the number of drive data set in a predetermined data area that can be stored in the predetermined area reaches the reference data number, new drive data is set. , it is possible to output a control signal output by the light emitting drive means (for example, a signal equivalent to PWM that is continuously output from the SPI serial data output terminal), and the light emitting means can stably emit light without using a driver. It becomes possible to do so. Moreover, when the brightness is changed, the changed drive data is set as new drive data, so it is possible to stably cause the first light emitting means to emit light according to the set brightness.

Note that the above-mentioned "standard number of data" corresponds to 1 to 64 if the number of data that can be set in a predetermined area of the data storage means (for example, FIFO data area) is up to 64, but Considering that it is necessary to prevent the number of data set in a predetermined area of the storage means from becoming zero, it is preferable that the number is two or more. Further, the number of luminance data that can be set in the FIFO data area is not limited to 64, but it is sufficient that at least two or more luminance data can be set. In this way, when the number of brightness data that can be set in the FIFO data area is, for example, two or more, if the brightness data set in the FIFO data area is less than the first number (for example, two), the second number (For example, one piece of brightness data) may be supplemented.

(1) The gaming machines listed in Appendix 16-2 are:
A lottery means (for example, the main CPU 101 that executes the process of step S45) that performs a lottery based on the establishment of predetermined conditions;
A display means (for example, a liquid crystal display device used as the display device 16) on which a predetermined effect image is displayed;
a variable display control means (e.g., display control circuit 2300) that performs a variable display of symbols (e.g., performance identification symbols) on the display means based on the result of the lottery;
a first light emitting means (for example, a backlight) capable of emitting light in a predetermined manner;
an operation means (for example, a brightness setting screen displayed on a liquid crystal display device used as the display device 16) that can change the brightness of the first light emitting means to one of a plurality of levels;
A first light emission control means that can change the brightness of the first light emission means to one of a plurality of levels based on the operation of the operation means (for example, a host control unit that executes the process of step S1394) circuit 2100);
a second light emitting means provided separately from the first light emitting means (for example, a panel side LED or a frame side LED);
a second light emission control means (host control circuit 2100 that executes the process of step S1392) that controls the light emission mode of the second light emission means based on a predetermined request;
Equipped with
The second light emission control means
Based on the operation of the operating means, the brightness of the second light emitting means is changed after the brightness of the first light emitting means is changed and after the variable display of the symbol is finished. (for example, execute the process of step S1399).

According to the gaming machine of (1) above, when the operating means is operated, the brightness of the first light emitting means can be changed. Further, the brightness of the second light emitting means is changed after the brightness of the first light emitting means is changed and after the variable display of the symbol is finished. Here, since the light emitting mode of the second light emitting means is controlled based on a predetermined request, the control load can be minimized by changing the brightness of the second light emitting means after the fluctuating display of the symbol is finished. It becomes possible to change the brightness of the first light emitting means and the second light emitting means while keeping the brightness to a minimum.

(2) In the gaming machine described in (1) above,
data storage means (for example, a FIFO data area) for storing drive data corresponding to a light emission mode emitted by the first light emitting means in a predetermined area;
a light emitting drive means (for example, LSI) that outputs a control signal based on the drive data stored in the data storage means to the first light emitting means;
data setting means (for example, host control circuit 2100 that executes the process of step S1346) for setting the drive data in a predetermined area of the data storage means;
Equipped with
The data setting means includes:
When the number of drive data set in the predetermined area of the data storage means that can be stored in the predetermined area reaches a reference number of data, new drive data is set;
It is characterized in that, when the operating means is operated, drive data whose brightness has been changed is set as the new drive data.

According to the gaming machine of (2) above, when the number of drive data set in a predetermined data area that can be stored in the predetermined area reaches the reference data number, new drive data is set. , it is possible to output a control signal output by the light emitting drive means (for example, a signal equivalent to PWM that is continuously output from the SPI serial data output terminal), and the light emitting means can stably emit light without using a driver. It becomes possible to do so. Moreover, when the brightness is changed, the changed drive data is set as new drive data, so it is possible to stably cause the first light emitting means to emit light according to the set brightness.

Note that the above-mentioned "standard number of data" corresponds to 1 to 64 if the number of data that can be set in a predetermined area of the data storage means (for example, FIFO data area) is up to 64, but Considering that it is necessary to prevent the number of data set in a predetermined area of the storage means from becoming zero, it is preferable that the number is two or more. Further, the number of luminance data that can be set in the FIFO data area is not limited to 64, but it is sufficient that at least two or more luminance data can be set. In this way, when the number of brightness data that can be set in the FIFO data area is, for example, two or more, if the brightness data set in the FIFO data area is less than the first number (for example, two), the second number (For example, one piece of brightness data) may be supplemented.

Further, according to the gaming machine of appendix 16-1 and the gaming machine of appendix 16-2, it is possible to provide a gaming machine that allows a player or the like to more suitably adjust the brightness of the light emitting device.

[11-17. Gaming machines in Appendix 17]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a game ball enters a starting slot, and an effect image is displayed on a liquid crystal display or the like based on the result of the lottery.

As a gaming machine of this type, a gaming machine is known that is used for performances and decorations by emitting light in a predetermined manner from a light-emitting device consisting of a plurality of light-emitting bodies such as LEDs provided on the front side. . Further, a game machine has been disclosed in which a player or the like can adjust the brightness of these light emitting devices within a preset range (see, for example, Japanese Patent Laid-Open No. 2008-295551).

(17th issue)
Incidentally, in recent years, displays have become more flashy, including light-emitting devices made up of light-emitting bodies such as a plurality of LEDs provided on the front side. Therefore, if the intensity of light received from the light emitting device is high, some players may find it stressful.

In order to solve the seventeenth problem described above, a gaming machine according to appendix 17 having the following configuration is provided.

(1) The gaming machine set forth in Appendix 17 is:
The gaming machine according to the present invention includes:
a first light emitting means (for example, a backlight) capable of emitting light in a predetermined manner;
an operation means (for example, a brightness setting screen displayed on a liquid crystal display device used as the display device 16) that can change the brightness of the first light emitting means to one of a plurality of levels;
A first light emission control means that can change the brightness of the first light emission means to one of a plurality of levels based on the operation of the operation means (for example, a host control circuit that executes the process of step S1394) 2100) and
a second light emitting means (for example, a panel side LED or a frame side LED) provided separately from the first light emitting means;
a second light emission control means (for example, a host control circuit 2100 that executes the process of step S1406) capable of changing the light emission mode of the second light emission means;
Equipped with
The second light emission control means
Based on the operation of the operating means, the mode of the light emitting effect executed by the second light emitting means is limited and executed at a timing different from the timing at which the brightness of the first light emitting means is changed. It is characterized by being configured to allow

According to the game machine of (1) above, when the operating means capable of changing the brightness of the first light emitting means is operated, the mode of the light emitting effect executed by the second light emitting means is limited. Therefore, with simple processing, it is possible to suppress the intensity of light received from the second light emitting means.

(2) In the gaming machine described in (1) above,
data storage means (for example, a FIFO data area) for storing drive data corresponding to a light emission mode emitted by the first light emitting means in a predetermined area;
a light emitting drive means (for example, an LSI) that outputs a control signal based on the drive data stored in the data storage means to the first light emitting means;
data setting means (for example, host control circuit 2100 that executes the process of step S1346) for setting the drive data in a predetermined area of the data storage means;
Equipped with
The data setting means includes:
When the number of drive data set in the predetermined area of the data storage means that can be stored in the predetermined area reaches a reference number of data, new drive data is set;
It is characterized in that, when the operating means is operated, drive data whose brightness has been changed is set as the new drive data.

According to the gaming machine of (2) above, when the number of drive data set in a predetermined data area that can be stored in the predetermined area reaches the reference data number, new drive data is set. , it is possible to output a control signal output by the light emitting drive means (for example, a signal equivalent to PWM that is continuously output from the SPI serial data output terminal), and the light emitting means can stably emit light without using a driver. It becomes possible to do so. Moreover, when the brightness is changed, the changed drive data is set as new drive data, so it is possible to stably cause the first light emitting means to emit light according to the set brightness.

Note that the above-mentioned "standard number of data" corresponds to 1 to 64 if the number of data that can be set in a predetermined area of the data storage means (for example, FIFO data area) is up to 64, but Considering that it is necessary to prevent the number of data set in a predetermined area of the storage means from becoming zero, it is preferable that the number is two or more. Further, the number of luminance data that can be set in the FIFO data area is not limited to 64, but it is sufficient that at least two or more luminance data can be set. In this way, when the number of brightness data that can be set in the FIFO data area is, for example, two or more, if the brightness data set in the FIFO data area is less than the first number (for example, two), the second number (For example, one piece of brightness data) may be supplemented.

In this way, according to the gaming machine of appendix 17, it is possible to provide a gaming machine that allows a player or the like to suitably adjust the intensity of light received from the light emitting device.

[11-18. Gaming machines in Appendix 18]
2. Description of the Related Art Conventionally, among gaming machines such as pachinko machines, gaming machines are known in which, for example, effects are performed depending on an RTC (real-time clock).

In this type of gaming machine, an abnormality is determined in the RTC when the power is turned on, etc., and if an abnormality is detected, the date and time are notified, and if an abnormality in the RTC is recognized, it can be quickly dealt with. It is publicly known (for example, see Japanese Patent Application Publication No. 2017-51853 (for example, paragraph [0094])).

(18th issue)
According to the gaming machine described in Japanese Patent Application Laid-Open No. 2017-51853, if there is an abnormality in the RTC, the date and time will be notified, so there is a possibility that it can be dealt with quickly. There is a risk that it will not be possible to perform the desired performance.

In order to solve the above-mentioned 18th problem, a gaming machine according to appendix 18 having the following configuration is provided.

(1) The gaming machine set forth in Appendix 18 is:
A real-time clock (for example, RTC) that can output time information,
a time information management unit that can acquire time information from the real-time clock and update the acquired time to current time information (for example, a host control circuit 2100 that executes the process of step S1413);
Effect execution means (e.g., host control circuit 2100) capable of executing a specific effect (e.g., RTC effect) based on the current time information being specific time information (e.g., designated time);
an abnormality determining means (for example, the host control circuit 2100 that executes the process of step S1414) that determines whether the real-time clock is abnormal;
Equipped with
The time information management means includes:
When it is determined that the real-time clock is abnormal, the time information management means maintains the previous time information acquired last time as current time information (for example, step S1415), and when it is determined that the real-time clock is normal. Then, the previous time information can be updated to the current time information (for example, in the process of step S1416),
The performance execution means is
The specific effect is executed on condition that the current time information is the specific time information (YES in step S1417) and the previous time information and the current time information do not match (YES in step S1418). ) It is characterized by being configured as follows.

According to the gaming machine of (1) above, even if there is an RTC abnormality, it is possible to suitably perform effects that depend on the RTC.

[11-19. Gaming machines listed in Appendix 19-1 and Appendix 19-2]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a game ball enters a starting slot, and an effect image is displayed on a display device or the like based on the result of the lottery. If the result of the lottery is a jackpot, a jackpot game is started.

As this type of gaming machine, a gaming machine that decodes compressed image data, performs appropriate conversion processing on the decoded image data, stores it in a frame buffer, and outputs it to a display device is known. (For example, see JP-A-2014-87402 (for example, see paragraph [0100])).

(19th issue)
In recent years, the variety of effect images displayed on display devices has increased, and control over effect images has tended to become more complex. In such cases, it is desirable to efficiently control the effect images.

In order to solve the above nineteenth problem, we provide the gaming machine of appendix 19-1 and the gaming machine of appendix 19-2 having the following configurations.

(1) The gaming machine specified in Supplementary Note 19-1 is
A gaming machine capable of executing processing (for example, bank flip) for switching functions between a drawing output destination buffer having a drawing function and a frame buffer having a display function,
Registration means (for example, display control circuit 2300 capable of executing step S1449 and step S1458) capable of registering image information (for example, composition) related to the effect image displayed on a predetermined display means in the drawing output destination buffer; and,
After the drawing output destination buffer is switched to the frame buffer (for example, after the process of step S1446 is performed), an effect image is displayed on the predetermined display means based on the image information registered by the registration means. Effect image display control means (for example, display control circuit 2300) that controls the display;
Equipped with
The registration means is
When the image information registered in the frame buffer switched from the drawing output destination buffer includes image information that causes the image to be temporarily stopped (for example, when it is determined as YES in step S1447), the a first registration unit (for example, display control circuit 2300 that executes the process of step S1449) that registers image information in the drawing output destination buffer;
Even if there is no image information registered in the drawing output destination buffer (for example, even if the determination is NO in step S1444), the effect image displayed on the predetermined display means is registered in the frame buffer. a second registration unit (for example, capable of executing step S1458) that registers the image information in the drawing output destination buffer when the upper limit of the image information being displayed has been reached (for example, when it is determined as YES in step S1450); A display control circuit 2300).

According to the gaming machine of (1) above, the image information is registered on the condition that the image information is not registered, but even if the image information is registered, there is a specific Since the image information is registered when the image information is included, it becomes possible to efficiently control the effect images.

(1) The gaming machines listed in Appendix 19-2 are:
a plurality of display means (for example, displays) capable of reproducing predetermined performance images;
display control means (for example, display control circuit 2300) capable of controlling image information related to effect images reproduced on the plurality of display means;
Equipped with
The display control means includes:
layer number determining means (for example, display control circuit 2300 that executes the process of step S1441) that determines the appropriateness of the number of layers of image information that is simultaneously reproduced on the display means;
When the number of layers is appropriate (for example, when it is determined YES in step S1441), display means number determining means (for example, step a display control circuit 2300) that executes the process of S1442;
Existence of display means for determining the existence of display means to be registered with the image information when the number of display means used to reproduce the effect image is appropriate (for example, when it is determined as YES in step S1442). A determining means (for example, the display control circuit 2300 that executes the process of step S1443),
When there is a display means to which the image information is to be registered (for example, when the determination is YES in step S1443), an image information registration means (for example, step S1449) that registers the image information to be reproduced on the display means exists. and a display control circuit 2300) that executes the process of step S1458.
After the image information to be reproduced on one of the plurality of display means is registered by the image information registration means, the image information is registered on another display means different from the one display means. The present invention is characterized in that it is configured to perform the determination by the display means number determination means and the determination by the display means presence determination means (after executing the process of step S1459, the process returns to step S1442).

According to the gaming machine of (1) above, when there are multiple display means and the number of layers related to image information is appropriate, after the image information related to the effect image displayed on one display means is registered, Since the image information related to the effect image displayed on another display means different from the first display means is registered, it is possible to efficiently register the image information for which it is determined that the number of layers is appropriate. Become.

In this way, according to the gaming machine of appendix 19-1 and the gaming machine of appendix 19-2, it is possible to provide a gaming machine that can efficiently control performance images.

[11-20. Each gaming machine in Appendix 20-1 and Appendix 20-2]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, when a game ball enters a starting slot, a lottery is held, and based on the result of the lottery, an effect image is displayed on, for example, a liquid crystal display. In addition to such effect images, audio effects are also output.

As this type of gaming machine, it is determined whether or not the timing for determining an abnormality of the digital amplifier has been reached. A gaming machine is known that acquires an abnormality notification signal ERR and determines whether the digital amplifier is at an abnormal level (see JP-A-2016-209723 (for example, paragraphs [0178] and [0179])).

(Twentieth issue)
In recent years, the content of performances has become more sophisticated and the interest has been improved due to an increase in the variety of performance images displayed on liquid crystal displays and the like. However, as the content of the game becomes more sophisticated, the content of the game sound also tends to become more sophisticated, and in order to output normal game sounds, it is necessary for the amplification device that amplifies the game sound to perform appropriate determination processing. There is.

In order to solve the above-mentioned 20th problem, we provide the gaming machine of attachment 20-1 and the gaming machine of attachment 20-2 having the following configurations.

(1) The gaming machine specified in Appendix 20-1 is
A gaming machine capable of executing predetermined processing (for example, main processing, interrupt processing, etc.) every time a predetermined time elapses,
Output means (for example, speaker 24) capable of outputting game sounds;
amplification means (for example, digital audio power amplifier 2620) capable of amplifying the game sound output from the output means;
an abnormality determination means (for example, a host control circuit 2100 that executes processes such as step S1503, step S1511, and step S1515) that performs abnormality determination processing to determine whether the amplifying hand is normal;
Equipped with
The abnormality determination means includes:
The abnormality determination process can be divided into a plurality of abnormality determination processes (for example, steps S1503, S1511, S1515, etc.) and can be executed;
Executing a part of the abnormality determination processing divided into a plurality of times (for example, step S1503, step S1511, step S1515) in one predetermined process (for example, one frame) executed within the predetermined time, The present invention is characterized in that it is configured to be able to execute part or all of the remaining abnormality determination processing in the predetermined processing from next time onwards.

According to the gaming machine of (1) above, part of the abnormality determination process of the amplification means (for example, normal amplifier or heavy bass amplifier) is performed over multiple frames within a predetermined process (for example, one frame). , it becomes possible to execute all the abnormality determination processing of each amplifying means over a plurality of frames.

(2) Another example of the gaming machine mentioned in Appendix 20-1 is:
A gaming machine capable of executing predetermined processing (for example, main processing, interrupt processing, etc.) every time a predetermined time elapses,
Output means (for example, speaker 24) capable of outputting game sounds;
amplification means (for example, digital audio power amplifier 2620) capable of amplifying the game sound output from the output means;
a setting information confirmation unit (for example, a host control circuit 2100 that executes processes such as steps S1506 to S507 and steps S1522 to S523) that performs a process to confirm setting information regarding the amplification unit;
Equipped with
The setting information confirmation means includes:
The confirmation process can be executed by dividing it into multiple confirmation processes, and
A part of the confirmation process divided into a plurality of times (for example, the host control circuit 2100 that executes the processes of steps S1506 to S507, steps S1522 to S523, etc.) in one of the predetermined processes executed within the predetermined time. The present invention is characterized in that it is configured to be able to execute part or all of the remaining confirmation process in the predetermined process from the next time onwards.

According to the gaming machine described in (2) above, part of the process for checking the setting information of the amplification means (for example, a normal amplifier or a heavy bass amplifier) is performed over multiple frames within a predetermined process (for example, one frame). Therefore, it becomes possible to perform the entire process of checking the setting information of each amplifying means over a plurality of frames.

(1) The gaming machine described in Appendix 20-2 is
A gaming machine capable of executing predetermined processing (for example, main processing, interrupt processing, etc.) every time a predetermined time elapses,
Output means (for example, speaker 24) capable of outputting game sounds;
amplification means (for example, digital audio power amplifier 2620) capable of amplifying the game sound output from the output means;
The abnormality determination process for determining whether or not the amplification means is normal can be executed by dividing into multiple abnormality determination processes (for example, processing for check status = 0, 2, 3), and the multiple abnormality determination processes can be executed separately. an abnormality determination means (for example, a host control circuit 2100 that executes processes such as step S1503, step S1511, and step S1515) that performs the determination process over the predetermined process a plurality of times;
progress management means for managing the progress of the abnormality determination process (for example, a host control circuit 2100 for managing check status);
Equipped with
The progress management means includes:
It is possible to determine whether one determination process among the plurality of abnormality determination processes (for example, processes for check status = 0, 2, 3) has been completed in one predetermined process,
The abnormality determining means includes:
When the first abnormality determination process (for example, check status 0 process) is completed in the first predetermined process, another abnormality determination process different from the first abnormality determination process will be performed in the next and subsequent predetermined processes (for example, after the next frame). An abnormality determination process (for example, a process for check status 2) is executed, and if the first abnormality determination process (for example, a process for check status 0) is not completed in the first predetermined process, then in the next and subsequent predetermined processes. The present invention is characterized in that the first abnormality determination process (for example, the process for check status 0) can be executed again.

According to the gaming machine of (1) above, part of the abnormality determination process of the amplification means (for example, normal amplifier or heavy bass amplifier) is performed over multiple frames within a predetermined process (for example, one frame). , it becomes possible to execute all the abnormality determination processing of each amplifying means over a plurality of frames. Moreover, if one abnormality determination process is not completed in one predetermined process (for example, the main process or interrupt process for one frame), the abnormality determination process will be performed in the next and subsequent predetermined processes (for example, from the next frame onward). Since the process is executed again, all abnormality determination processes will be executed until completion.

(2) Another example of the gaming machine described in Appendix 20-2 is:
A gaming machine capable of executing predetermined processing (for example, main processing, interrupt processing, etc.) every time a predetermined time elapses,
Output means (for example, speaker 24) capable of outputting game sounds;
amplification means (for example, digital audio power amplifier 2620) capable of amplifying the game sound output from the output means;
The confirmation process of the setting information regarding the amplification means can be executed by dividing into a plurality of confirmation processes (for example, the process of check status = 1, 5), and the plurality of confirmation processes are executed as a plurality of the predetermined processes. Setting information confirmation means (for example, the host control circuit 2100 that executes the processes of steps S1506 to S507, steps S1522 to S523, etc.);
a progress management unit (for example, a host control circuit 2100 that manages check status) that manages the progress of the setting information confirmation process;
Equipped with
The progress management means includes:
It is possible to determine whether one confirmation process among the plurality of confirmation processes (for example, processes with check status = 1, 5) has been completed in one predetermined process,
The setting information confirmation means includes:
When the one confirmation process (for example, the process with check status = 1) is completed in the one predetermined process, another confirmation process different from the one confirmation process (for example, check status = 1) is completed in the next and subsequent predetermined processes. 5), and if the first confirmation process is not completed in the first predetermined process, the first confirmation process can be executed again in the next and subsequent predetermined processes. .

According to the gaming machine described in (2) above, part of the process for checking the setting information of the amplification means (for example, a normal amplifier or a heavy bass amplifier) is performed over multiple frames within a predetermined process (for example, one frame). Therefore, it becomes possible to perform the entire process of checking the setting information of each amplifying means over a plurality of frames. Moreover, if one confirmation process is not completed in one predetermined process (for example, one frame's main process or interrupt process), that one confirmation process will be performed in the next and subsequent predetermined processes (for example, from the next frame onwards). Since it will be executed again, all confirmation processes will be executed until they are completed.

In this way, according to the gaming machine of attachment 20-1 and the gaming machine of attachment 20-2, it is possible to provide a gaming machine that can appropriately perform the determination process of the amplification device.

[11-21. Gaming machines listed in Appendix 21-1 and Appendix 21-2]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, when a game ball enters a starting slot, a lottery is held, and based on the result of the lottery, an effect image is displayed on, for example, a liquid crystal display. In addition to such effect images, game sounds are also output from the speaker.

As a game machine of this type, a game machine that operates a simple access controller by writing an SAC number into a voice control register and outputs voice data such as game sounds from a voice memory has been disclosed (for example, Japanese Patent Laid-Open No. (Refer to Publication No. 2017-79971).

(21st issue)
In recent years, variations in game sounds have increased as variations in production images have increased, but if, for example, multiple game sounds overlap, there is a risk that the effect of the game sounds will be halved.

In order to solve the above-mentioned twenty-first problem, we provide the gaming machine of attachment 21-1 and the gaming machine of attachment 21-2 having the following configurations.

(1) The gaming machine described in Appendix 21-1 is
Setting means (for example, host control circuit 2100) that can allocate and set sound information (for example, SAC number) related to game sound data to channels;
a sound output means (for example, a sound/LED control circuit) capable of outputting game sound based on the sound information assigned to the channel;
Equipped with
The setting means is
When assigning sound information to one channel, when a plurality of sound information is set to the one channel (for example, when it is determined as YES in the process of step S1542),
When the plurality of sound information is specific sound information (for example, chain playback of SHOT playback and LOOP playback), one of the plurality of sound information (for example, loop playback) is played for at least a predetermined period of time. a first setting unit (for example, the host control circuit 2100 that executes the process of step S1544) that sets with a delay of at least one frame (for example, one frame);
on the condition that the plurality of sound information is non-specific sound information different from the specific sound information (for example, NO is determined in the process of step S1543), without delaying for more than the predetermined time ( For example, the second setting means (for example, the host control circuit 2100 that executes the processing of step S1546 and step S1547) sets the plurality of sound information (for example, in the frame).

According to the gaming machine of (1) above, when a plurality of sound information is set in one channel and the plurality of sound information is specific sound information, one of the sound information is delayed. Since this is set, it is possible to enjoy the sound effects caused by delaying the sound (for example, the sound effects caused by muting). On the other hand, if the plurality of sound information is non-specific sound information, the plurality of sound information is set without delay, so that processing can be performed quickly. In other words, by delaying or not delaying depending on the situation, it is possible to ensure the speed of processing while making the most of the game sound effect caused by the delay.

(2) In the gaming machine described in (1) above,
The specific sound information is
It includes at least first sound information that is played only once (for example, SHOT playback) and second sound information that is played multiple times (LOOP playback),
The first setting means includes:
The apparatus is characterized in that the second sound information can be set after a predetermined time delay or more after the first sound information is set.

According to the gaming machine of (2) above, after the first sound information that is played only once is set, the second sound information that is played multiple times is set with a delay of more than a predetermined time. It is possible to prevent the first sound information that is reproduced only once from becoming difficult to hear.

(1) The gaming machine specified in Appendix 21-2 is
Setting means (e.g., audio/LED control circuit) that can assign and set sound information (e.g., SAC number) related to game sound data to channels;
a sound output means capable of outputting game sound based on the sound information assigned to the channel;
Equipped with
The setting means is
When assigning sound information to one channel, when a plurality of sound information is set to the one channel (for example, when it is determined as YES in the process of step S1542),
When the plurality of sound information is specific sound information (for example, chain playback of SHOT + loop), one of the sound information (for example, loop playback) among the plurality of sound information is played for at least a predetermined period of time (for example, a first setting unit (e.g., host control circuit 2100 that executes the process of step S1544) that sets with a delay of at least one frame);
on the condition that the plurality of sound information is non-specific sound information different from the specific sound information (for example, NO is determined in the process of step S1543), without delaying for more than the predetermined time ( a second setting unit (for example, the host control circuit 2100 that executes the processing of step S1546 and step S1547) that sets the plurality of sound information (for example, in the frame);
has
The second setting means includes:
When all channels are set to mute (for example, when the determination is YES in the process of step S1545), the sound information is set without overwriting the mute setting (for example, the process of step S1546 is performed). ) On the other hand, when the mute setting is not for all channels but for one channel (for example, when the determination is NO in step S1545), the mute setting is overwritten and sound information is set (for example, in step S1547 It is characterized by being configured so that it can perform the following processing.

(1) According to the game machine of 1 above, when multiple pieces of sound information are set in one channel, if the plurality of pieces of sound information are specific pieces of sound information, one of the pieces of sound information is delayed. Therefore, it is possible to enjoy sound effects caused by delaying the sound (for example, sound effects caused by muting). On the other hand, if the plurality of sound information is non-specific sound information, the plurality of sound information is set without delay, so that processing can be performed quickly. In other words, by delaying or not delaying depending on the situation, it is possible to ensure the speed of processing while making the most of the game sound effect caused by the delay. Furthermore, when multiple pieces of sound information are non-specific sound information, if the mute setting is set for all channels, the sound information is set without overwriting the mute setting, and instead of the mute setting for all channels, the sound information is set. When the mute setting is for a channel, the mute setting is overwritten and sound information is set, so it can be used for as long as necessary (for example, from when the fluctuating display of a special symbol ends until the fluctuating display of the next special symbol starts. ).

In this way, according to the gaming machines of appendices 21-1 and 21-2, it is possible to provide a gaming machine that can suitably output gaming sounds.

[11-22. Gaming machines in Appendix 22]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, when a game ball enters a starting slot, a lottery is held, and based on the result of the lottery, an effect image is displayed on, for example, a liquid crystal display. In addition to such effect images, game sounds are also output from the speaker.

As this type of gaming machine, a gaming machine that outputs sounds that enliven the game in conjunction with an effect image displayed on a liquid crystal display or the like has been disclosed (for example, see Japanese Patent Laid-Open No. 2014-144066).

(22nd issue)
However, in the gaming machine described in JP-A-2014-144066, the secondary volume is maintained at a fixed value and the volume of the effect sound is controlled by the primary volume, so it is difficult to increase the variation in the volume of the effect sound. There is a limit.

In order to solve the above-mentioned 22nd problem, a gaming machine according to appendix 22 having the following configuration is provided.

(1) The gaming machine mentioned in Appendix 22 is
Output means (for example, speaker 24) capable of outputting a predetermined game sound;
sound data setting means (for example, host control circuit 2100) capable of setting sound data (for example, audio data) related to game sounds output from the output means;
a volume control means (for example, a host control circuit 2100 that executes a sound request) having a plurality of playback channels (for example, CH1 to CH31) and capable of controlling the volume output from the output means;
Equipped with
The volume control means includes:
A first volume control means (e.g., a first volume control means (e.g., , a host control circuit 2100) that executes volume control 2810 using a hardware switch, user volume control 2820 using a volume setting screen, and debug volume control 2830 during debugging;
Second volume control means (for example, first playback channel primary control 2840, second playback channel primary control 2850, and a host control circuit 2100) that performs volume control 2860, 2870, 2880 embedded in the audio data;
and configured so that the volume output from the output means can be changed by multiplying the information regarding the volume by the first volume control means and the information regarding the volume by the second volume control means. ,
The second volume control means includes:
Volume control (first playback channel primary control 2840) for controlling each playback channel so that information related to the volume is changed when the predetermined operation is performed;
For each playback channel, even if the predetermined operation is performed, the volume is controlled so that information related to a constant volume (for example, an error sound or a warning sound in case of illegal activity) is output before and after the said operation is performed. control (second playback channel primary control 2850).

According to the game machine of (1) above, the game sound output from the output means is defined by multiplying the information regarding the volume by the first volume control means and the information regarding the volume by the second volume control means. Therefore, it is possible to provide variety in the volume of game sounds. Furthermore, the second volume control means controls each playback channel so that even if a predetermined operation is performed, information related to a constant volume is output before and after the predetermined operation is performed. As a result, even if a predetermined operation is performed, it is possible to perform a control that outputs information related to a certain volume before and after the operation is performed only on a specific playback channel rather than on all channels. .

(2) In the gaming machine described in (1) above,
The first volume control means includes:
A feature is that information related to volume can be controlled by debug volume control during debugging.

According to the game machine of (2) above, the game sound data used in the game can be used as is during debugging, and it is possible to improve work efficiency during debugging.

Further, according to the gaming machine of appendix 22, it is possible to provide a gaming machine that can provide diversity in variations in volume of performance sounds.

[11-23. Each gaming machine from Appendix 23-1 to Appendix 23-58]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, when a game ball enters a starting slot, a lottery is held, and based on the result of the lottery, an effect image is displayed on, for example, a liquid crystal display. In addition to such effect images, game sounds are also output from the speaker.

As this type of gaming machine, a gaming machine is disclosed in which the volume of gaming sound output from a speaker can be adjusted by a player's operation (for example, see Japanese Patent Laid-Open No. 2011-229766).

(23rd issue)
However, if it is possible to adjust the volume of the game sound output from the speakers by manipulating the game sound, this may affect sounds whose volume you do not want to change, such as error sounds and warning sounds. , undesirable.

In order to solve the above twenty-third problem, we provide gaming machines according to appendices 23-1 to 23-5 having the following configurations.

(1) The gaming machine described in Appendix 23-1 is
A plurality of output means (for example, the speaker 24) capable of outputting predetermined game sounds;
an operating means (for example, a volume setting screen) capable of controlling the volume output from the output means;
a sound control means (for example, a host control circuit 2100 that executes a sound request control process) capable of controlling the volume based on the operation of the operation means;
Equipped with
The volume output from the output means is determined by at least first information (for example, output by the second playback channel primary control 2850) having information on a constant volume before and after the operation is performed even if the operation means is operated. and second information (for example, an audio signal output by the first playback channel primary control 2840) having information on the volume that is changed based on the operation of the operating means. is,
The plurality of output means include a dedicated output means (e.g., a dedicated speaker) used to output a specific sound, and a shared output means (e.g., a shared speaker) used to output sounds other than the specific sound. contains at least
The sound control means includes:
The dedicated output means may include a specific sound control means (e.g., step a host control circuit 2100) that executes S1559;
The shared output means may include a non-specific sound control means (for example, a host that executes step S1558) capable of executing control to output the second information so that the volume is changed based on the operation of the operation means. control circuit 2100).

According to the gaming machine of (1) above, the dedicated output means used to output a specific sound outputs a constant volume even if an operator who can control the volume operates it, before and after the operation is performed. controlled so that That is, although the volume can be controlled, the volume does not change before and after operating the operating means, and a constant volume is output. Furthermore, regarding the shared output means used for outputting sounds other than specific sounds, second information is output in which the volume information is changed based on the operation of the operator who can operate the volume. It becomes possible to suitably adjust the volume.

(2) In the gaming machine described in (1) above,
The dedicated output means is a vibration speaker.

According to the gaming machine (2) above, it is possible to output a specific sound (for example, an error sound, a warning sound, etc.) at a constant volume from the vibration speaker.

(3) In the gaming machine of (1) or (2) above,
Dedicated output setting means (for example, executing the process of step S1201) for setting which of the plurality of output means is to be used as the dedicated output means when the power is turned on (for example, during various initialization processes of step S1201) further comprising a host control circuit 2100),
The data relating to the specific sound (for example, the audio data relating to the specific sound specified by the SAC number) is characterized in that it is specified that the output destination of the specific sound is the dedicated output means. shall be.

According to the game machine (3) above, when the power is turned on, the output destination of data related to a specific sound is specified in the dedicated output means, so it is possible to set which output means is to be used as the dedicated output means. In addition, since it is specified that audio data relating to a specific sound that is output at a constant volume is output from a dedicated output means, it is possible to increase versatility.

(1) The gaming machine described in Appendix 23-2 is
Output means (for example, speaker 24) capable of outputting a predetermined game sound;
an operating means (for example, a volume setting screen) capable of controlling the volume output from the output means;
a sound control means (for example, a host control circuit 2100 that executes a sound request control process) having a plurality of playback channels and capable of controlling the volume based on the operation of the operation means;
Equipped with
The volume output from the output means is determined by at least first information (for example, output by the second playback channel primary control 2850) having information on a constant volume before and after the operation is performed even if the operation means is operated. and second information (for example, an audio signal output by the first playback channel primary control 2840) having information on the volume that is changed based on the operation of the operating means. is,
The plurality of playback channels include at least a dedicated channel used to output a specific sound and a shared channel used to output sounds other than the specific sound,
The sound control means includes:
Regarding the dedicated channel, a specific sound control means (for example, step S1580 a host control circuit 2100) that executes
Regarding the shared channel, non-specific sound control means capable of executing control to output the second information so that the volume is changed based on the operation of the operation means (for example, a host control unit that executes step S1581) circuit 2100).

According to the gaming machine of (1) above, even if the operating means is operated for the dedicated channel used to output a specific sound, the control is performed so that a constant volume is output before and after the operation is performed. . That is, although the volume can be controlled, the volume does not change before and after operating the operating means, and constant volume information is output. In addition, for shared channels used to output sounds other than specific sounds, the volume is controlled to change based on the operation of the operator who can control the volume, so it is recommended to adjust the volume. It becomes possible to do so.

(2) In the gaming machine described in (1) above,
When the power is turned on, set dedicated channels (for example, CH31, CH32) used for outputting the specific sound and shared channels (for example, CH1 to CH30) used for outputting sounds other than the specific sound. channel setting means (for example, host control circuit 2100 that executes the process of step S1201),
Sound information registration means (for example, a host that registers the SAC number) for registering sound information (for example, SAC number) related to data of each of the specific sound and sounds other than the specific sound in the dedicated channel or the shared channel; control circuit 2100);
It is characterized by further comprising:

According to the gaming machine of (2) above, when the power is turned on, a dedicated channel used for outputting a specific sound and a shared channel used for outputting sounds other than the specific sound are set, and a specific Since the sound information related to the data of each sound and sounds other than the specific sound is registered in each channel, it is possible to increase versatility.

(1) The gaming machines listed in Appendix 23-3 are:
Output means (for example, speaker 24) capable of outputting a predetermined game sound;
an operating means (for example, a volume setting screen) capable of controlling the volume output from the output means;
a sound control means (for example, a host control circuit 2100 that executes a sound request control process) having a reproduction channel and capable of controlling the volume based on the operation of the operation means;
Equipped with
The volume output from the output means is determined by at least first information (for example, output by the second playback channel primary control 2850) having information on a constant volume before and after the operation is performed even if the operation means is operated. and second information (for example, an audio signal output by the first playback channel primary control 2840) having information on the volume that is changed based on the operation of the operating means. is,
The sound control means includes:
a data determining unit (for example, a host control circuit 2100 that executes step S1599) that determines whether data of a game sound being reproduced on the reproduction channel is specific data of a specific sound;
When the data determining means determines that the data of the game sound being reproduced on the reproduction channel is the specific data, even if the operating means is operated, a constant volume is output before and after the operation is performed. specific sound control means (for example, host control circuit 2100 that executes step S1600) capable of executing control to output the first information;
When the data determining means determines that the data of the game sound being reproduced on the reproduction channel is non-specific data, the second information is transmitted so that the volume is changed based on the operation of the operating means. The present invention is characterized in that it includes non-specific sound control means (for example, host control circuit 2100 that executes step S1601) that can execute output control.

According to the gaming machine of (1) above, if the data of the game sound being played is determined to be specific data, even if the operating means is operated, a constant volume is output before and after the operation is performed. In addition, if it is determined that the game sound data being played is non-specific data, the volume is controlled to be changed based on the operation of the operating means, so the volume cannot be adjusted. It becomes possible to carry out the process suitably.

(1) The gaming machine described in Appendix 23-4 is
Output means (for example, speaker 24) capable of outputting a predetermined game sound;
an operating means (for example, a volume setting screen) capable of controlling the volume output from the output means;
a sound control means (for example, a host control circuit 2100 that executes a sound request control process) having a reproduction channel and capable of controlling the volume based on the operation of the operation means;
Equipped with
The volume output from the output means is determined by at least first information (for example, output by the second playback channel primary control 2850) having information on a constant volume before and after the operation is performed even if the operation means is operated. and second information (for example, an audio signal output by the first playback channel primary control 2840) having information on the volume that is changed based on the operation of the operating means. is,
The sound control means includes:
When the sound information (for example, SAC number) corresponding to the sound output played on the playback channel is specific sound information, even if the operation means is operated, a constant volume is output before and after the operation is performed. specific sound control means (for example, host control circuit 2100 that executes step S1621) capable of setting the first information to the reproduction channel so that the playback channel is set to the first information;
When the sound information (for example, SAC number) corresponding to the game sound played on the playback channel is non-specific sound information, the playback is performed such that the volume is changed based on the operation of the operation means. The present invention is characterized in that it includes a non-specific sound control means (for example, a host control circuit 2100 that executes step S1623) that can set the second information to a channel.

According to the gaming machine of (1) above, if the sound information (for example, SAC number) corresponding to the sound output played on the playback channel is specific sound information, the volume will be constant even if the operating means is operated. If the sound information (for example, SAC number) corresponding to the game sound that is controlled to be output and played on the playback channel is non-specific sound information, the volume may be adjusted based on the operation of the operating means. Therefore, the volume can be suitably adjusted.

(1) The gaming machine described in Appendix 23-5 is
Output means (for example, speaker 24) capable of outputting a predetermined game sound;
an operating means (for example, a volume setting screen) capable of controlling the volume output from the output means;
a sound control means (for example, a host control circuit 2100 that executes a sound request control process) having a reproduction channel and capable of controlling the volume based on the operation of the operation means;
Equipped with
The volume output from the output means is determined by at least first information (for example, output by the second playback channel primary control 285) having information on a constant volume before and after the operation is performed even if the operation means is operated second information (for example, an audio signal output by the first playback channel primary control 2840) having information on a volume that is changed based on the operation of the operating means; Third information having information on the volume incorporated in the sound data specified from the sound information registered in the playback channel (for example, the audio signal output by the volume control 2860, 2870, 2880 incorporated in the audio data) ) and
The sound control means includes:
When the sound data specified from the sound information (for example, SAC number) registered in the playback channel is specific sound data (for example, sound data that is not affected by volume adjustment), the specific sound data an identification information setting means (for example, the host control circuit 2100 that executes the process of step S1632) that sets in advance identification information that can be identified (for example, a flag indicating whether each channel is affected by volume adjustment); ,
When setting the volume for the playback channel, if the sound data specified from the sound information (for example, SAC number) can be identified as the specific sound data by the identification information (for example, if YES is determined in step S1637). first volume setting means (for example, step a host control circuit 2100) capable of executing the process of S1641;
When setting the volume of the playback channel, if the sound data specified from the sound information can be identified from the identification information as not being the specific sound data (for example, when the determination is NO in step S1637), the operation a second volume setting means (for example, a host control circuit 2100 capable of executing the process of step S1638) capable of setting the second information to the reproduction channel so that the volume is changed based on the operation of the means;
In setting the volume to the reproduction channel, the present invention is characterized by comprising a third volume setting means (for example, a host control circuit 2100 capable of executing the process of step S1644) that sets third information to the reproduction channel.

According to the gaming machine of (1) above, identification information that can identify that the sound data specified from the sound information registered in the playback channel is specific sound data is set in advance, and the sound data specified from the sound information is set in advance. When sound information can be identified as specific sound data by identification information, a constant volume is set to be output even if an operating means is operated. Further, the volume is set to be changed based on sound data specified from the sound information registered in the playback channel. Further, third information having volume information incorporated in the sound data specified from the sound information registered in the playback channel is set in the playback channel. In this way, it becomes possible to suitably adjust the volume.

Note that in the gaming machine described above, when the sound data specified from the sound information (for example, SAC number) registered in the playback channel can be identified as specific sound data by the identification information (for example, if YES is selected in step S1637). Even if the operating means is operated, a constant volume is output before and after the operation is performed, but the constant volume in this case is always information related to the maximum volume. Also good. However, even if the sound data specified from the sound information registered in the playback channel is specific sound data (first information related to a certain volume), the sound data registered in the playback channel (for example, the SAC number ), the output volume may not be a constant volume.

In this way, according to each of the gaming machines described in Supplementary Notes 23-1 to 23-5, it is possible to provide a gaming machine in which the volume can be suitably adjusted.

[11-24. Gaming machines in Appendix 24]
Conventionally, a game machine such as a pachinko machine is equipped with a light-emitting means made of a light-emitting body such as an LED on the front side of the game machine, and a game is known in which the light-emitting means is lit or flashed in a predetermined manner to create a light-emitting effect. ing.

As this type of gaming machine, a gaming machine is known in which the brightness of a light emitting device can be adjusted by, for example, an operation by a player (see, for example, Japanese Patent Laid-Open No. 2008-295551).

(24th issue)
According to the gaming machine described in Japanese Patent Application Laid-open No. 2008-295551, although the brightness of the light emitting means can be controlled by the player, if the light emitting means can emit light in full color, changing the brightness will cause the light to emit less. Even the color may change significantly.

In order to solve the twenty-fourth problem described above, a gaming machine according to appendix 24 is provided having the following configuration.

(1) The gaming machine mentioned in Appendix 24 is:
Predetermined light emitting means (for example, lamp (LED) group 25),
an operating means (for example, a brightness setting screen displayed on a liquid crystal display device used as the display device 16) operable to select the brightness of the light emitting means;
Storage means (e.g., attenuation table) for storing a brightness information table (e.g., attenuation table) in which brightness information is set for each of a plurality of colors (e.g., RGB) as brightness information (e.g., brightness attenuation rate) related to the brightness of the light emitting means. sub-main ROM2050) and
brightness control means (for example, host control circuit 2100) capable of controlling the brightness of the light emitting means based on the brightness information table when the brightness is selected by the operation means;
Equipped with
The storage means is
storing a brightness information table in which the brightness information is set for each of the plurality of colors in correspondence with brightness selectable by the operating means;
The brightness control means includes:
Based on the brightness information table corresponding to the brightness selected by the operating means, the brightness of the light emitting means can be controlled so that the attenuation rate of blue is the largest and the attenuation rate of red is the smallest among the plurality of colors. It is characterized by being configured as follows.

According to the gaming machine described in (1) above, the light emitting means controls the light emitting device so that the attenuation rate of blue is the largest and the attenuation rate of red is the smallest among the plurality of colors, based on the luminance information set for each of the plurality of colors. Since the light emission of the light emitting device is controlled, even if the brightness of the light emitting means is changed by, for example, an operation by a player or the like, it is possible to suppress a change in the emitted light color, that is, maintain the white balance.

In this way, according to the gaming machine (1) above, it is possible to provide a gaming machine that can change the brightness while suppressing changes in the emitted light color.

[11-25. Gaming machines in Appendix 25]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, when a game ball enters a starting slot, a lottery is held, and based on the result of the lottery, an effect image is displayed on, for example, a liquid crystal display.

As a game machine of this type, a game machine has been proposed in which a movable body is disposed on a game board, and by operating the movable body, it gives an impact to the player and increases his desire to play the game. (For example, see Japanese Patent Application Publication No. 2006-288694).

(25th issue)
For example, in a gaming machine that operates a movable body as disclosed in Japanese Patent Application Laid-open No. 2006-288694, the movements of the movable body have become more diverse in recent years, and the control for operating the movable body has become more complex. Therefore, in recent years, there has been a desire for a gaming machine that can suppress the control load while providing diversity in the movement of the movable body.

In order to solve the above twenty-first problem, a gaming machine according to appendix 25 is provided having the following configuration.

(1) The gaming machine set forth in Appendix 25 is:
with a prescribed role,
a control means (for example, host control circuit 2100) capable of controlling the operation of the predetermined accessory;
an actuating member (for example, a solenoid) capable of actuating a member constituting the accessory;
a plurality of light emitting means (e.g. LEDs);
a plurality of connection parts (for example, Port0 to Port23) capable of transmitting signals to the connected light-emitting means by being connected to any one of the plurality of light-emitting means;
a light emission control means (for example, audio/LED control circuit 2200) capable of controlling the light emission means by transmitting a signal to the light emission means through the connection part;
Equipped with
The actuating member is
It is connected to any one of the plurality of connection parts, and is configured to be able to operate a member constituting the accessory in response to a signal from the light emission control means,
The control means includes:
The actuating member connected to any one of the plurality of connecting parts is configured to be able to be actuated in synchronization with the predetermined accessory.

According to the game machine of (1) above, even if the number of actuating members increases due to diversification of the movement of the accessory, the control for operating the accessory while maintaining the diversity of the movement of the accessory is possible. It becomes possible to suppress the load and synchronize the accessory and the operating member.

In this way, according to the gaming machine (1) above, it is possible to provide a gaming machine that can suppress the control load.

[11-26. Gaming machines in Appendix 26]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, when a game ball enters a starting slot, a lottery is held, and based on the result of the lottery, an effect image is displayed on, for example, a liquid crystal display.

This type of gaming machine reads compressed data from a CGROM that stores compressed data of still images and moving images displayed on a liquid crystal display, decompresses the read compressed data, and outputs image data to the liquid crystal display. A gaming machine that generates a game is known (for example, see Japanese Patent Laid-Open No. 2016-159026).

(26th issue)
However, as described in Japanese Unexamined Patent Publication No. 2016-159026, for example, when reading compressed data from a CGROM and generating image data to be output, if the amount of data is large, it takes time to load the data. . In this case, the watchdog reset may occur even though the loading process is progressing normally, which is not preferable.

In order to solve the twenty-sixth problem described above, a gaming machine according to appendix 26 having the following configuration is provided.

(1) The gaming machine set forth in Supplementary Note 26 is:
A read-only storage area (for example, sub-main ROM 2050 or CGROM 2060) in which game data related to games is stored;
A volatile storage area (for example, SRAM 2100b or built-in VRAM 2370) that can read and write gaming data related to gaming;
a transfer execution unit (for example, a host control circuit 2100 that executes the data load process in FIG. 93) that executes a load process of reading the gaming data stored in the read-only storage area and writing it to the volatile storage area;
watchdog timer,
Clearing means (for example, a host control circuit 2100 having a CPU processor) that clears the clock of the watchdog timer after a predetermined period of time has elapsed;
Equipped with
The transfer execution means includes:
The present invention is characterized by comprising a load reprocessing means (host control circuit 2100 that executes the process of step S1656) that resets the watchdog timer and executes the load process again when the load process exceeds a predetermined time.

According to the gaming machine of (1) above, when the time required for the load process by the transfer execution means exceeds a predetermined upper limit, the load process is ended and the load process is executed again. Even if it takes time to recover, automatic recovery is possible.

In this way, according to the gaming machine of appendix 26, even if the loading process takes time, it is possible to suitably proceed with the loading process.

(2) In the gaming machine described in (1) above,
The clearing means is
If the load process does not exceed the predetermined time, clear the watchdog timer (for example, the process in step S1655), and only when the load process exceeds the predetermined time, clock the watchdog timer. It is configured such that error processing (for example, the processing in step S1656) is executed without clearing,
The transfer execution means includes:
The error processing is characterized in that the load processing is executed again.

According to the gaming machine (2) above, the watchdog timer is cleared when the loading process does not exceed the predetermined time, but the watchdog timer is not cleared only when the loading process exceeds the predetermined time. Since error processing is executed at the end of the process, it is possible to understand that the load processing could not be completed due to the occurrence of an error.

[11-27. Gaming machines listed in Appendix 27-1 and Appendix 27-2]
BACKGROUND ART Conventionally, in gaming machines such as pachinko machines, a lottery is held when a game ball enters a starting slot, and if the result of the lottery is a jackpot, a jackpot game is played. Furthermore, it is provided with, for example, a liquid crystal display on which an effect image is displayed, and an effect image determined by a lottery is displayed on this liquid crystal display.

In this type of gaming machine, a lottery is held in various situations, and the lottery is performed by generating and obtaining random numbers. For example, in JP 2017-023629, the number of digits of a newly acquired random number is determined, one-digit numbers are calculated from the standard random number by the determined number of digits, and the calculated value is assigned to each digit. It describes how to place them and obtain new values.

(27th issue)
In the random number acquisition process of acquiring random numbers, it is required that the acquired random numbers are unlikely to have any regularity. However, if the processing is complicated, the control load increases, which is not preferable. Therefore, it is preferable to perform random number acquisition processing in which regularity is unlikely to occur while suppressing an increase in control load.

In order to solve the above twenty-seventh problem, we provide the gaming machine of attachment 27-1 and the gaming machine of attachment 27-2 having the following configurations.

(1) The gaming machine specified in Supplementary Note 27-1 is
A gaming machine that performs a lottery using predetermined random numbers,
A real-time clock (for example, RTC) that can output time information,
Random number generation means (for example, host control circuit 2100 that executes the processing of FIGS. 95 and 96) that generates random numbers used in a predetermined lottery,
Equipped with
The random number generation means is
initialization means (for example, a host control circuit 2100 that executes random number initialization processing) that acquires time information from the real-time clock and generates an initial value of a random number using the acquired time information;
unsteady updating means (host control circuit 2100 that executes the process of FIG. 96) that updates the random number when the generated random number is used in the lottery;
Constant updating means (host control circuit 2100 that executes the process of FIG. 95) that regularly updates the generated random numbers even if they are not used in the lottery;
It is characterized by

According to the gaming machine (1) above, the initial value of the random number is generated using the time information obtained from the real-time clock, so the obtained random number can be made random, and the obtained random number is biased. can be suppressed from occurring. In particular, since the initial value of the random number is affected by the time when the power is turned on down to the minute or second level, it is possible to change the initial value each time.

(1) The gaming machine described in Appendix 27-2 is
A gaming machine that performs a lottery using predetermined random numbers,
Random number table creation means that creates a random number table in which a plurality of random numbers are registered using any one of the random number seeds (for example, random number seeds a to h) (for example, executes the process of step S1704) host control circuit 2100);
Random number acquisition means that acquires random numbers to be used in a predetermined lottery by referring to the random number table created by the random number table creation means (for example, in the random number acquisition process of step S1706, from the random number table created in step S1704) a host control circuit 2100) that obtains random numbers;
Reference position updating means for updating the reference position of the random number table at a timing different from the timing at which the random number table is created (in step S1706, a host control circuit that updates the reference position of the random number table when a random number is acquired from the random number table) 2100) and
Equipped with
The random number acquisition means is
After obtaining a random number by referring to the random number table, it is possible to obtain a random number to be used in the predetermined lottery by referring to the same random number table in which the reference position has been updated without creating the random number table (for example, The random number acquisition process in step S1706 can be executed in the packet reception loop shown in FIG. 98).

According to the gaming machine described in (1) above, even if there are multiple opportunities to obtain random numbers, the random numbers are only obtained by updating the reference position using the same random number table that has already been created. It becomes possible to lighten the control load while providing irregularity to the random numbers.

In this way, according to the gaming machine of Supplementary Note 27-1 and the gaming machine of Supplementary Note 27-2, it is possible to provide a gaming machine that can execute processing in which regularity is unlikely to occur while suppressing an increase in control load. .

[11-28. Gaming machines in Appendix 28]
Conventionally, in gaming machines such as pachinko machines and pachi-slot machines, a lottery is held when a predetermined condition is met, and a variable display of symbols is displayed in a display area based on the result of the lottery. When the symbols stop at a specific combination, a special game state advantageous to the player is entered. Also, when the symbols are displayed in a fluctuating manner, various effects are performed.

As this type of gaming machine, a gaming machine that performs performances using movable accessories driven by a motor is known. In a gaming machine that performs a performance using such movable accessories, when a problem such as the movable accessory not returning to the initial position occurs, a process (retry process) to return the movable accessory to the initial position is performed. ) has been proposed (for example, see Japanese Patent Laid-Open No. 2007-268038).

The gaming machine described in JP-A No. 2007-268038 is provided with a reference position sensor that detects whether or not a movable accessory exists at an operation reference position (initial position), and based on the detection result of this reference position sensor. Executing retry processing. When a problem occurs such as the movable accessory not returning to its initial position, if the movable accessory does not return to its initial position even after repeated retry processing, it is determined to be an error and a predetermined error is detected. Processing is being executed.

(28th issue)
However, as problems related to the operation of the movable accessory, there are also minor errors that are resolved when the variable display of the symbol is executed a plurality of times. If such a minor error is determined to be an error, there is a problem in that unnecessary error processing increases.

In order to solve the above twenty-eighth problem, a gaming machine according to appendix 28 is provided having the following configuration.

(1) The gaming machine set forth in Supplementary Note 28 is:
A game control means that can execute one game by starting the variable display of symbols (for example, special symbols) when a predetermined starting condition is met, and stopping the variable display of the symbols when a predetermined end condition is met. For example, the main CPU 101) of the main control circuit 100,
A production control means (for example, a host control circuit 2100 having a CPU processor) that can execute control related to the operation of movable members (for example, the accessory group 1000, etc.);
Equipped with
The game control means is
At least, the start information of the variable display of the symbols and the stop information of the variable display of the symbols can be transmitted to the production control means (for example, the main CPU 101 can execute the process of step S55),
The performance control means is
a first determination unit (for example, a host control circuit 2100 that executes the process of step S19141) that determines whether or not a state related to the operation of the movable member is normal at the timing when the variable display of the symbol is started;
If it is determined by the first determining means that the state related to the operation of the movable member is not normal, a first restoration process (for example, initial position restoration operation transition setting in step S19147) can be executed to normalize the state. a first recovery control means (for example, the host control circuit 2100 that executes the process of step S19147),
a second determining means (for example, a host control circuit 2100 that executes the process of step S19171) that determines whether or not the state related to the operation of the movable member is normal at the timing when the fluctuating display of the symbol is stopped;
If it is determined by the second determination means that the state related to the operation of the movable member is not normal, a second determination unit that can perform a second recovery process (for example, the motor driver reset process in step S19176) so that the state of the operation of the movable member is normalized is determined by the second determination unit. 2 recovery control means (for example, a host control circuit 2100 that executes the process of step S19176),
The first determining means includes:
In a plurality of games, it is possible to determine whether or not a state related to the operation of the predetermined accessory or the movable member is normal at the timing when the variable display of the symbol starts.
The first recovery control means includes:
Each time the first determination means determines that the game is not normal in the plurality of games, the first recovery process is configured to be executable;
The second determining means is
In a plurality of games, it is possible to determine whether or not the state related to the operation of the predetermined accessory or the movable member is normal at the timing when the fluctuating display of the symbol is stopped;
The second recovery control means includes:
The second recovery process is configured to be able to be executed each time the second determination means determines that the game is not normal during the plurality of games;
The performance control means further includes:
a first counting unit (for example, a host control circuit 2100 that executes the process of step S19144) that counts the number of times the first recovery process has been executed by the first recovery control unit;
a second counting unit (for example, a host control circuit 2100 that executes the process of step S19177) that counts the number of times the second recovery process has been executed by the second recovery control unit;
The result of counting by the first counting means has reached a first prescribed number of times (for example, 10 times), and the result of counting by the second counting means has reached a second prescribed number of times (for example, 10 times). If at least one of the above conditions is satisfied, the movable member is placed in an inoperable state (e.g., error motor operation stopped state), and an accessory inoperable means (e.g., host control circuit 2100) is provided. It is characterized by

According to the gaming machine described in (1) above, just because the first determining means determines that the state related to the operation of the movable member is not normal, the movable member is not rendered inoperable, and the first recovery process is performed. Similarly, if the second determination means determines that the state related to the operation of the movable member is not normal, the movable member is not rendered inoperable, and the second recovery process is performed. Then, when the number of games in which the first recovery process has been executed reaches the first specified number of times, or when the number of games in which the first recovery process has been executed reaches the first specified number of times, the movable member is It is in an inoperable state. Therefore, the inoperable state does not occur only when a minor error occurs, but the inoperable state does not occur when recovery is not possible even though the first recovery process or the second recovery process has been executed over multiple games. This makes it possible to prevent serious errors from occurring.

Furthermore, it is determined whether the state related to the operation of the movable member is normal or not at each timing when the variable display of the symbols is started and at the timing when the variable display of the symbols is stopped. Then, the recovery process and the number of games in which the recovery process was executed are counted separately at the timing when the variable display of symbols starts and the timing when the variable display of symbols is stopped, and the number of times the recovery process is executed. Since the operation is disabled when either one reaches a specified number of times, it is possible to further suppress the occurrence of serious errors.

(2) In the gaming machine described in (1) above,
position detection means (for example, a group of accessory detection sensors 1002) capable of detecting that the movable member is present at a specific position (for example, an initial position);
a drive means capable of moving the movable member from the specific position to a prescribed position (for example, maximum range of motion);
Furthermore,
The first determining means includes:
determining that the movable member is not normal when it is not present at least in the specific position;
The second determining means is
It is characterized in that when the movable member cannot be moved from the specific position to at least the prescribed position by the driving means (for example, when a motor error is detected), it is determined that the movable member is not normal.

According to the gaming machine of (2) above, it is determined whether or not the state related to the operation of the movable member is normal, which is performed at the timing when the variable display of symbols is started, and the timing at which the variable display of symbols is stopped. Since the determination of whether or not the state related to the operation of the movable member is normal is performed from different viewpoints, the accuracy of determining the occurrence of an error can be improved. As a result, it becomes possible to prevent the occurrence of serious errors with higher accuracy while avoiding the state of being inoperable due to the occurrence of even a minor error.

In this way, according to appendix 28, it is possible to provide a gaming machine that can suitably perform error handling.

[11-29. Each gaming machine listed in Appendix 29-1 to Appendix 29-3]
Conventionally, in gaming machines such as pachinko machines and pachi-slot machines, a lottery is held when a predetermined condition is met, and a variable display of symbols is displayed in a display area based on the result of the lottery. When the symbols stop at a specific combination, a special game state advantageous to the player is entered. Also, when the symbols are displayed in a fluctuating manner, various effects are performed.

As this type of gaming machine, a gaming machine that performs performances using movable accessories driven by a motor is known. In a gaming machine that performs a performance using such movable accessories, when a problem such as the movable accessory not returning to the initial position occurs, a process (retry process) to return the movable accessory to the initial position is performed. ) has been proposed (for example, see Japanese Patent Laid-Open No. 2007-268038).

The gaming machine described in JP-A No. 2007-268038 is provided with a reference position sensor that detects whether or not a movable accessory exists at an operation reference position (initial position), and based on the detection result of this reference position sensor. Executing retry processing. When a problem occurs such as the movable accessory not returning to its initial position, if the movable accessory does not return to its initial position even after repeated retry processing, it is determined to be an error and a predetermined error is detected. Processing is being executed.

(29th issue)
However, as problems related to the operation of the movable accessory, there are also minor errors that are resolved when the variable display of the symbol is executed a plurality of times. If such a minor error is determined to be an error, unnecessary error processing will increase, which is not appropriate. On the other hand, performances using movable accessories are an important element in increasing game interest, so if a game is played on a gaming machine where an error related to the movement of movable accessories has occurred, the interest will inevitably decrease. do not have. Therefore, it is preferable that a gaming machine in which a movable accessory cannot operate normally be managed by an authorized person in charge of the hall, including the decision as to whether to continue or stop the operation.

In order to solve the twenty-ninth problem described above, gaming machines according to attachments 29-1 to 229-3 having the following configurations are provided.

(1) The gaming machine specified in Supplementary Note 29-1 is
It is possible to execute control related to the progress of the game based on any one of a plurality of set values, and when a predetermined starting condition is met, the variable display of symbols (for example, special symbols) is started, and the predetermined A game control means (for example, the main CPU 101 of the main control circuit 100) capable of executing one game by stopping the fluctuating display of the symbols when the termination condition is satisfied;
a setting operation means (for example, setting key 328) that is operated when changing at least the one setting value;
A production control means (for example, a host control circuit 2100 having a CPU processor) capable of executing control related to the operation of the movable member;
When a power-on operation is performed, a power supply means (for example, a power supply circuit 338) capable of supplying power to the game control means and the performance control means;
Equipped with
The game control means is
When the power is turned on while at least the setting operation means is operated, the setting change state control means (for example, in step S24) controls the setting change state in which the one set value can be changed. It has a main CPU 101) capable of executing processing, and is capable of transmitting various information (for example, information related to the progress of the game, setting change information indicating that a setting value has been changed) to the effect control means. Yes (for example, the main CPU 101 can execute the process of step S55),
The performance control means is
A determining means (for example, a host control circuit 2100 that executes the processing of step S19141 and step S19147) that determines whether the state related to the operation of the movable member is normal at a predetermined timing in the one game;
If it is determined by the determination means that the state related to the operation of the movable member is not normal, a restoration process (for example, the initial position restoration operation transition setting in step S19147 or the motor driver reset process in step S19176) is performed so that the state related to the operation of the movable member is not normal. ); recovery control means (for example, host control circuit 2100) capable of executing
and is capable of receiving various information transmitted from the game control means,
The determining means is
In a plurality of games, it is possible to determine whether or not a state related to the operation of the movable member is normal at a predetermined timing in each game, and
The recovery control means includes:
The restoration process is configured to be able to be executed each time the determining means determines that the game is not normal during the plurality of games;
The performance control means further includes:
a counting unit for counting the number of times the recovery process has been executed by the recovery control unit (for example, a host control circuit 2100 that executes the processes in step S19144 and step S19177);
When the result of counting by the counting means reaches a predetermined number of times (for example, 10 times), accessory operation disabling means (for example, a host control circuit 2100) that executes the processing in step S19146 and step S19179;
Based on the reception of setting change information indicating that the first set value has been changed, a canceling unit for canceling the inoperable state caused by the accessory inoperable unit (for example, executes the process of step S311) The present invention is characterized by having a host control circuit 2100).

According to the gaming machine of (1) above, even if the determination means determines that the state related to the operation of the movable member is not normal, the state is not rendered inoperable, and the restoration process is performed. Then, when the number of times the recovery process has been executed reaches a predetermined number of times, the movable member is rendered inoperable. Therefore, the occurrence of a minor error will not cause the game to become inoperable; instead, it will become inoperable when recovery cannot be performed even after the recovery process has been executed multiple times, thereby preventing the occurrence of a serious error. It becomes possible to suppress the

By the way, performances using movable members are an important element in increasing game interest, so if a game is played on a gaming machine in which the movable members cannot operate normally, the interest will inevitably decrease. Therefore, in the gaming machine of (1) above, by making it possible to cancel the inoperable state based on the reception of setting change information indicating that one setting value has been changed, the movable member becomes inoperable. Important judgments such as whether or not to operate a gaming machine that has become inoperable can be made by authorized hall personnel, and it is possible to prevent an unauthorized person from canceling the error motor operation stop state.

(2) In the gaming machine described in (1) above,
Further comprising a position detection means (for example, a group of accessory detection sensors 1002) capable of detecting that the movable member is present at a specific position (for example, an initial position),
The determining means is
comprising a position determining means for determining that the movable member is not normal when it is not present at least in the specific position;
The recovery control means includes:
Every time the position determining means determines that the movable member does not exist at the specific position, a position recovery process (for example, initial position recovery operation transition setting in step S19147) is executed to return the movable member to the specific position. has a position recovery control means (for example, a host control circuit 2100 that executes the process of step S19147),
The release means is
Based on the reception of setting change information indicating that the first setting value has been changed, the number of times the position recovery process has been executed, which is counted by the counting means, is reset (for example, in step S323). process)
It is characterized by

According to the gaming machine of (2) above, even if the machine is not in an inoperable state, when the position recovery process for returning the movable member to a specific position has been executed one or more times, the position recovery process The number of times that has been executed can be reset based on receiving setting change information indicating that one setting value has been changed. Therefore, the resetting of the number of times the position recovery process has been executed is performed by an authorized person related to the hall, and not by an unauthorized person, making it possible to appropriately manage the gaming machine.

(3) In the gaming machine described in (1) or (2) above,
Further comprising a driving means (for example, a motor for operating the accessory group 1000) capable of moving the movable member from a specific position (for example, the initial position) to a prescribed position (for example, the maximum operating range). Prepare,
The determining means is
Operation determining means (for example, It has a host control circuit 2100) that executes the process of step S19171,
The recovery control means includes:
Operation recovery control that executes operation recovery processing (for example, motor driver reset processing in step S19176) that resets a driver of the drive means each time the operation determination means determines that a state related to the operation of the movable member is not normal. means (e.g., host control circuit 2100);
The release means is
Based on the reception of setting change information indicating that the first setting value has been changed, the number of times the operation recovery process has been executed, which is counted by the counting means, is reset (for example, in step S323). process)
It is characterized by

According to the gaming machine of (3) above, even if the machine is not in an inoperable state, when the operation recovery process for resetting the driver of the driving means has been executed one or more times, the operation recovery process is executed. The number of executions can be reset based on receiving setting change information indicating that one setting value has been changed. Therefore, the resetting of the number of times the operation recovery process has been executed is performed by an authorized person related to the hall, and not by an unauthorized person, making it possible to properly manage the gaming machine.

(1) The gaming machine specified in Supplementary Note 29-2 is
It is possible to execute control related to the progress of the game based on any one of a plurality of set values, and has a storage means (for example, main ROM 102) capable of storing game information related to the progress of the game, A game control means that can execute one game by starting the variable display of symbols (for example, special symbols) when a predetermined starting condition is met, and stopping the variable display of the symbols when a predetermined end condition is met. For example, the main CPU 101) of the main control circuit 100,
a setting operation means (for example, setting key 328) that is operated when changing at least the one setting value;
at least a specific operation means (for example, backup clear switch 330) that is operated when erasing game information stored in the storage means;
A production control means (for example, a host control circuit 2100 having a CPU processor) capable of executing control related to the operation of the movable member;
When a power-on operation is performed, a power supply means (for example, a power supply circuit 338) capable of supplying power to the game control means and the performance control means;
Equipped with
The game control means is
Setting change state control for controlling to a setting change state in which the one setting value can be changed when the specific operation means is operated and the power is turned on while the setting operation means is being operated. means (for example, main CPU 101 capable of executing the process of step S24);
When at least the operation of the specific operation means and the power-on operation are performed, a game information erasing means (for example, a means capable of executing the process of step S2420) capable of erasing the game information stored in the storage means main CPU101) and
and transmits various information (for example, information related to the progress of the game, setting change information indicating that one setting value has been changed, information indicating that the game information has been deleted) to the production control means. transmission is possible (for example, the main CPU 101 is capable of executing the process of step S55),
The performance control means is
A determining means (for example, a host control circuit 2100 that executes the processing of step S19141 and step S19147) that determines whether the state related to the operation of the movable member is normal at a predetermined timing in the one game;
If it is determined by the determination means that the state related to the operation of the movable member is not normal, a restoration process (for example, the initial position restoration operation transition setting in step S19147 or the motor driver reset process in step S19176) is performed so that the state related to the operation of the movable member is not normal. ); and a recovery control means (for example, host control circuit 2100) capable of executing
The determining means is
In a plurality of games, it is possible to determine whether or not a state related to the operation of the movable member is normal at a predetermined timing in each game, and
The recovery control means includes:
The restoration process is configured to be able to be executed each time the determining means determines that the game is not normal during the plurality of games;
The performance control means further includes:
a counting unit for counting the number of times the recovery process has been executed by the recovery control unit (for example, a host control circuit 2100 that executes the processes in step S191444 and step S19177);
When the result of counting by the counting means reaches a predetermined number of times (for example, 10 times), accessory operation disabling means (for example, a host control circuit 2100) that executes the processing in step S19146 and step S19179;
a canceling unit (for example, a host control circuit 2100 that executes the process of step S311) that cancels the inoperable state caused by the accessory object inoperable unit based on the establishment of a predetermined condition;
The release means is
When the setting change state is not controlled after the power is turned on, even if an operation to delete the game information stored in the storage means is performed, the disabling state by the accessory disabling means is not released; It is characterized in that it is configured to cancel the inoperable state by the accessory object inoperable means (for example, execute the process of step S311) when the setting change state is controlled after the power is turned on.

According to the gaming machine of (1) above, even if the determination means determines that the state related to the operation of the movable member is not normal, the state is not rendered inoperable, and the restoration process is performed. Then, when the number of times the recovery process has been executed reaches a predetermined number of times, the movable member is rendered inoperable. Therefore, the occurrence of a minor error will not cause the game to become inoperable; instead, it will become inoperable when recovery cannot be performed even after the recovery process has been executed multiple times, thereby preventing the occurrence of a serious error. It becomes possible to suppress the

By the way, performances using movable members are an important element in increasing game interest, so if a game is played on a gaming machine in which the movable members cannot operate normally, the interest will inevitably decrease. Therefore, in the above gaming machine (1), if the setting change state is not controlled, the inoperable state will not be released even if an operation to delete the gaming information stored in the storage means is performed, and the setting change state will not be released. The inoperable state is released when the change state is controlled. As a result, important decisions such as whether or not to operate a gaming machine whose movable parts have become inoperable will be made by authorized hall personnel, and the error motor operation stop state cannot be canceled by unauthorized persons. You can do it like this.

(2) In the gaming machine described in (1) above,
Further comprising a driving means (for example, a motor that operates the accessory group 1000) that can move the movable member from the specific position to a prescribed position,
The determining means is
Operation determining means (for example, when the movable member cannot be moved from the specific position toward at least the prescribed position by the driving means) to determine that the movable member is not normal (for example, when a motor error is detected); It has a host control circuit 2100) that executes the process of step S19171,
The recovery control means includes:
Even if the determination means determines that the state related to the operation of the movable member is not normal, the operation is not set to the non-operational state until the result of counting by the counting means reaches a predetermined number of times (for example, 10 times). It has an accessory production disallowing means (for example, a host control circuit 2100 that executes the process of step S19180) for setting an accessory production disallowing state so that the production using the movable member cannot be performed,
The release means is
When the setting change state is not controlled after the power is turned on, even if an operation is performed to erase the game information stored in the storage means, the inoperable state by the accessory disable means will not be canceled. The apparatus is characterized in that the state in which the performance of an accessory is not permitted by the means for disallowing the performance of an accessory is configured to be cancelable.

According to the gaming machine of (2) above, even if it is determined that the state related to the operation of the movable member is not normal, it cannot operate until the number of times the recovery process has been executed reaches a specified number (for example, 10 times). The accessory performance is not permitted so that the performance using movable members cannot be performed without being in the state. In the case where the setting change state is not controlled after the power is turned on, even if an operation is performed to erase the game information stored in the storage means, the inoperable state will not be canceled, but the role performance disallowed state will be canceled. We are trying to remove this. As a result, while important decisions are made by authorized hall personnel, if the error is not serious enough to make the performance unavailable, such as when the performance is not permitted, the performance information can be erased. Convenience can be ensured by canceling the performance disallowed state.

(1) The gaming machine specified in Supplementary Note 29-3 is
Control related to the progress of the game can be executed based on any one of a plurality of set values, and when a predetermined start condition is met, the display of symbols starts to fluctuate, and when a predetermined end condition is met, the control related to the progress of the game is executed. A game control means (for example, main CPU 101 of main control circuit 100) that can execute one game by stopping the fluctuating display of symbols;
a setting operation means (for example, setting key 328) that is operated when changing at least the one setting value;
Display means (for example, display device 16) on which a predetermined image is displayed;
A production control means (for example, a host control circuit 2100 having a CPU processor) capable of executing control related to the operation of the movable member;
When a power-on operation is performed, a power supply means (for example, a power supply circuit 338) capable of supplying power to the game control means and the performance control means;
Equipped with
The game control means is
When the power is turned on while at least the setting operation means is operated, the setting change state control means (for example, in step S24) controls the setting change state in which the one set value can be changed. It has a main CPU 101) capable of executing processing, and is capable of transmitting various information (for example, information related to the progress of the game, setting change information indicating that a setting value has been changed) to the effect control means. Yes (for example, the main CPU 101 can execute the process of step S55),
The performance control means is
A determining means (for example, a host control circuit 2100 that executes the processing of step S19141 and step S19147) that determines whether the state related to the operation of the movable member is normal at a predetermined timing in the one game;
If it is determined by the determination means that the state related to the operation of the movable member is not normal, a restoration process (for example, the initial position restoration operation transition setting in step S19147 or the motor driver reset process in step S19176) is performed so that the state related to the operation of the movable member is not normal. ); recovery control means (for example, host control circuit 2100) capable of executing
and is capable of receiving various information transmitted from the game control means,
The determining means is
In a plurality of games, it is possible to determine whether or not a state related to the operation of the movable member is normal at a predetermined timing in each game, and
The recovery control means includes:
The restoration process is configured to be able to be executed each time the determining means determines that the game is not normal during the plurality of games;
The performance control means further includes:
a counting unit for counting the number of times the recovery process has been executed by the recovery control unit (for example, a host control circuit 2100 that executes the processes in step S19144 and step S19177);
When the result of counting by the counting means reaches a predetermined number of times (for example, 10 times), accessory operation disabling means (for example, a host control circuit 2100) that executes the processing in step S19146 and step S19179;
Based on the reception of setting change information indicating that the first set value has been changed, a canceling unit for canceling the inoperable state caused by the accessory inoperable unit (for example, executes the process of step S311) a host control circuit 2100);
Based on the fact that the accessory is set in the disabled state by the accessory disable unit, a storage unit capable of storing the time information of the disabled state as history information (for example, the history recording process of step S306 and step S307 a sub-work RAM 2100a) that stores history information when the
Display control means capable of displaying an information screen in which the history information is shown based on a predetermined operation (for example, a host control circuit 2100 that displays the error information history screen of FIG. 116 via the display control circuit 2300); It is characterized by having.

According to the gaming machine of (1) above, even if the determination means determines that the state related to the operation of the movable member is not normal, the state is not rendered inoperable, and the restoration process is performed. Then, when the number of times the recovery process has been executed reaches a predetermined number of times, the movable member is rendered inoperable. Therefore, the occurrence of a minor error will not cause the game to become inoperable; instead, it will become inoperable when recovery cannot be performed even after the recovery process has been executed multiple times, thereby preventing the occurrence of a serious error. It becomes possible to suppress the

Further, since an information screen is displayed that shows time information of the inoperable state as history information, it becomes possible to manage the history of serious errors.

(2) In the gaming machine described in (1) above,
Further comprising a position detection means (for example, a group of accessory detection sensors 1002) capable of detecting that the movable member is present at a specific position (for example, an initial position),
The determining means is
comprising a position determining means (for example, host control circuit 2100) that determines that the movable member is not normal when it is not present at least at the specific position (for example, NO in step S19141);
The recovery control means includes:
Each time the position determining means determines that the movable member does not exist at the specific position (for example, NO is determined in step S19141), a position restoration process (for example, a position recovery control means (for example, host control circuit 2100) that executes the initial position recovery operation transition setting in step S19147;
The release means is
Based on the reception of setting change information indicating that the first setting value has been changed, the number of times the position recovery process has been executed, which is counted by the counting means, is reset (for example, in step S323). process),
The storage means is
It is possible to store at least one of position recovery process history information including time information when the position recovery process was executed, and position recovery process count reset history information in which the number of times the position recovery process was executed was reset. ,
The display control means includes:
Information indicating at least one of the position recovery process history information and the position recovery process count reset history information based on reception of setting change information indicating that the first setting value has been changed. It is characterized by being configured to be able to display a screen.

According to the gaming machine of (2) above, each time it is determined that the movable member does not exist at a specific position, a position restoration process is executed to return the movable member to the specific position, and the first setting value is changed. The number of times the position recovery process has been executed is reset based on the number of times the position recovery process has been executed. Based on the change in the first setting value, the location recovery process history information including the time information when the position recovery process was executed and the time information when the number of times the position recovery process was executed are reset. An information screen is displayed that shows at least one of the included location recovery processing count reset history information. Therefore, even if the error has not reached the level of a serious error such as an inoperable state, by viewing the location recovery processing history information and position recovery processing count reset history information, the possibility of a serious error such as an inoperable state can be grasped in advance. This makes it possible to appropriately manage gaming machines.

(3) In the gaming machine described in (1) or (2) above,
Further comprising a driving means (for example, a motor that operates the accessory group 1000) capable of moving the movable member from a specific position (for example, the initial position) to a prescribed position (for example, the maximum operating range). Prepare,
The determining means is
Operation determining means (for example, when the movable member cannot be moved from the specific position toward at least the prescribed position by the driving means) to determine that the movable member is not normal (for example, when a motor error is detected); It has a host control circuit 2100) that executes the process of step S19171,
The recovery control means includes:
operation recovery control that executes operation recovery processing (for example, motor driver reset processing in step S19176) for resetting a driver of the drive means each time the operation determination means determines that a state related to the operation of the movable member is not normal; means (e.g., host control circuit 2100);
The release means is
Based on the reception of setting change information indicating that the first setting value has been changed, the number of times the operation recovery process has been executed, which is counted by the counting means, is reset (for example, in step S323). process),
The storage means is
It is possible to store at least one of operation recovery process history information including time information when the operation recovery process was executed, and operation recovery process count reset history information in which the number of times the operation recovery process was executed was reset. ,
The display control means includes:
Information indicating at least one of the operation recovery process history information and the operation recovery process count reset history information based on the reception of setting change information indicating that the first setting value has been changed. It is characterized in that it is configured to be able to display a screen (for example, to be able to execute the hall menu display process in step S302).

According to the gaming machine described in (3) above, each time it is determined that the state related to the movable member is not normal, an operation recovery process is executed to reset the driver of the driving means, and the first setting value is changed. Based on this, the number of times the operation recovery process has been executed is reset. Then, based on the change in the first setting value, the operation recovery processing history information including the time information when the operation recovery processing was executed, and the time information when the number of times the position recovery processing was executed were reset. An information screen showing at least one of the included operation recovery processing count reset history information is displayed. Therefore, even if the error has not reached the level of a serious error such as an inoperable state, by viewing the operation recovery processing history information and the operation recovery processing count reset history information, we can grasp the possibility of a serious error such as an inoperable state in advance. This makes it possible to appropriately manage gaming machines.

As described above, according to each of the gaming machines described in Supplementary Notes 29-1 to 29-3, it is possible to provide a gaming machine in which error processing and gaming machine management can be suitably performed.

[12. Other expansion examples, etc.]
Although this embodiment describes an embodiment in which it is applied to a pachinko game machine, all the inventions described in this specification can be applied to a pachinko machine, a game machine, a slot machine, etc. without departing from the spirit of the invention. It can be applied to machines and all other gaming machines.

In addition, each of the above-described embodiments, examples, and modifications, including the above-mentioned supplementary notes, are merely examples. It goes without saying that each configuration shown in each embodiment, each example, and each modification can be partially replaced or combined in other embodiments, other examples, and other modifications. stomach. That is, each component described in each embodiment, each example, and each modification can be arbitrarily combined with each other.

B. Second Embodiment Next, the configuration and various operations of a pachinko gaming machine (gaming machine) according to a second embodiment of the present invention will be described with reference to the drawings. Note that the pachinko gaming machine of this embodiment is a gaming machine of a type (simultaneous variation type) in which a plurality of special symbols (first special symbol and second special symbol) can be varied simultaneously.

<Functional flow>
First, with reference to FIG. 155, the functions of the pachinko gaming machine according to this embodiment will be explained. FIG. 155 is a diagram showing a functional flow of the pachinko gaming machine according to this embodiment.

As shown in FIG. 155, the pachinko game is a game in which a game ball is fired by a user's operation, and when the game ball wins various prizes, a game ball payout control process is performed. Further, pachinko games include special symbol games using special symbols and normal symbol games using normal symbols. When it becomes a "jackpot" in a special symbol game or a "hit" in a normal symbol game, the probability that the game ball will win increases relatively, and the payout control process for the game ball is more likely to be performed. Become.

In addition, various winnings include special symbol start winning, which is one of the conditions for variable display of special symbols in special symbol games, and one condition for variable display of normal symbols in normal symbol games. It also includes a certain normal symbol starting prize.

Note that the term "variable display" as used herein refers to the concept of a variable display, such as a "fluctuating display" that actually changes and is displayed, and a "stop display" that actually stops and is displayed. ”, etc. Further, in the "variable display", for example, a "derivation display" in which a special symbol (identification information) is displayed as a result of a special symbol game can be performed. That is, in this specification, the operation from the start of the "variable display" to the "derived display" is referred to as one "variable display." Furthermore, in this specification, "identification information" refers to "designs" used in pachinko games such as special designs, normal designs, decorative designs, and identification designs, and identification designs and decorations used in pachislot or slot games. It is meant to include symbols used to display or suggest the results of a game when a player plays a game, such as symbols.

Hereinafter, an outline of the processing flow of the special symbol game and the normal symbol game will be explained.

[Special design game]
When a special symbol starts winning in a special symbol game, random values (random value for jackpot determination and random value for symbol determination) are extracted from the jackpot determination counter and the symbol determination counter, and each extracted random value is The numerical value is stored (see the flow of the special symbol start winning process during the special symbol game shown in FIG. 155).

In the special symbol control process during the special symbol game, as shown in FIG. 155, it is first determined whether a condition for starting variable display of the special symbol is satisfied. In this determination process, it is determined whether or not a random number value is stored due to the special symbol starting winning, and with one condition that the random number value is stored, it is determined that the condition for starting variable display of the special symbol is satisfied. It will be judged.

Next, when starting variable display of the special symbols, a jackpot determination is made to determine whether or not it is a "jackpot" by referring to the random value for jackpot determination extracted from the jackpot determination counter. After that, a stop symbol determination process is performed. In this process, a special symbol to be stopped and displayed is determined by referring to the random number value for symbol determination extracted from the symbol determination counter and the result of the jackpot determination described above.

Next, a variation pattern determination process is performed. In this process, a random number value is extracted from the counter for determining the variation pattern, and a variation pattern of the special symbol is determined by referring to the random number value, the result of the above-mentioned jackpot determination, and the above-mentioned special symbol to be stopped and displayed. Ru.

Next, performance pattern determination processing is performed. In this process, a random value is extracted from the performance pattern determination counter, and the random value is referred to, the result of the jackpot determination described above, the special symbol to be stopped and displayed, and the fluctuation pattern of the special symbol described above, A performance pattern to be executed in conjunction with the variable display of special symbols is determined.

Next, a variable display control process that controls the variable display of the special symbol by referring to the determined result of the jackpot determination, the special symbol to be stopped and displayed, the variation pattern of the special symbol, and the performance pattern accompanying the variable display of the special symbol; Then, a performance control process for performing a predetermined performance is executed.

Then, when the variable display control process and the effect display control process are completed, it is determined whether or not there is a "big hit". In this determination process, if it is determined that a "jackpot" has been achieved, a jackpot game control process for performing a jackpot game is executed. In addition, in the jackpot game, the possibility of winning the various prizes mentioned above increases. On the other hand, if it is determined that the "big hit" has not occurred, the jackpot game control process is not executed.

If it is determined that the "big hit" has not been achieved, or if the jackpot game control process has ended, a game state transition control process is performed to shift the game state. In this gaming state transition control process, the normal gaming state, which is different from the jackpot gaming state, is managed. As a normal gaming state, for example, in the above-mentioned jackpot determination, a gaming state in which the probability of being judged as a "jackpot" increases (hereinafter referred to as "probability variable gaming state"), or a special symbol starting winning is easier to obtain. Examples include a gaming state (hereinafter referred to as a "time-saving gaming state"). After that, the process of determining whether or not to start variable display of the special symbols is performed again, and thereafter, various processes of the special symbol control process described above are repeated.

In addition, in the pachinko game machine of this embodiment, when the game ball starts winning while the special symbol is being displayed in a variable manner, various data acquired at the time of starting winning (random value for jackpot determination, random value for determining symbol, etc.) ) will be put on hold. In other words, if a game ball starts winning while a special symbol is being displayed in a variable manner, the variable display (variable display) of the special symbol corresponding to the starting prize is suspended, and after the variable display of the currently executed special symbol ends. Variable display of the reserved special symbols is started. Hereinafter, the variable display of the reserved special symbol will also be referred to as a "reserved ball."

In addition, in the pachinko game machine of this embodiment, as will be described later, two types of special symbol starting winnings are provided (first starting opening winning and second starting opening winning), and a maximum of four winnings are provided for each special symbol starting winning. It is possible to obtain a reserved ball. That is, in this embodiment, a maximum of eight reserved balls can be acquired.

Furthermore, although not shown in FIG. 155, the pachinko gaming machine of this embodiment determines whether the held ball is a hit or miss (whether or not there is a "jackpot" win) based on the above-mentioned information on the held balls, and further, based on the judgment result. It also has a function to perform a predetermined effect based on the information, that is, a pre-read effect function.

In addition, in the pachinko game machine of this embodiment, as explained below, the special symbol variation pattern is divided into a first half variation pattern and a second half variation pattern, and each variation pattern is determined separately. Here, with reference to FIG. 156, a method for determining the first half variation pattern and the second half variation pattern of the special symbol will be explained. FIG. 156 is a diagram showing a fluctuation pattern table that defines a first half fluctuation pattern, a second half fluctuation pattern, and a combination of these fluctuation patterns stored in the main ROM 6102 of the main control circuit 6100, which will be described later.

These tables are referred to in order to determine the variation pattern type and the first half and second half variation patterns based on the winning type, symbol designation command, etc. at the time of winning. Furthermore, the main CPU 6101 transmits a combination of commands corresponding to the first half and second half variation patterns to the sub control circuit 200 as a variation pattern designation command. Note that in the following explanation, a combination of the first half and second half variation patterns is simply referred to as a "variation pattern."

First, the main CPU 6101 determines the type of variation pattern (for example, any of the 9 types of losing variation patterns and the 9 types of winning variation patterns) based on the winning type and symbol designation command at the time of winning, and further takes appropriate action. The first half fluctuation pattern and the second half fluctuation pattern are determined. For example, when the "normal fluctuation" of the outlier fluctuation pattern is determined as the fluctuation pattern, "none" of the command "00H" is determined as the first half fluctuation pattern, and "low probability fluctuation" of the command "00H" is determined as the second half fluctuation pattern. Either "Variation 1 (4.0 seconds)" or "Low Accuracy Fluctuation 2 (8.0 seconds)" of the command "01H" is determined. A variation pattern designation command corresponding to such a "normal variation" is transmitted to the sub-control circuit 6200 as "0000H" or "0001H" which is a combination of commands for the first half and second half variation patterns. Note that the fluctuation pattern designation command may be written as "00H00H" or "00H01H", for example.

The variation time of the variation pattern is the sum of the variation times of the first half and second half variation patterns. For example, with the fluctuation pattern specification command "0000H", the time (4000ms) is the sum of the fluctuation time of the first half fluctuation pattern (0ms) and the fluctuation time (4000ms) of the second half fluctuation pattern, and with the fluctuation pattern designation command "0102H", the first half fluctuation time This is the total time (21,000 ms) of the variation time of the variation pattern (11,000 ms) and the variation time of the latter half variation pattern (10,000 ms). In this way, after the general type of variation pattern is determined, the first half and second half variation patterns are determined in stages, which allows for diversification of the combinations of variation patterns, which in turn allows for variations in performance patterns. It can be easily increased.

For convenience, FIG. 156 shows only 18 types of variation patterns including misses and hits, but of course there may be more than shown in the figure. "Pseudo 1 to 4" and "Special pseudo 1 to 3" are variation patterns corresponding to so-called pseudo series. "Pseudo 1 to 4" are provided as variation patterns for executing pseudo sequences such as normal pseudo sequence and high speed pseudo sequence, for example. For example, "Pseudo 1 to Pseudo 4 wins" is a variation pattern in which, for example, after executing a pseudo series, a jackpot is achieved via normal reach or SP reach. "Low probability", "Chance time", and "Small winning rush" respectively mean "non-probability variable gaming state", "probability variable and time-saving gaming state", and "probability variable and non-time-saving gaming state". In this embodiment, only the winning fluctuation pattern is set as the fluctuation pattern related to "Premier", but it is not limited to this. It may also be a variation pattern that indicates that something is likely to happen (high expectation of winning).

A small hit rush is a game state in which small wins occur more frequently than in a normal game state, and when electric support (support by an electric tulip: a state in which the normal electric accessory 6046 described later is easier to open than normal) is not performed ( This is a gaming state when the normal symbol has a low probability) and the fluctuation time of one special symbol (in this embodiment, the second special symbol, which will be described later) is short. Furthermore, during the chance time (for example, 20 times of time saving), when the time saving ends, a small winning rush may occur. Although not shown, in the variable display of the second special symbol, a 10 minute variation (relatively long variation time) may be performed during the normal game state (low probability of special symbol, low probability of normal symbol). be.

[Normal symbol game]
When there is a normal symbol starting winning in the normal symbol game, a random number is extracted from the hit determination counter and the random number is stored (the flow of normal symbol starting winning processing in the normal symbol game shown in Fig. 155). reference).

In the normal symbol control process during the normal symbol game, as shown in FIG. 155, it is first determined whether a condition for starting variable display of the normal symbol is satisfied. In this determination process, it is determined whether or not a random number value is stored due to the normal symbol starting winning, and if the random number value is stored as one of the conditions, the condition for starting the variable display of the normal symbol is established. It will be judged.

Next, when starting the variable display of the normal symbols, a hit determination is made as to whether or not it is a "win" by referring to the random value extracted from the hit determination counter. After that, a variation pattern determination process is performed. In this process, the fluctuation pattern of the normal symbols is determined with reference to the result of the hit determination.

Next, with reference to the determined result of the hit determination and the fluctuation pattern of the normal symbols, a variable display control process for controlling the variable display of the normal symbols and an effect control process for performing a predetermined effect are executed.

When the variable display control process and the effect display control process are completed, it is determined whether or not there is a "win". In this determination process, if it is determined that it is a "win", a winning game control process for performing a winning game is executed. In the winning game control process, the possibility of winning the various prizes mentioned above increases, especially the possibility of winning a special symbol starting prize of the game ball in the special symbol game. On the other hand, if it is determined that it is not a "win", the winning game control process is not executed. After that, the process of determining whether or not to start variable display of the normal symbols is performed again, and thereafter, the various processes of the normal symbol control process described above are repeated.

As mentioned above, in a pachinko game, the payout of game balls is controlled based on conditions such as whether or not there will be a "jackpot" in the special symbol game, the transition status of the gaming state, and whether or not there will be a "win" in the normal symbol game. Ease of processing changes.

In this embodiment, as a method for extracting various random numbers, a soft random number method is used in which random numbers are generated by executing a program. However, the present invention is not limited to this, and for example, if a pachinko game machine is equipped with a random number generator whose random numbers are updated at a predetermined period, a random number is obtained from a counter (so-called ring counter) in the random number generator. A hard random number method for extracting may be adopted as the method for extracting the various random numbers described above. Note that when using the hard random number method, by determining the initial value of the random number value at a timing different from the predetermined cycle, it is possible to prevent the same random number value from being extracted at the predetermined cycle.

<Structure of pachinko machine>
Next, the structure of the pachinko gaming machine in this embodiment will be explained with reference to FIGS. 157 to 159. Note that FIG. 157 is a perspective view showing the external appearance of the pachinko gaming machine seen from the front side. FIG. 158 is an exploded perspective view of the pachinko game machine. Moreover, FIG. 159 is a perspective view showing the appearance of the pachinko game machine seen from the back side.

As shown in FIGS. 157 to 159, the pachinko gaming machine 6001 includes a main body 6002, a base door 6003 attached to the main body 6002 so as to be openable and closable, and a glass door attached to the base door 6003 so as to be openable and closable. 6004.

[Body]
The main body 6002 is composed of a frame member having a rectangular opening 6002a (see FIG. 158). This main body 6002 is made of a material such as wood, for example.

[Base door]
The base door 6003 is composed of a plate-like member having a rectangular outer shape that is approximately the same as the outer shape of the main body 6002. The base door 6003 is arranged in front of the main body 6002 (the front side of the pachinko gaming machine 6001), and by rotating the base door 6003 around one side end of the main body 6002, the main body 6002 can be opened. Opening 6002a is opened and closed. As shown in FIG. 158, the base door 6003 is provided with a rectangular opening 6003a. This opening 6003a is formed from approximately the center of the base door 6003 to an upper region thereof, and has a size that occupies most of the region.

Further, a speaker 6011, a game board 6012, a display device 6013, a dish unit 6014, a firing device 6015, a payout device 6016, and a board unit 6017 are attached to the base door 6003.

The speaker 6011 is arranged at the top (near the top end) of the base door 6003. The game board 6012 is placed in front of the base door 6003 (on the front side of the pachinko game machine 6001), and is placed so as to cover the opening 6003a of the base door 6003.

The game board 6012 is made of a plate-shaped resin member that is transparent to light. Note that, as the resin having light transmittance, for example, acrylic resin, polycarbonate resin, methacrylic resin, etc. can be used.

Further, on the front surface of the game board 6012 (the front surface of the pachinko game machine 6001), a game area 6012a is formed in which game balls fired from a firing device 6015 roll. This game area 6012a is an area surrounded by a guide rail 6041 (specifically, an outer rail 6041a shown in FIG. 160, which will be described later), and its outer circumference is approximately circular. Furthermore, a plurality of game nails (see FIG. 160 described later) are driven into the game area 6012a. Note that the configuration of the game board 6012 (game area 6012a) will be described in detail later with reference to FIG. 160, which will be described later. Although not shown, the game board 6012 is provided with various sensors such as a magnetic sensor and a vibration sensor for abnormality detection.

The display device 6013 is attached to the back side of the game board 6012 (the side opposite to the front side of the pachinko game machine 6001). This display device 6013 has a display area 6013a that displays images. The size of the display area 6013a is set to a size that occupies all or part of the surface of the game board 6012. In the display area 6013a of the display device 6013, various images such as identification symbols for presentation, presentation images, and decorative images (decorative patterns) are displayed. The player can view various images displayed in the display area 6013a of the display device 6013 via the game board 6012.

Note that in this embodiment, a liquid crystal display device is used as the display device 6013. However, the present invention is not limited thereto, and display devices such as a plasma display, a rear projection display, and a CRT (Cathode Ray Tube) display may be applied as the display device 6013, for example.

Further, a spacer 6019 is provided on the back side of the game board 6012 (the side opposite to the front side of the pachinko game machine 6001). This spacer 6019 is provided between the back surface of the game board 6012 (the surface on the back side of the pachinko game machine 6001) and the front surface of the display device 6013 (the surface on the front side of the pachinko game machine 6001). A space is formed that becomes a flow path for game balls rolling in the region 6012a. The spacer 6019 is made of a material that transmits light. Note that the present invention is not limited to this, and the spacer 6019 may be partially formed of a material that has optical transparency, or may be formed of a material that does not have optical transparency, for example. .

The plate unit 6014 is arranged below the game board 6012. This plate unit 6014 includes an upper plate 6021 and a lower plate 6022 arranged below the upper plate 6021. As shown in FIG. 157, the upper tray 6021 and the lower tray 6022 are provided with a payout port 6021a and a payout port 6022a, respectively, for lending game balls and paying out game balls (prize balls). When predetermined payout conditions are met, game balls are ejected from the payout port 6021a and the payout port 6022a and stored in the upper tray 6021 and lower tray 6022, respectively. Further, the game balls stored in the upper tray 6021 are fired into the game area 6012a by the firing device 6015.

Further, the dish unit 6014 is provided with a production button 6023. This effect button 6023 is attached on the upper plate 6021. Further, a dial operation section (jog dial) 6024 is attached to the periphery of the production button 6023 so as to be rotatable with respect to the production button 6023. The pachinko game machine 6001 of this embodiment has a predetermined performance function that is performed using a performance button 6023 and/or a dial operation section 6024, and when performing a predetermined performance, a display area 6013a of the display device 6013 displays An image prompting the user to operate the production button 6023 and/or the dial operation section 6024 is displayed.

The firing device 6015 is arranged in the lower right area (near the lower right corner) on the front surface of the base door 6003. This firing device 6015 includes a firing handle 6025 that can be operated by the player, and a panel body 6026 that engages with the lower right portion of the dish unit 6014. The firing handle 6025 is arranged on the front side of the panel body 6026 and is rotatably supported by the panel body 6026.

Although not shown in FIGS. 157 to 159, a solenoid actuator (drive device) that controls the firing operation of the game ball (game medium) is provided on the back side of the panel body 6026. Although not shown in FIGS. 157 to 159, a touch sensor is provided on the periphery of the firing handle 6025, and a firing volume is provided inside the firing handle 6025. The firing volume changes the resistance value according to the amount of rotation of the firing handle 6025, and changes the power supplied to the solenoid actuator.

In the pachinko game machine 6001 of this embodiment, when the player's hand comes into contact with the touch sensor of the firing handle 6025, the touch sensor outputs a detection signal. As a result, it is detected that the player has grasped the firing handle 6025, and the solenoid actuator can fire the game ball. When the player grasps the firing handle 6025 and rotates it clockwise (clockwise when viewed from the player's side), the resistance value of the firing volume changes according to the rotation angle of the firing handle 6025. , power corresponding to the resistance value is supplied to the solenoid actuator. As a result, the game balls stored in the upper tray 6021 are sequentially fired, and the fired game balls are guided by a guide rail 6041 (see FIG. 160 described later) and released into the game area 6012a of the game board 6012.

Although not shown in FIGS. 157 to 159, a firing stop button is provided on the side of the firing handle 6025. The firing stop button is a button provided to stop the solenoid actuator from firing the game ball. When the player presses the firing stop button, firing of the game ball is stopped even if the firing handle 6025 is held and rotated.

The dispensing device 6016 is arranged on the back side of the base door 6003. Game balls are supplied to the payout device 6016 from a storage unit (not shown). The payout device 6016 pays out a predetermined number of game balls from among the game balls supplied from the storage unit to the upper tray 6021 or the lower tray 6022 based on the establishment of the payout condition. Further, on the back side of the dispensing device 6016, as shown in FIG. 159, a power switch 6035 is provided.

The board unit 6017 is arranged on the back side of the base door 6003. The board unit 6017 is provided with various control boards, various units, various switches, and the like. Specifically, as shown in FIG. 159, a main control board 6030 on which a main control circuit 6100 (see FIG. 161 described later) is mounted, and a sub-control circuit 6200 (see FIGS. 161 and 162 described later) are mounted. A sub-control board 6040, a payout/launch control board 6050 on which a payout/launch control circuit 6300 (see FIG. 161 described below) that controls the payout/launch of game balls is mounted, and a power supply circuit 6033 that supplies power (described later). The board unit 6017 is provided with a power supply unit 6060 and the like (see FIG. 161).

Note that in this embodiment, the sub-control board 6040 is configured as a one-board board (a board in which one control LSI or a plurality of LSIs is provided on one board); however, the present invention is not limited to this; The board 6040 may be composed of a plurality of boards (for example, a host control circuit 6210, an audio/LED control circuit 6220, a display control circuit 6230, etc., which will be described later, are each composed of separate boards).

In addition, the pachinko game machine 6001 of this embodiment has a plurality of setting values (in this embodiment, six levels from "1" to "6") that differ in various data (for example, jackpot probability, etc.) related to the degree of advantage of the pachinko game. It is provided. Setting "6" is the most advantageous for the player (for example, the jackpot probability is the highest), and as the setting value becomes smaller, the advantage for the player gradually decreases.

Although not shown in FIG. 159, inside the main board case that houses the main control board 6030 are setting keys 6080 that are operated by the player to change or confirm the setting values, and A setting switch 6081, a performance display monitor 6070, and an error notification monitor 6071 (all shown in FIG. 161, which will be described later) are housed therein. The performance display monitor 6070 displays, for example, performance display data and setting values, which will be described later. For example, an error code is displayed on the error notification monitor 6071.

The reason why the setting key 6080 and the setting switch 6081 are housed in the main board case is that the person in charge of managing the pachinko game machine 6001 (hereinafter referred to as "the person in charge of managing the game machine") takes security into consideration. This is to prevent a third party other than the player (for example, a player) from easily accessing the setting key 6080 and/or the setting switch 6081. However, in this specification, "inside the main board case" includes not only those configured such that the setting key 6080 and/or setting switch 6081 cannot be accessed without opening the main board case, but also the setting key of the main board case. A notch is provided only at the corresponding installation location of the setting switch 6080 and the setting switch 6081, and the pachinko gaming machine 6001 can be rotated from the island equipment where the pachinko gaming machine 6001 is installed using a key managed by the gaming machine management manager. It also includes a machine configured so that a game machine manager can access the setting key 6080 and/or the setting switch 6081 when the back side is exposed.

[Glass door]
The glass door 6004 is composed of a plate-like member with a substantially rectangular surface. Furthermore, the glass door 6004 is arranged on the front side of the game board 6012 and has a size that covers the game board 6012. On the front surface of this glass door 6004, a speaker cover 6029 is provided in an upper region facing the speaker 6011.

Further, in the central portion of the glass door 6004, an opening 6004a having a size that exposes at least the game area 6012a is formed in an area facing the game area 6012a of the game board 6012. A light-transmitting protective glass 6028 is attached to the opening 6004a of the glass door 6004, thereby closing the opening 6004a. Therefore, when the glass door 6004 is closed with respect to the base door 6003, the protective glass 6028 is arranged to face at least the gaming area 6012a of the gaming board 6012.

[Game board]
Next, the configuration of the game board 6012 will be explained with reference to FIG. 160. FIG. 160 is a front view showing the configuration of the game board 6012.

As shown in FIG. 160, the front surface of the game board 6012 includes a guide rail 6041, a ball passage detector 6043, a first starting port 6044 (starting area), a second starting port 6045 (starting area), and a normal An electric accessory 6046 is provided. In addition, on the front side of the game board 6012, there are general winning holes 6051, 6052, a first big winning hole 6053 (variable winning device), a second big winning hole 6054 (variable winning device), and an out hole 6055. A game nail 6056 is provided. Further, on the front surface of the game board 6012, a first special symbol display device 6061, a second special symbol display device 6062, and a normal symbol display device are provided at the top of the display area 6013a of the display device 6013 located approximately in the center. 6063, a first special symbol retention display device 6064, a second special symbol retention display device 6065, and a normal symbol retention display device 6066 are provided.

Although not shown in FIG. 160, a 7-segment counter for performance is also provided on the front surface of the game board 6012. The 7-segment counter for presentation is composed of a display counter that can display two digit numbers or two alphabetical characters. In addition, in this embodiment, a notification LED (Light Emitting Diode) that lights up when the result of the stop display of the special symbol is a "jackpot", a round number display LED that displays the number of rounds during a jackpot game, etc. are provided. Good too.

[Various components of the gaming area]
The guide rail 6041 is composed of an outer rail 6041a that extends in an arc shape that partitions the gaming area 6012a, and an inner rail 6041b that extends in an arc shape and is arranged inside (inner circumferential side) of this outer rail 6041a. be done. The game area 6012a is formed inside the outer rail 6041a. The outer rail 6041a and the inner rail 6041b are arranged so as to face each other near the left end of the gaming area 6012a when viewed from the player side, so that the launching device is placed between the outer rail 6041a and the inner rail 6041b. A guide path 6041c is formed that guides the game ball shot by 6015 to the upper part of the game area 6012a.

In addition, a ball discharge opening 6041d is formed at the tip of the inner rail 6041b located at the upper left side of the gaming area 6012a by the tip of the inner rail 6041b and a part of the outer rail 6041a facing thereto. A ball return prevention piece 6042 is provided at the tip of the inner rail 6041b so as to close the ball release port 6041d. This ball return prevention piece 6042 prevents the game ball released from the ball release port 6041d into the game area 6012a from passing through the ball release port 6041d again and entering the guide path 6041c.

The game balls released from the ball release port 6041d flow down from the top to the bottom of the game area 6012a. At this time, the game ball collides with various members provided in the game area 6012a, such as the plurality of game nails 6056, the first starting port 6044, the second starting port 6045, etc., and changes the direction of movement of the game ball. Flows down from the top to the bottom.

A display area 6013a of a display device 6013 is provided approximately in the center of the gaming area 6012a. An obstacle 6013b is provided at the upper end of this display area 6013a. By providing the obstacle 6013b, the game ball does not pass over the area that overlaps with the display area 6013a in the game area 6012a.

The ball passage detector 6043 is arranged near the right end of the display area 6013a when viewed from the player side. The ball passing detector 6043 is provided with a passing ball switch 6043a (see FIG. 161 described later) for detecting a game ball passing through the ball passing detector 6043. Furthermore, when the game ball passes through the ball passage detector 6043, a lottery is performed to determine whether or not it is a "win", and a variable display of normal symbols is started based on the result of the lottery.

The first starting port 6044 is arranged below the display area 6013a, and the second starting port 6045 is arranged below the first starting port 6044. The first starting port 6044 and the second starting port 6045 are made of a member capable of receiving game balls. Hereinafter, entering or passing the game ball into the first starting port 6044 or the second starting port 6045 will be referred to as "winning." Then, when a game ball enters the first starting hole 6044 or the second starting hole 6045, a first predetermined number (three in this embodiment) of game balls are paid out. Further, when a game ball enters the first starting hole 6044, a lottery is performed to determine whether or not it is a "jackpot", and a variable display of special symbols is started based on the result of the lottery. Furthermore, when a game ball enters the second starting port 6045, a lottery is held to determine whether it is a "big hit" or a "small hit", and the special symbols change based on the result of the lottery. Display starts.

The first starting opening 6044 is provided with a first starting opening prize ball switch 6044a (see FIG. 161 described later) for detecting the game ball that has won in the first starting opening 6044. Further, the second starting opening 6045 is provided with a second starting opening winning ball switch 6045a (see FIG. 161 described later) for detecting the game ball that has won the second starting opening 6045. Note that the game balls won in the first starting port 6044 and the second starting port 6045 pass through a collection port (not shown) provided on the game board 6012 and are transported to a game ball collection section (not shown). .

A normal electric accessory 6046 is provided at the second starting port 6045. The normal electric accessory 6046 includes a pair of blade members rotatably attached to both sides of the second starting port 6045, and a normal electric accessory solenoid 6046a (starting port solenoid, described later in FIG. 161) that drives the pair of blade members. ). This normal electric accessory 6046 is driven by a normal electric accessory solenoid 6046a, and has an open state in which the pair of blade members is expanded to make it easier to enter the game ball into the second starting port 6045, and an open state in which the pair of blade members is closed. One of the closed states that makes it impossible to win a game ball is generated in the second starting port 6045. In the time-saving game state, the normal electric accessory 6046 is likely to be in the open state. In addition, when the normal electric accessory 6046 is in the closed state, the opening form of the pair of blade members is not a form that makes it impossible to win a prize as in this embodiment, but a form that makes it difficult for the game ball to win a prize. You can also do this.

The general winning hole 6051 is arranged near the lower left of the gaming area 6012a when viewed from the player side. In addition, the general winning hole 6052 is arranged below the ball passage detector 6043, and near the lower right of the gaming area 6012a when viewed from the player side. The general winning hole 6051 and the general winning hole 6052 are made of a member capable of receiving game balls. Hereinafter, entering or passing the game ball into the general winning hole 6051 or the general winning hole 6052 will also be referred to as "winning." When a game ball enters the general winning hole 6051 or the general winning hole 6052, a second predetermined number (10 in this embodiment) of game balls are paid out.

The general winning hole 6051 is provided with a general winning ball switch 6051a (see FIG. 161 described later) for detecting a game ball that has won a prize in the general winning hole 6051. Further, the general winning hole 6052 is provided with a general winning ball switch 6052a (see FIG. 161 described later) for detecting the game ball that has won in the general winning hole 6052.

The first big winning hole 6053 and the second big winning hole 6054 (special electric accessory) are arranged below the ball passage detector 6043 and between the first starting hole 6044 and the general winning hole 6052. The first big winning hole 6053 and the second big winning hole 6054 are arranged in the vertical direction along the flow path of the game ball, and the first big winning hole 6053 is arranged above the second big winning hole 6054. Ru. Both the first big winning hole 6053 and the second big winning hole 6054 are so-called attacker-type opening/closing devices, and include shutters 6053a and 6054a that can be opened and closed, and a solenoid actuator (the first in FIG. 161 described later) that drives the shutters. It has a big winning opening solenoid 6053b and a second big winning opening solenoid 6054b).

Each of the first big winning hole 6053 and the second big winning hole 6054 receives a game ball when the corresponding shutter is open (open state), and receives a game ball when the shutter is closed (closed state). Do not accept the ball. Hereinafter, entering or passing the game ball into the first grand prize opening 6053 or the second grand prize opening 6054 will also be referred to as "winning." When a game ball enters the first big prize opening 6053, a third predetermined number of game balls (10 in this embodiment) are paid out. On the other hand, when a game ball enters the second big prize opening 6054, a fourth predetermined number of game balls (15 in this embodiment) are paid out.

Further, the first big winning hole 6053 is provided with a count switch 6053c (see FIG. 161 described later) for counting the game balls that have won in the first big winning hole 6053. Further, the second big winning hole 6054 is provided with a count switch 6054c (see FIG. 161 described later) for counting the game balls that have won in the second big winning hole 6054.

The out port 6055 is provided at the bottom of the gaming area 6012a. This out opening 6055 is for games that did not win in any of the first starting opening 6044, second starting opening 6045, general winning opening 6051, general winning opening 6052, first grand winning opening 6053, and second grand winning opening 6054. Accept the ball.

When the various constituent members in the gaming area 6012a of this embodiment are arranged as shown in FIG. 160, when a game ball is hit into the right area of the gaming area 6012a by a player (when the game ball is hit to the right), The game ball is guided to the second starting port 6045 by the game nail 6056 or the like. In this case, there is almost no possibility of winning in the first starting slot 6044. In addition, in the pachinko gaming machine 6001 of this embodiment, the player who wins the prize in the second starting opening 6045 has a gaming property in which it is easier to receive a "jackpot" lottery which is more advantageous for the player than when winning the first starting opening 6044. It has become. Therefore, in the time-saving gaming state in which it is relatively easy to win a prize in the second starting opening 6045, by hitting right, the possibility of winning in the first starting opening 6044 (which becomes a disadvantageous gaming state for the player) possibility) can be lowered.

[Special symbol display device]
The first special symbol display device 6061 and the second special symbol display device 6062 are arranged approximately in the upper center of the display area 6013a of the display device 6013, as shown in FIG.

The first special symbol display device 6061 and the second special symbol display device 6062 each variably display (variable display and stop display) the corresponding special symbol (first special symbol or second special symbol described later) in the special symbol game. It is a display device that In this embodiment, as shown in FIG. 160, each special symbol display device is constituted by a device that displays the special symbol as a symbol consisting of numbers, symbols, etc. Note that the present invention is not limited to this, and the special symbol display device may be configured with a plurality of LEDs, for example. In this case, a display pattern formed by turning on and off a plurality of LEDs is represented as a special symbol.

The first special symbol display device 6061 displays a special symbol (identification information) in a variable manner when the game ball enters the first starting hole 6044 (special symbol starting prize). Then, the first special symbol display device 6061 displays the special symbols in a variable manner for a predetermined period of time, and then displays the special symbols in a stopped state. In addition, below, when the game ball enters the first starting hole 6044, the special symbol that is variably displayed on the first special symbol display device 6061 will be referred to as a "first special symbol."

Then, in the first special symbol display device 6061, when the first special symbol that is stopped and displayed is in a specific mode (a "jackpot" mode), the gaming state changes from the normal gaming state to a state advantageous to the player. The game shifts to a jackpot gaming state. That is, in the first special symbol display device 6061, it is a "jackpot" that the first special symbol is stopped and displayed in a manner that transitions to a jackpot gaming state (jackpot symbol).

The second special symbol display device 6062 displays the special symbol (identification information) in a variable manner when the game ball enters the second starting hole 6045 (special symbol starting prize). Then, the second special symbol display device 6062 displays the special symbols in a variable manner for a predetermined period of time, and then displays the special symbols in a stopped state. In addition, below, when the game ball enters the second starting hole 6045, the special symbol that is variably displayed on the second special symbol display device 6062 will be referred to as a "second special symbol."

Then, in the second special symbol display device 6062, if the second special symbol that is stopped and displayed is in a specific mode (a "jackpot" mode), the gaming state changes from the normal gaming state to a state advantageous to the player. The game shifts to a jackpot gaming state. That is, in the second special symbol display device 6062, it is a "jackpot" that the second special symbol is stopped and displayed in a manner that transitions to the jackpot gaming state (jackpot symbol). In addition, in the second special symbol display device 6062, if the second special symbol that is stopped and displayed is in a prescribed mode (“small win” mode), the gaming state changes from the normal gaming state to a large prize for the player. The game shifts to a small hit game state in which balls cannot be expected. That is, in the second special symbol display device 6062, it is a "small win" that the second special symbol is stopped and displayed in a mode (small win symbol) that transitions to a small win game state.

The pachinko gaming machine 6001 of this embodiment is a gaming machine of a type (simultaneous variation type) in which the first special symbol and the second special symbol can be varied simultaneously. Therefore, in the pachinko gaming machine 6001 of this embodiment, while the first special symbol display device 6061 and the second special symbol display device 6062 are displaying a special symbol in a variable manner, the other special symbol is being displayed. The device can start variable display of special symbols based on the special symbol starting winning.

In the jackpot game state, the first jackpot 6053 or the second jackpot 6054 is in an open state. Specifically, in this embodiment, when the game ball enters the first starting hole 6044 and the first special symbol is stopped and displayed in a specific manner on the first special symbol display device 6061 (at the time of jackpot), , the first big prize opening 6053 becomes open. On the other hand, when the game ball enters the second starting hole 6045 and the second special symbol is stopped and displayed in a specific manner or prescribed manner on the second special symbol display device 6062 (at the time of a jackpot or a small hit), , the second big prize opening 6054 becomes open.

The open state of each grand prize opening is maintained until a predetermined number of game balls are won or until a certain period of time (for example, 30 seconds) has elapsed. Then, when the elapsed period of the open state of each big winning hole satisfies any of these conditions, the big winning hole that was in the open state becomes a closed state.

Hereinafter, a game in which the first big winning hole 6053 or the second big winning hole 6054 is in a state (open state) where it is easy to accept game balls will be referred to as a "round game." The grand prize opening will be closed between round games. Further, a round game is counted as the number of rounds such as 1 round, 2 rounds, etc. For example, the first round game is called the first round, and the second round game is called the second round.

In addition, in the first special symbol display device 6061, if the first special symbol that is stopped and displayed is in a mode other than the specific mode (“losing” mode), or in the second special symbol display device 6062, the stop display is If the second special symbol drawn is in a mode other than the specified and prescribed mode (a "lose" mode), the player wins the falling lottery (which is not performed in the pachinko gaming machine 6001 of this embodiment). The game state does not change except for. That is, the special symbol game is a game in which a special symbol is displayed in a variable manner by a special symbol display device, and then the special symbol is stopped and displayed, and the gaming state is shifted or maintained depending on the result.

In addition, in the pachinko gaming machine 6001 of this embodiment, if a game ball enters the first starting hole 6044 during the variable display of the first special symbol, the variable display of the first special symbol corresponding to the winning (holding ball) will be put on hold. Then, when the first special symbol currently being displayed in a variable manner is stopped and displayed, the variable display of the first special symbol that has been on hold is started. In this embodiment, the number of variable displays of the first special symbol to be reserved (so-called "number of reserved symbols (number of reserved balls)") is defined as a maximum of four times (pieces).

Furthermore, in this embodiment, when a game ball enters the second starting hole 6045 during the variable display of the second special symbol, the variable display (holding ball) of the second special symbol corresponding to the winning is suspended. Then, when the second special symbol currently being displayed in a variable manner is stopped and displayed, the variable display of the second special symbol that has been on hold is started. In this embodiment, the number of variable displays of the second special symbols to be suspended (the number of suspended symbols) is defined as a maximum of four times (pieces). Therefore, in this embodiment, the maximum number of reserved special symbols for variable display is 8 in total.

In addition, since the pachinko gaming machine 6001 of this embodiment is a simultaneous fluctuation type gaming machine, when the reserved balls of the first special symbol and the reserved balls of the second special symbol are mixed, the pachinko game machine 6001 of the present embodiment is based on the reserved balls of one of the special symbols. During the variable display of one special symbol, the variable display of the other special symbol based on the reserved ball of the other special symbol may be started.

[Normal symbol display device]
The normal symbol display device 6063 is arranged approximately at the upper center of the display area 6013a of the display device 6013, as shown in FIG. 160. In this embodiment, the normal symbol display device 6063 is arranged on the right side of the special symbol display device (first special symbol display device 6061 and second special symbol display device 6062) when viewed from the player side.

The normal symbol display device 6063 is a display device that variably displays normal symbols (variable display and static display) in the normal symbol game. In this embodiment, as shown in FIG. 160, the normal symbol display device 6063 is composed of two LEDs (normal symbol display LEDs) arranged in the vertical direction. In the normal symbol display device 6063, a display pattern constituted by lighting and extinguishing of each normal symbol display LED is expressed as a normal symbol.

The normal symbol display device 6063 alternately lights and extinguishes the two normal symbol display LEDs in response to the game ball passing through the ball passage detector 6043, and performs a variable display of the normal symbol. Then, the normal symbol display device 6063 displays the normal symbols in a variable manner for a predetermined period of time, and then displays the normal symbols in a stopped state.

In the normal symbol display device 6063, when the stopped and displayed normal symbol is in a predetermined mode (“win” mode), the normal electric accessory 6046 changes from the closed state to the open state for a predetermined period. On the other hand, when the stopped and displayed normal symbol is in a mode other than the predetermined mode (a "loss" mode), the normal electric accessory 6046 maintains the closed state. That is, the normal symbol game is a game in which normal symbols are displayed in a variable manner by the normal symbol display device 6063, then the normal symbols are stopped and displayed, and the normal electric accessory 6046 operates according to the result.

In addition, when the game ball passes the ball passage detector 6043 during the variable display of the normal symbols, the variable display of the normal symbols is suspended. Then, when the normal symbol currently being displayed in a variable manner is stopped and displayed, the variable display of the suspended normal symbol is started. In this embodiment, the number of variable displays of normal symbols to be held (ie, the "number of pending items") is defined as a maximum of four times (pieces).

[First special symbol holding display device]
As shown in FIG. 160, the first special symbol holding display device 6064 is arranged on the left side of the first special symbol display device 6061 in the upper part of the display area 6013a of the display device 6013 when viewed from the player side.

The first special symbol reservation display device 6064 is a device that displays information regarding the variable display of the reserved first special symbol (the reserved ball of the first special symbol). In this embodiment, as shown in FIG. 160, the first special symbol reservation display device 6064 includes a first special symbol reservation number display section 6064a and a first special symbol reservation information display section 6064b. The first special symbol reservation information display section 6064b is arranged on the left side of the first special symbol display device 6061, and the first special symbol reservation number display section 6064a is arranged on the left side of the first special symbol reservation information display section 6064b. be done.

The first special symbol reservation number display section 6064a has four LEDs (first special symbol reservation display LEDs) arranged in the left-right direction. And, in the first special symbol reservation display device 6064, the number of reservations of the variable display of the first special symbol is displayed by lighting/extinguishing each first special symbol reservation display LED.

Specifically, when the number of pending symbols in the variable display of the first special symbol is one, the first special symbol pending display LED located on the leftmost side when viewed from the player side (the first special symbol pending display LED from the left) The special symbol pending display LED) lights up, and the other first special symbol pending display LEDs turn off. If the number of pending items in the variable display of the first special symbol is 2, the first and second 1st special symbol pending display LEDs from the left will light up, and the other 1st special symbol pending display LEDs will turn off. do. If the number of pending items in the variable display of the first special symbol is 3, the 1st to 3rd special symbol pending display LEDs from the left will light up, and the other 1st special symbol pending display LEDs will turn off. . Then, when the number of pending variable displays of the first special symbols is four, all the first special symbol pending display LEDs are lit.

The first special symbol reservation information display section 6064b displays information regarding the reservation ball of the first special symbol. For example, the first special symbol reservation information display section 6064b displays information (identification information) regarding the reserved ball of the first special symbol to be displayed in a variable manner next with a symbol consisting of numbers, symbols, etc. Note that the configuration of the first special symbol reservation display device 6064 is not limited to the example shown in FIG. 160, and can be arbitrarily configured as long as it can display the number of reservations in the variable display of at least the first special symbol. .

[Second special symbol holding display device]
As shown in FIG. 160, the second special symbol reservation display device 6065 is arranged on the right side of the normal symbol display device 6063 at the upper part of the display area 6013a of the display device 6013 when viewed from the player side.

The second special symbol reservation display device 6065 is a device that displays information regarding the variable display of the reserved second special symbol (the reserved ball of the second special symbol). In this embodiment, as shown in FIG. 160, the second special symbol reservation display device 6065 includes a second special symbol reservation number display section 6065a and a second special symbol reservation information display section 6065b. The second special symbol reservation information display section 6065b is arranged on the right side of the normal symbol display device 6063, and the second special symbol reservation number display section 6065a is arranged on the right side of the second special symbol reservation information display section 6065b. .

The second special symbol reservation number display section 6065a has four LEDs (second special symbol reservation display LEDs) arranged in the left-right direction. The display mode of the second special symbol reservation number display section 6065a is the same as the display mode of the first special symbol reservation number display section 6064a. That is, when the variable display of the second special symbol is suspended, the second special symbol suspension display LED from the second special symbol suspension display LED located on the leftmost side to the number of pending symbols when viewed from the player side lights up.

The second special symbol reservation information display section 6065b displays information regarding the reservation ball of the second special symbol. For example, the second special symbol reservation information display section 6065b displays information (identification information) regarding the reserved ball of the second special symbol to be displayed in a variable manner next with a symbol consisting of numbers, symbols, etc. Note that the configuration of the second special symbol reservation display device 6065 is not limited to the example shown in FIG. 160, and can be arbitrarily configured as long as it can display at least the number of reservations in the variable display of the second special symbol. .

[Normal symbol retention display device]
The normal symbol holding display device 6066 is arranged approximately in the upper center of the display area 6013a of the display device 6013, as shown in FIG. 160. In this embodiment, the normal symbol holding display device 6066 is arranged below the first special symbol display device 6061, the second special symbol display device 6062, and the normal symbol display device 6063.

The normal symbol reservation display device 6066 is a device that displays the number of reserved symbols in a variable display of normal symbols. In this embodiment, as shown in FIG. 160, the normal symbol retention display device 6066 is configured with four LEDs (normal symbol retention display LEDs) arranged in the left and right direction. Then, the normal symbol reservation display device 6066 displays the number of pending symbols in the variable display of normal symbols by lighting and extinguishing each of the normal symbol reservation display LEDs.

The display mode of the normal symbol reservation display device 6066 is the same as the display mode of the first special symbol reservation number display section 6064a. That is, when the variable display of normal symbols is suspended, the normal symbol suspension display LEDs from the leftmost normal symbol suspension display LED to the number of pending symbols are lit when viewed from the player side.

[Display device]
The display device 6013 is composed of a liquid crystal display device as described above, and performs various image display effects in its display area 6013a. Specifically, performance images related to the first special symbol displayed on the first special symbol display device 6061 and the second special symbol displayed on the second special symbol display device 6062 are displayed in the display area 6013a.

For example, when the first special symbol is being displayed in a variable manner on the first special symbol display device 6061, except in specific cases, for example, a plurality of presentation identification symbols consisting of numbers 1 to 8 and various characters ( Decorative patterns) are displayed in a changing manner in the display area 6013a. Next, when the first special symbol is stopped and displayed on the first special symbol display device 6061, a plurality of decorative symbols (such as jackpot symbols) corresponding to the first special symbol are also stopped and displayed in the display area 6013a.

When the first special symbol stopped and displayed on the first special symbol display device 6061 is in a specific manner (the result of the stop display is a "jackpot"), the player is informed that it is a "jackpot". An effect image for understanding is displayed in the display area 6013a. For example, as an effect to make the player understand that it is a "jackpot", first, a plurality of decorative symbols that are stopped and displayed are arranged in a specific manner (for example, a manner in which the same decorative symbols are lined up along a predetermined direction). ), and then an image announcing a "big win" is displayed.

For example, when the second special symbol is being displayed in a variable manner on the second special symbol display device 6062, a plurality of performance identification symbols (decorative symbols) are displayed in a variable manner in the display area 6013a, except in specific cases. . Next, when the second special symbol is stopped and displayed on the second special symbol display device 6062, a plurality of decorative symbols (such as jackpot symbols) corresponding to the second special symbol are also stopped and displayed in the display area 6013a. When the second special symbol stopped and displayed on the second special symbol display device 6062 is in a specific manner (the result of the stop display is a "jackpot"), the player is informed that it is a "jackpot". An effect image for understanding is displayed in the display area 6013a.

Also, for example, when both the first special symbol and the second special symbol are being displayed in a variable manner, the variable display of a plurality of decorative symbols corresponding to the variable display of the first special symbol and the variable display of the second special symbol are supported. Both of the variable display of a plurality of decorative symbols are performed in the display area 6013a.

Moreover, in this embodiment, the display area 6013a of the display device 6013 displays an effect image related to the display contents of the first special symbol retention display device 6064 and the second special symbol retention display device 6065. For example, in the display area 6013a, reservation information (for example, the same number of reservation symbols as the number of reservations) that informs the number of reservations in the variable display of special symbols is displayed. Further, for example, in the pachinko game machine 6001 of the present embodiment, a pre-read effect is performed based on the information of the reserved balls of the special symbol, and a preview notification at this time is also displayed in the display area 6013a.

Furthermore, in the present embodiment, when the gaming state is in the standby state, an effect image (demonstration image) for making the player understand that the game is in the standby state is displayed in the display area 6013a. In addition, in this embodiment, when the normal symbols stopped and displayed on the normal symbol display device 6063 are in a predetermined mode, a performance image that allows the player to grasp the information is displayed in the display area 6013a of the display device 6013. Additional functions may be provided.

<Configuration of circuit included in pachinko gaming machine>
Next, with reference to FIG. 161, the configurations of various circuits included in the pachinko gaming machine 6001 of this embodiment will be explained. Note that FIG. 161 is a block diagram showing the circuit configuration of the pachinko gaming machine 6001.

As shown in FIG. 161, the pachinko gaming machine 6001 mainly includes a main control circuit 6100 that controls gaming operations, a sub-control circuit 6200 that controls performance operations according to the progress of the game, and a payout/launch control circuit. It has a circuit 6300 and a power supply circuit 6033.

[Main control circuit]
The main control circuit 6100 includes a main CPU (Central Processing Unit) 6101, a main ROM (Read Only Memory) 6102, a main RAM (Random Access Memory) 6103, an initial reset circuit 6104, an I/O port 6105, and a command It includes an output port 6106 and a backup capacitor 6107. Main ROM 6102, main RAM 6103, and initial reset circuit 6104 are connected to main CPU 6101.

In this embodiment, a special symbol lottery (jackpot lottery) is performed when the first starting hole 6044 or the second starting hole 6045 wins, but this lottery process is controlled by the main control circuit 6100. That is, the main control circuit 6100 also serves as a means (determination means) for performing a lottery process to determine whether or not to shift the gaming state to a state advantageous to the player.

Further, in this embodiment, the main CPU 6101, main ROM 6102, main RAM 6103, I/O port 6105, and command output port 6106 may be provided separately. Furthermore, in this embodiment, a configuration example will be described in which the main ROM 6102 is built into the board of the main control circuit 6100, but the present invention is not limited to this. For example, a ROM board on which the main ROM 6102 is mounted may be connected to the board of the main control circuit 6100. Furthermore, in this embodiment, the various circuits (various means) within the main control circuit 6100 may be formed integrally or may be formed separately. Further, the main ROM 6102 does not need to be installed in the gaming machine, and may be configured to be able to communicate with the gaming machine.

The main CPU 6101 executes various processes according to programs stored in the main ROM 6102. The main ROM 6102 stores various programs for controlling the operation of the pachinko gaming machine 6001 by the main CPU 6101, various data tables, and the like.

The main RAM 6103 acts as a temporary storage area when the main CPU 6101 executes various processes, and stores various random numbers, lottery results, and values of various flags and variables that the main CPU 6101 needs for various processes. Specific examples of the memory maps of the main ROM 6102 and the main RAM 6103 and various types of information stored in the main RAM 6103 will be described later with reference to FIGS. 164 and 166 to 169, which will be described later. Note that in this embodiment, the main RAM 6103 is used as the temporary storage area of the main CPU 6101, but the present invention is not limited thereto, and any readable/writable storage medium can be used as the temporary storage area. .

The initial reset circuit 6104 is a circuit that generates a reset signal when the power is turned on. The I/O port 6105 is an interface (input/output port) for signals input and output between the main control circuit 6100 and various devices connected thereto. The command output port 6106 is an output port used when transmitting command data from the main CPU 6101 to the sub control circuit 6200. The backup capacitor 6107 is a capacitor for quickly supplying power to, for example, the main RAM 6103 in the event of a power outage (power off).By supplying power with this capacitor, various types of data stored in the main RAM 6103 can be saved even in the event of a power outage. Data can be retained.

Further, various devices that operate according to signals output from the main control circuit 6100 are connected to the main control circuit 6100, as shown in FIG. 161.

Specifically, the main control circuit 6100 includes a first special symbol display device 6061, a second special symbol display device 6062, a normal symbol display device 6063, a first special symbol retention display device 6064, and a second special symbol retention display device. 6065 and a normal symbol holding display device 6066 are connected. Each of these devices performs a predetermined operation based on a signal output from main control circuit 6100. For example, when a predetermined output signal is transmitted from the main control circuit 6100 to the first special symbol display device 6061, the first special symbol display device 6061 selects the first special symbol in the special symbol game based on the output signal. Controls the operation of variable display.

Furthermore, as shown in FIG. 161, the main control circuit 6100 is connected to various switches (sensors) and receives output signals from the various switches. Specifically, the main control circuit 6100 includes count switches 6053c, 6054c, general winning ball switches 6051a, 6052a, passing ball switch 6043a, first starting opening winning ball switch 6044a, second starting opening winning ball switch 6045a, etc. Connected.

The count switch 6053c counts the game balls that have won in the first big prize opening 6053, and outputs a predetermined output signal indicating the result to the main control circuit 6100. The count switch 6054c counts the game balls that have won into the second grand prize opening 6054, and outputs a predetermined output signal indicating the result to the main control circuit 6100. The general winning ball switch 6051a outputs a predetermined detection signal to the main control circuit 6100 when a game ball wins in the general winning hole 6051, and the general winning ball switch 6052a outputs a predetermined detection signal to the main control circuit 6100 when a game ball wins in the general winning hole 6052. In this case, a predetermined detection signal is output to main control circuit 6100.

Passing ball switch 6043a outputs a predetermined detection signal to main control circuit 6100 when a game ball passes ball passing detector 6043. The first starting opening winning ball switch 6044a outputs a predetermined detection signal to the main control circuit 6100 when a game ball wins in the first starting opening 6044. Further, the second starting opening winning ball switch 6045a outputs a predetermined detection signal to the main control circuit 6100 when the game ball wins the second starting opening 6045.

Moreover, as shown in FIG. 161, the main control circuit 6100 is connected to a normal electric accessory solenoid 6046a, a first big winning hole solenoid 6053b, and a second big winning hole solenoid 6054b. Then, the main control circuit 6100 drives and controls the normal electric accessory solenoid 6046a to bring the pair of blade members of the normal electric accessory 6046 into an open state or a closed state. In addition, the main control circuit 6100 drives and controls the first big winning hole solenoid 6053b and the second big winning hole solenoid 6054b, respectively, to put the first big winning hole 6053 and the second big winning hole 6054 in an open state or a closed state. (Controls opening and closing of special electric accessories (shutters 6053a, 6054a)).

Further, a performance display monitor 6070 and an error notification monitor 6071 are connected to the main control circuit 6100, as shown in FIG. 161.

Performance display data is displayed on the performance display monitor 6070 under the control of the main CPU 6101. The performance display data is, for example, data indicating the ratio of game balls paid out in a game state other than the jackpot game state with respect to the firing of a predetermined number (for example, 60,000 game balls), and is also called a base value. Note that the display contents displayed on the performance display monitor 6070 will be described in detail later.

An error code is displayed on the error notification monitor 6071. Furthermore, in addition to the error code, the error notification monitor 6071 displays a setting changing code indicating that the setting changing process is in progress, which will be described later, a setting checking code indicating that the setting confirmation process is in progress, etc., which will be described later. You can also do that. In addition, as the setting change code, a symbol (setting change symbol) that is not normally displayed may be displayed on the special symbol display device.

Further, a setting key 6080, a setting switch 6081, and a RAM clear switch 6121 are connected to the main control circuit 6100, as shown in FIG. 161.

The setting key 6080 is a key or a key-like key that triggers the execution of setting change processing and setting confirmation processing, which will be described later. The setting switch 6081 can be pressed down, and is pressed down when changing the set setting value during a setting change process to be described later. In addition, in this embodiment, as described above, in order to prevent a third party (for example, a player) other than the person in charge of gaming machine management from easily accessing the setting key 6080 and setting switch 6081, the setting key 6080 and setting switch 6081 are The switch 6081 is housed within the main board case.

In this embodiment, the setting key 6080 and the setting switch 6081 are connected to the main control circuit 6100, but the present invention is not limited to this. For example, the setting key 6080 and the setting switch 6081 are connected to the power supply circuit described below. It may be configured such that it is connected to 6033. In this case, too, the setting key 6080 and the setting switch 6081 are set in a predetermined case so that the setting key 6080 and the setting switch 6081 cannot be easily accessed by a third party (for example, a player) other than the person in charge of managing the gaming machine. Preferably, it is housed within. Note that "within a predetermined case" here includes not only those configured such that the setting keys 6080 and setting switches 6081 cannot be accessed without opening the case, but also the corresponding settings of the setting keys 6080 and setting switches 6081 of the case. When the pachinko game machine 6001 is rotated from the island equipment where the pachinko game machine 6001 is installed using a key managed by the game machine management manager and the back side is exposed. This also includes those configured so that a gaming machine manager can access the setting key 6080 and/or the setting switch 6081.

The RAM clear switch 6121 is connected not only to the main control circuit 6100 but also to the payout/emission control circuit 6300, and is a switch that can be operated when initializing (clearing) the main RAM 6103. When the backup data is cleared in response to the operation of the RAM clear switch 6121 by a game parlor manager or the like during a power outage, a predetermined detection signal is output to the main control circuit 6100 and the payout/launch control circuit 6300. Ru.

Further, a payout/emission control circuit 6300 is connected to the main control circuit 6100, as shown in FIG. 161. Note that the payout/launch control circuit 6300 is connected to a firing device 6015 that shoots game balls, a payout device 6016 that pays out game balls, and a card unit 6150, and a lending operation section 6151 is connected to the card unit 6150. be done.

When the payout/launch control circuit 6300 receives the prize ball control command supplied from the main control circuit 6100 or the rental ball control signal supplied from the card unit 6150, it transmits a predetermined signal to the payout device 6016, The payout operation of game balls by the payout device 6016 is controlled.

Further, the payout and firing control circuit 6300 controls the solenoid of the firing device 6015 according to the rotation angle (rotation amount) when the firing handle 6025 is grasped by the player and rotated clockwise. Power is supplied to an actuator (not shown) to control the firing operation of the game ball by the firing device 6015. Note that as a driving means for the firing device 6015, a motor may be used instead of the solenoid actuator.

When operated by a player, the rental operation section 6151 outputs a signal requesting the card unit 6150 to rent out game balls. The card unit 6150 determines the number of game balls to be paid out (the number of rental balls) based on a signal output from the rental operation section 6151 requesting the rental of game balls. When card unit 6150 receives a signal requesting rental of game balls from rental operation section 6151, card unit 6150 transmits a rental ball control signal including information on the determined number of rental balls to payout/launch control circuit 6300.

Further, a power supply circuit 6033 is connected to the main control circuit 6100, as shown in FIG. 161. Note that the power supply circuit 6033 is connected not only to the main control circuit 6100 but also to the sub control circuit 6200, the payout/emission control circuit 6300, and the like. The power supply circuit 6033 generates a power supply voltage necessary for playing a game with the pachinko game machine 6001, and supplies the generated power supply voltage to the main control circuit 6100, the sub-control circuit 6200, the payout/launch control circuit 6300, etc.

Further, a power switch 6035 (see also FIG. 159) and the like are connected to the power supply circuit 6033. The power switch 6035 is turned on when supplying the necessary power to the pachinko game machine 6001.

As shown in FIG. 161, the main control circuit 6100 also includes an external terminal board 6140 used to transmit data to the hall computer 6700 that manages the pachinko machines in the entire hall, a function to call the hall staff, and the number of jackpots. A calling device (not shown) having a function of displaying a message, etc. is connected.

[Performance display monitor]
Here, the contents of the data displayed on the performance display monitor 6070 will be explained. The payout/firing control circuit 6300 totals the base value based on past game history, and stores the total result in a specific work area within the work area of the main RAM 6103. This specific work area is an area in which data is not cleared even if RAM clear processing (backup clear processing) is performed. Note that the base value may be tallied based on the performance of a predetermined operation, or may be always tallied so that the base value is always displayed on the performance display monitor 6070. .

Although not shown, the payout/launch control circuit 6300 is a system that calculates all base values based on the entire gaming history from the initial power-on (the first power-on after the pachinko game machine 6001 was manufactured) to the present. The gaming machine includes a history aggregation means and a history aggregation means for each setting value that executes aggregation of base values for each setting value based on past game history for each setting value.

For example, when a gaming machine manager or the like performs an operation to display all base values, the all history aggregation means executes the aggregation of all base values as described above. The total base value totaled by the total history totaling means is displayed on the performance display monitor 6070 under the control of the main CPU 6101. Further, when the display operation of the base value by setting value is performed, the history aggregation unit by setting value executes the aggregation of the base value by setting value. Then, the setting value-specific base values aggregated by the setting value-specific history aggregating means are displayed on the performance display monitor 6070 under the control of the main CPU 6101.

The setting value-by-setting history aggregation means can also aggregate only base values for arbitrary setting values in response to a request (operation). In this case, not only the base value of the currently set setting value but also the base value of other setting values that are not currently set can be compiled. Therefore, the main CPU 6101 can display base values for other setting values on the performance display monitor 6070 without executing setting change processing.

In addition, the main CPU 6101 calculates both the total base value totaled by the total history totaling means and the base value by setting value totaled by the setting value-specific history totaling means, in response to an operation by, for example, a gaming machine management manager. Not only can it be displayed on the performance display monitor 6070, but also only one of the two can be selectively displayed on the performance display monitor 6070.

Note that the main CPU 6101 may display only the base value of a specific setting value on the performance display monitor 6070, or may display the base value of all setting values on the performance display monitor 6070. Further, the main CPU 6101 may display both the total base value and the base value by setting value on the performance display monitor 6070. Furthermore, the main CPU 6101 displays both the performance display monitor 6070 and other display means when displaying the base value of all setting values or when displaying both the total base value and the base value by setting value. You can also display these base values using

Further, as described above, the dispensing/firing control circuit 6300 includes a total history aggregation means and a history aggregation means for each setting value, but in addition to these, or in place of the history aggregation means for each setting value, a setting change process is performed. The game machine may also include a post-setting change history aggregating means for tabulating the post-setting change base value based on the game history from the time when the game was executed to the present. In this case, the main CPU 6101 can display the base value by setting value after the setting change on the performance display monitor 6070 based on the display operation of the base value after the setting change.

In this way, all or part of all base values, base values by setting value, and/or base values by setting value after setting change (base value after setting change) are displayed on the performance display monitor 6070. By doing so, for example, information based on the past gaming history of the pachinko gaming machine 6001 can be easily confirmed.

In addition, in this embodiment, the configuration in which the base value is displayed on the performance display monitor 6070 has been described, but the present invention is not limited to this. ), the ratio of the number of game balls paid out by balls entering the normal electric accessory (payout by the accessory) may be displayed. In addition, for example, the ratio of the number of game balls paid out by the accessory to the total number of game balls fired may be displayed, and further, for example, the ratio of the number of game balls paid out by the special electric accessory (big prize opening) may be displayed. It may also be one that displays the percentage of pitches. Further, these ratios may be displayed for each set value.

[Sub control circuit]
Sub-control circuit 6200 is connected to command output port 6106 of main control circuit 6100, as shown in FIG. 161. The sub control circuit 6200 (host control circuit 6210 to be described later) controls the entire sub control circuit 6200 in accordance with various commands (information regarding the progress of the game) transmitted from the main control circuit 6100.

Specifically, the sub control circuit 6200 controls the audio reproduction operation by the speaker 6011, the image display operation by the display device 6013, and the lamp group including LEDs based on various commands sent from the main control circuit 6100. The lamp lighting/extinguishing operation by the lamp 6018 is controlled, and the presentation operation by the accessory 6020 (decorative member) is controlled. That is, the sub-control circuit 6200 controls various presentation devices based on commands from the main control circuit 6100, and executes various presentations according to the progress of the game. Note that although this embodiment has a configuration in which signals cannot be supplied from the sub-control circuit 6200 to the main control circuit 6100, the present invention is not limited to this, and it is possible to send signals from the sub-control circuit 6200 to the main control circuit 6100. It may have a configuration.

Furthermore, an accessory detection sensor 6090 is connected to the sub-control circuit 6200, as shown in FIG. 161. The accessory detection sensor 6090 is a sensor that detects that the accessory 6020 (movable accessory) is at the initial position. Note that when the accessory 6020 is composed of a plurality of movable parts (including a plurality of motors), the accessory detection sensor 6090 is provided for each motor.

Although illustrations and explanations are omitted, in the pachinko gaming machine 6001 of this embodiment, as in the first embodiment, the sub control circuit 6200 includes a volume switch 108, a performance button switch 621, and a main button switch. Various effect switches such as 6621 and select button switches 6641a to 6641d are connected, and various effect functions are also provided to operate these switches based on their on/off states.

Next, the internal configuration of sub control circuit 6200 will be described in more detail with reference to FIG. 162. Note that FIG. 162 is a block diagram showing the circuit configuration inside the sub-control circuit 6200 and the connection relationship between the sub-control circuit 6200 and its various peripheral devices. Note that in FIG. 162, illustration of the accessory detection sensor 6090 is omitted for convenience of explanation.

The sub-control circuit 6200 includes a relay board 6201, a sub-board 6202, a control ROM board 6203, and a CGROM (Character Generator ROM) board 6204, as shown in FIG. The sub-board 6202 is connected to the relay board 6201, the control ROM board 6203, and the CGROM board 6204. Note that in the sub-control circuit 6200, the sub-board 6202 and various ROM boards (control ROM board 6203 and CGROM board 6204) are connected via a board-to-board connector (not shown).

Relay board 6201 is a relay board for receiving commands transmitted from main control circuit 6100 and transmitting the received commands to sub-board 6202.

The sub board 6202 is provided with a host control circuit 6210, an audio/LED control circuit 6220, a display control circuit 6230, an SDRAM (Synchronous Dynamic RAM) 6250, and a built-in relay board 6260.

The host control circuit 6210 is a circuit that controls the overall operation of the sub control circuit 6200 based on various commands sent from the main control circuit 6100, and is configured by a CPU processor. The host control circuit 6210 is connected to an audio/LED control circuit 6220, a display control circuit 6230, and a built-in relay board 6260 within the sub-board 6202. Further, the host control circuit 6210 is connected to the control ROM board 6203.

Further, the host control circuit 6210 includes a sub-work RAM 6210a and an SRAM (Static RAM) 6210b. The sub-work RAM 6210a is a storage device that acts as a temporary storage area for work when the host control circuit 6210 executes various processes, and stores various flags and variables necessary when the host control circuit 6210 executes various processes. Memorize the value etc. The SRAM 6210b is a storage device that backs up predetermined data in the subwork RAM 6210a. Note that in this embodiment, a RAM is used as the temporary storage area of the host control circuit 6210, but the present invention is not limited to this, and any storage medium that can be read and written may be used as the temporary storage area. .

The audio/LED control circuit 6220 is connected to the speaker 6011 and the lamp group 6018 via the built-in relay board 6260, and controls the audio output from the speaker 6011 based on control signals (sound request and lamp request) input from the host control circuit 6210. This circuit controls the reproduction operation and the light emission operation by the lamp group 6018. Therefore, functionally, the audio and LED control circuit 6220 includes an audio controller 6220a and a lamp controller 6220b. The audio controller 6220a and the lamp controller 6220b are substantially included in a sound and lamp control module 6226, which will be described below.

Note that in this embodiment, when the control signal and data (for example, LED data described below) output from the audio/LED control circuit 6220 are transmitted to the lamp group 6018 via the built-in relay board 6260, the audio/LED control circuit 6220 Communication between the control circuit 6220 and the lamp group 6018 is performed using an SPI (Serial Peripheral Interface) communication method (a type of serial communication method). Further, in this embodiment, lamp group 6018 includes one or more LEDs and one or more LED drivers for controlling each LED.

The display control circuit 6230 is connected to the display device 6013 and displays images related to effects (decorative pattern images, background images, images for effects, etc.) on the display device 6013 based on a control signal (drawing request) input from the host control circuit 6210. This is a circuit for controlling various processing operations when displaying images. Note that the display control circuit 6230 includes display controllers (a first display controller 6238 and a second display controller 6239) and a built-in VRAM (Video RAM) 6237.

Further, the display control circuit 6230 is connected to the SDRAM 6250 within the sub-board 6202. Furthermore, display control circuit 6230 is connected to CGROM board 6204. Further, the display controller in the display control circuit 6230 is directly connected to the display device 6013 without using a relay board.

The SDRAM 6250 is configured with a DDR2 (Double-Date Rate 2) SDRAM. Further, the SDRAM 6250 is provided with various buffers that temporarily store various image data during rendering processing of images (moving images and still images) displayed by the display device 6013. For example, the SDRAM 6250 is provided with a texture buffer, a movie buffer, a blend buffer, two frame buffers (a first frame buffer and a second frame buffer), a motion buffer, and the like.

The built-in relay board 6260 receives various signals and various data output from the host control circuit 6210 and the audio/LED control circuit 6220, and transmits the received various signals and various data to the speaker 6011, the lamp group 6018, and the accessory 6020. This is a relay board that transmits data.

Further, the built-in relay board 6260 includes an I2C (Inter-Integrated Circuit) controller 6261, a digital audio power amplifier 6262 (audio amplification means), and a voltage conversion circuit section 6269.

Although this embodiment shows an example in which the I2C controller 6261, digital audio power amplifier 6262, and voltage conversion circuit section 6269 are mounted on the same relay board, the present invention is not limited to this, and the relay board equipped with the I2C controller 6261 is The substrate, the relay board on which the digital audio power amplifier 6262 is mounted, and the relay board on which the voltage conversion circuit section 6269 is mounted may be provided separately. Further, in this embodiment, an example has been described in which a relay board on which an I2C controller 6261, a digital audio power amplifier 6262, and a voltage conversion circuit section 6269 are mounted is provided in the sub-board 6202, but the present invention is not limited to this. A relay board on which the I2C controller 6261, digital audio power amplifier 6262, and voltage conversion circuit section 6269 are mounted may be provided separately from the sub-board 6202, and the two boards may be electrically connected by wiring or the like.

The I2C controller 6261 is connected to the host control circuit 6210 and the motor controller 6270 of the accessory 6020. That is, the host control circuit 6210 is connected to the accessory 6020 via the I2C controller 6261 and the motor controller 6270. Control signals and data (for example, excitation data, etc.) output from the host control circuit 6210 are input to the accessory 6020 via the I2C controller 6261 and the motor controller 6270.

Note that in this embodiment, communication between the I2C controller 6261 and the motor controller 6270 is performed using an I2C communication method (a type of serial communication method). Although not shown, the accessory 6020 includes one or more motors, and the motor controller 6270 includes one or more motor drivers for driving each motor. Moreover, although FIG. 162 shows an example in which only one accessory 6020 is provided, the present invention is not limited to this, and a plurality of accessory objects 6020 may be provided.

Furthermore, in the configuration of this embodiment, the host control circuit 6210 may directly drive the motor of the accessory 6020 without using the motor controller 6270, or a control circuit for controlling the motor may be provided separately. good. Further, in this embodiment, a plurality of motor drivers (motors) are controlled by one control circuit, but the present invention is not limited to this. In this embodiment, one or more (one or more) control circuits may control one or more (one or more) motors (motor drivers), or one or more (one or more) control circuits may control one or more (one or more) motors (motor drivers). The configuration may be such that one motor (motor driver) is controlled, or the configuration may be configured such that one control circuit controls one motor (motor driver).

Further, the digital audio power amplifier 6262 is connected to the audio/LED control circuit 6220 and the speaker 6011. That is, the audio/LED control circuit 6220 is connected to the speaker 6011 via the digital audio power amplifier 6262. Therefore, the audio signal etc. output from the audio/LED control circuit 6220 is input to the speaker 6011 via the digital audio power amplifier 6262.

Although not shown, the voltage conversion circuit section 6269 is connected to the power supply circuit 6033, the speaker 6011, the lamp group 6018, and the motor controller 6270 (accessories 6020). The voltage conversion circuit section 6269 is a circuit section (DC/DC conversion circuit section) that converts the input DC voltage into a lower DC voltage and outputs the DC voltage. In this embodiment, the voltage conversion circuit unit 6269 converts the +12V power supply voltage (DC voltage) input from the power supply circuit 6033 into a +5V drive voltage (DC voltage). Then, the voltage conversion circuit section 6269 supplies the converted +5V driving voltage to the speaker 6011, the lamp group 6018, and the motor controller 6270 (accessories 6020).

The control ROM board 6203 is provided with a sub-main ROM 6205. The sub-main ROM 6205 stores various programs and various data tables for controlling the performance operations of the pachinko gaming machine 6001 by the host control circuit 6210. The host control circuit 6210 then executes various processes according to the programs stored in the sub-main ROM 6205.

Note that in this embodiment, the sub-main ROM 6205 is used as a storage means for storing programs, various tables, etc. used in the host control circuit 6210, but the present invention is not limited thereto. As such storage means, other types of storage media may be used as long as they are readable by a computer equipped with a control means, such as hard disk drives, CD-ROMs, DVD-ROMs, ROM cartridges, etc. storage media may be applied. Furthermore, each of the programs may be recorded on separate storage media. Further, the program may be recorded in advance on a recording medium, or may be downloaded from an external source after power is turned on and recorded in the sub-main ROM 6205.

A CGROM 6206 is provided on the CGROM board 6204. The CGROM 6206 is composed of a NOR type or NAND type flash memory. Further, the CGROM 6206 stores, for example, image data displayed on the display device 6013, audio data (access data) played back by the speaker 6011, and the like. Note that at this time, various data are compressed (encoded) and stored in the CGROM 6206, but the present invention is not limited to this, and the various data may be stored in the CGROM 6206 without being compressed.

Note that in this embodiment, a configuration in which various ROM boards (control ROM board 6203 and CGROM board 6204) and sub-board 6202 are connected by a board-to-board connector in the sub-control circuit 6200 has been described. The invention is not limited to this. For example, the sub-board 6202 may be configured with a single board having a ROM function or the ROM itself by directly inserting various ROMs into ports such as sockets provided on the sub-board 6202. That is, the sub-board 6202 and various ROMs may be integrally configured. Further, when the sub-board 6202 is configured by a single board having a ROM function or a ROM itself, the sub-control circuit 6200 controls the sub-board to be used according to the type of memory used as a CGROM. It may also include switching means for physically or electrically switching the circuits on the substrate, or switching means for switching the information of the circuits on the sub-boards to be used depending on the type of memory.

Furthermore, in this embodiment, the relationship in data communication speed between each of the various storage means (sub-main ROM 6205, CGROM 6206, built-in VRAM 6237, SDRAM 6250) and the corresponding control circuit is as follows: Built-in VRAM 6237>SDRAM 6250>Sub-main ROM6205≒CGROM6206. That is, in this embodiment, the communication speed between the built-in VRAM 6237 and various circuits in the display control circuit 6230 is the fastest, and the communication speed between the SDRAM 6250 and the display control circuit 6230 is the second fastest. The communication speed between the sub-main ROM 6205 and the host control circuit 6210 and the communication speed between the CGROM 6206 and the display control circuit 6230 are the slowest. However, the present invention is not limited thereto, and the relationship in communication speed between each of the various storage means and the corresponding control circuit can be set arbitrarily. For example, the magnitude relationship of the communication speed between each of the various storage means and the corresponding control circuit may be different from this embodiment, or the communication speed between each storage means and the corresponding control circuit may be different from this embodiment. may all be the same.

Here, possible configurations of the various storage means (information storage means) described above will be explained. In this embodiment, the storage means (first storage means) for information regarding image data (compressed (encoded) image data) stores information regarding transparency data that can be used when setting transparency for image data. Although the configuration is physically the same (CGROM6206) as the storage means (second storage means) of (alpha table), the present invention is not limited to this. For example, the first storage means (first information storage means) may be comprised of a storage means (storage medium) that is physically different from the second storage means (second information storage means). .

Furthermore, the term "information storage means" as used herein refers not only to storage means such as the CGROM 6206, but also to tables stored in the storage means, data storage areas within the storage means, etc. good. Therefore, for example, the first information storage means and the second information storage means described above may be different data storage areas within the same storage means, or may be different tables, Alternatively, the information may be stored in mutually different register addresses. In other words, "information storage means" used in this specification are different not only when they are physically different storage means (storage media), but also when they are physically the same storage means (for example, ROM, RAM, etc.) However, the meaning also includes cases where data areas (storage areas distinguished by addresses, registers, tables, structures, etc.) are different within the storage means.

Note that the above-mentioned meaning of "information storage means" in this specification is also applicable to the above-mentioned SDRAM 6250 (third information storage means) and built-in VRAM 6237 (fourth information storage means). Therefore, for example, the above-mentioned first information storage means to fourth information storage means may be configured with physically different storage means (storage media), or the first information storage means to fourth information storage means may be composed of physically different storage means (storage media). The information storage means 4 may be composed of mutually different data areas (storage areas distinguished by addresses, registers, tables, structures, etc.) within one storage means.

Further, in this embodiment, the first information storage means and the second information storage means are configured in mutually different data areas within one storage means (CGROM 6206), and the third information storage means is configured as A storage means (CGROM6206) including a first information storage means and a second information storage means, and a physically different storage means (SDRAM6250), and the fourth information storage means is configured to store the first information. Although an example has been described in which the storage means (CGROM 6206) including the storage means and the second information storage means, and the storage means (built-in VRAM 6237) which is physically different from the third information storage means (SDRAM 6250), this The invention is not limited to this. Whether the "information storage means" should consist of a data area or a storage means, and how the "information storage means" defined as a data area should be combined with the "information storage means" defined as a storage means. The mode can be set as appropriate depending on, for example, the configuration (number, type, etc.) of the storage means provided in the gaming machine. For example, in the present embodiment, the first information storage means to the third information storage means are constituted by mutually different data areas within one storage means, and the fourth information storage means is constituted by the above-mentioned third information storage means. The storage means may be physically different from the storage means including the first information storage means to the third information storage means.

<Various registers included in the main CPU>
Next, various registers included in the main CPU 6101 will be described with reference to FIG. 163. Note that FIG. 163 is a schematic configuration diagram of various registers included in the main CPU 6101.

The main CPU 6101 has main registers such as an accumulator A (hereinafter referred to as the "A register"), a flag register F, a general-purpose register B (hereinafter referred to as the "B register"), and a general-purpose register C (hereinafter referred to as the "C register"). ), general-purpose register D (hereinafter referred to as "D register"), general-purpose register E (hereinafter referred to as "E register"), general-purpose register H (hereinafter referred to as "H register"), and general-purpose register L (hereinafter referred to as "L register"). ”). The main CPU 6101 also has sub-registers such as accumulator A', flag register F', general-purpose register B', general-purpose register C', general-purpose register D', general-purpose register E', general-purpose register H', and general-purpose register L'. has as a general-purpose register. Note that each register is composed of a 1-byte register.

Further, in this embodiment, the B register and C register are used as a pair register (hereinafter referred to as "BC register"), and the D register and E register are used as a pair register (hereinafter referred to as "DE register"). Furthermore, in this embodiment, an H register and an L register are used as a pair register (hereinafter referred to as "HL register").

As shown in FIG. 163, predetermined flag information indicating the result of arithmetic processing, etc. is set in each bit of the flag registers F and F'. For example, bit 6 (D6) is set with data (zero flag) indicating whether or not the calculation result is "0" in the calculation result determination process. Specifically, if the calculation result is "0", data "1" is set in bit 6, and if the calculation result is not "0", data "0" is set in bit 6. In the process of determining the calculation result, the main CPU 6101 makes the determination by referring to the data "0"/"1" of bit 6.

The main CPU 6101 also has an extension register Q (hereinafter referred to as "Q register"). The Q register consists of a 1-byte register. In addition, in this embodiment, various instruction codes dedicated to the main CPU 6101 that can specify addresses using this Q register are provided on the source programs for various processes described later, and by using these instruction codes, This improves processing efficiency and reduces the capacity of the main ROM 6102. Note that in various main CPU 6101-dedicated instruction codes that specify addresses using the Q register, address data (address value) on the upper side of the address is stored in the Q register. Furthermore, "F0H" is set as an initial value in the Q register immediately after the main CPU 6101 is reset.

Furthermore, the main CPU 6101 includes an interrupt page address register I (hereinafter referred to as "I register") and a memory refresh register R, each of which is composed of a 1-byte register, and a 2-byte register. It has an index register IX (hereinafter referred to as "IX register"), an index register IY (hereinafter referred to as "IY register"), a stack pointer SP, and a program counter PC as dedicated registers.

<Internal configuration of main ROM and main RAM (memory map)>
Next, the internal configurations (hereinafter referred to as "memory map") of the main ROM 6102 and main RAM 6103 included in the main control circuit 6100 (microprocessor) will be described with reference to FIGS. 164A to 164C. Note that FIG. 164A is a diagram showing a memory map of the entire memory, FIG. 164B is a diagram showing a memory map of the main ROM 6102, and FIG. 164C is a diagram showing a memory map of the main RAM 6103.

In the memory map of the entire memory included in the main control circuit 6100, as shown in FIG. 164A, from the beginning of the address (0000H), the memory area of the main ROM 6102, the memory area of the main RAM 6103, the built-in register area, and the XCS decode area are as follows: They are arranged at predetermined addresses in this order with an unused area in between.

In the memory map of the main ROM 6102, as shown in FIG. 164B, the program area, data area, outside area, trademark recording area, program management area, and security setting area are arranged in this order from the address start (0000H) side of the main ROM 6102. They are placed at predetermined addresses in order.

Note that the program area stores control programs for various processes executed by the main CPU 6101 in various control processes related to the progress of the game and the gameplay. The data area contains various data used by the main CPU 6101 in various control processes related to game progress and gameplay (for example, data tables such as a jackpot lottery data table, and various control commands to the sub control circuit 6200). data, etc. for sending commands) are stored. That is, the gaming ROM area (gaming storage area) consisting of a program area and a data area stores various programs and programs necessary for control processing (processing related to gaming) related to the games actually played by players at the gaming parlor. Various data are stored.

Furthermore, control programs and data for various processes (processes that do not affect the gameplay) that are not directly involved in the games played by the players (game progress and gameplay) are stored in the outside area. For example, programs and data used in the certification test (sight shooting test) of the pachinko gaming machine 6001, control programs used in checksum generation processing at the time of power outage, sum check processing at the time of power outage recovery (power recovery), etc. and data, as well as anti-fraud programs and necessary data, etc., are stored in the outside area.

In the memory map of the main RAM 6103, as shown in FIG. 164C, the gaming RAM area (temporary storage area for gaming) and the outside RAM area (temporary storage area outside the area) are arranged from the start address (F000H) of the main RAM 6103. , are placed at predetermined addresses in this order.

The gaming RAM area temporarily stores, for example, various data (various random numbers, jackpot determination results, etc.) determined by the execution of control programs related to the games (game progress and gameplay) played by the player. A storage work area and a stack area are provided. Each of the various data is stored in a work area at a predetermined address within the gaming RAM area.

Further, the extra-area RAM area is provided with an extra-area work area and an extra-area stack, which are work areas for various processes that are not directly involved in the game played by the player (game progress and gameplay). In this embodiment, this extra-regional RAM area is used to execute various processes that are not directly related to the game played by the player, such as a sum check process.

As described above, in the pachinko gaming machine 6001 of this embodiment, various programs and various data (tables) used for various processes that are not directly related to the games played by the players are stored in the main ROM 6102 in the gaming ROM 6102. The data is stored in an out-of-area ROM area (out-of-area storage area) located at an address different from the area. Further, various processes that are not directly related to the games played by such players are performed using an extra-area RAM area located at a different address from the gaming RAM area within the main RAM 6103.

With such a configuration of the main ROM 6102, programs and data that are unnecessary for the game actually played by the player can be placed in the outside ROM area. Therefore, in this embodiment, it is possible to avoid pressure on the capacity of the gaming ROM area.

[Modified example of the configuration of the work area in the main RAM]
In this embodiment, as shown in FIG. 164, an example is shown in which the work area of the gaming RAM area is used as one area in the main RAM 6103 arranged in an area within a predetermined range from address "F000H" in the memory map. However, the present invention is not limited thereto.

For example, when the pachinko gaming machine 6001 of this embodiment has a simultaneous variation function, various control processes related to the variable display of the first special symbol and various control processes related to the variable display of the second special symbol are performed. It is desirable to be able to efficiently switch between the two. To solve this problem, for example, the work area of the gaming RAM area in the main RAM 6103 is divided into a first work area starting from address "F000H" and a second work area starting from address "F100H". Various control processes related to the variable display of the first special symbol may be executed using the first work area, and various control processes related to the variable display of the second special symbol may be executed using the second work area.

In this case, for example, an identifier indicating which of the first work area and the second work area is used is added to various data used in various control processes regarding the variable display of special symbols. Based on the identifier added to the data to be processed, if the identifier corresponds to the use of the first work area (various control processes for variable display of the first special symbol), the first work The upper address ("F0H") of the start address of the area is loaded, and various control processes are performed on the data to be processed in the first work area. On the other hand, if the identifier added to the data to be processed corresponds to the use of the second work area (various control processes for variable display of the second special symbol), then the upper address of the start address of the second work area ("F1H") and performs various control processing predetermined on the data to be processed in the second work area.

When such a work area configuration is adopted in the pachinko gaming machine 6001 of the present embodiment, various control processes related to the variable display of the first special symbol and various control processes related to the variable display of the second special symbol. can be switched efficiently. That is, when the configuration of the working area of the gaming RAM area in this example is used, the processing performed by the main control circuit 6100 can be executed more efficiently in the pachinko gaming machine 6001 equipped with the simultaneous variation function. , the processing load on the main control circuit 6100 can be reduced. Further, in this embodiment, the pachinko gaming machine 6001 is shown having a simultaneous variation function, but the playability is not limited to this, and the processing related to the variation display of the first special symbol and the second special symbol can be efficiently performed. can do well.

In this example, various control processes related to the variable display of the first special symbol are executed using the first work area, and various control processes related to the variable display of the second special symbol are executed using the second work area. Although an example of execution has been described, the present invention is not limited to this. For example, regardless of the type of special symbol, whether the first work area or the second work area is used in each processing unit performed in game progress control is specified by an identifier added to the data to be processed. However, a configuration may be adopted in which a work area to be used in the processing is selected based on the identifier. With such a configuration, it is possible to efficiently select a work area to be used in accordance with the identifier added to the data to be processed in units of processing, and perform predetermined processing. As a result, the processing performed by the main control circuit 6100 can be executed more efficiently, and the processing load on the main control circuit 6100 can be reduced.

<Type of gaming state>
Next, the types of gaming states controlled and managed by the main CPU 6101 in the pachinko gaming machine 6001 of this embodiment will be explained.

First, the types of gaming states controlled and managed by the main CPU 6101 include a "big hit gaming state" and a "small winning gaming state" which have different expectations of prize balls.

The jackpot game state is a game state in which a round game occurs in which the opening period (i.e., one round period) of the shutter 6053a of the first big prize opening 6053 or the shutter 6054a of the second big winning opening 6054 is long (for example, 30 seconds). This is a gaming state in which the player can expect a large prize ball. That is, in the jackpot game state, the repeating mode of the open state and closed state of the shutter of the big winning opening becomes an advantageous state for the player.

On the other hand, the small winning gaming state is a gaming state in which a round game occurs in which the period of one round is shorter (for example, 1.8 seconds) compared to the jackpot gaming state, and it is a gaming state in which the player cannot expect a large prize ball. be. That is, in the small winning game state, the repeated manner of opening and closing the shutter of the big winning opening is disadvantageous for the player compared to the jackpot playing state. In addition, in this embodiment, the small hit game state is when a "small win" is won in the second special symbol lottery (jackpot lottery) that is triggered by the game ball entering the second starting slot 6045. This is the gaming state to which the game will be transferred.

In addition, in the jackpot game state, it is possible to play a round game, while in the small win game state, basically there is no round game, and the jackpot continuous operation device does not operate and the jackpot is opened and closed. may be made possible. In addition, after the jackpot game state ends, it is possible to shift to a game state that is advantageous for the player, but after the small win game ends, the player shifts to a game state that is more advantageous than before the transition to the small win game state. It is also possible to not allow it. However, if the big prize opening with a specific area is opened during the small winning game state, the condition device is activated by the game ball passing through the specific area, and the accessory continuous operation device is activated, the small winning After the gaming state ends, the player may move to a jackpot gaming state, which is an advantageous gaming state, and it may be possible to count the number of rounds even in the small winning gaming state.

Further, in the present embodiment, an example has been described in which a small hit is not provided for the first special symbol and a small win is provided for the second special symbol, but the present invention is not limited to this. The present invention provides a case where a small hit is provided for both the first special symbol and a second special symbol, a case where a small win is provided for the first special symbol, and a small win is not provided for the second special symbol. , and the case where a small hit is not provided for both the first special symbol and the second special symbol.

In addition, the types of gaming states controlled and managed by the main CPU 6101 include "variable gaming states" (high probability gaming states) and "normal gaming states" (low probability gaming states), which have different probabilities of winning the "jackpot". be. The variable probability gaming state is a gaming state in which the probability of winning a "jackpot" is high, and the normal gaming state is a gaming state in which the probability of winning a "jackpot" is low compared to the variable probability gaming state.

In addition, in the pachinko game machine 6001 of this embodiment, the probability of winning a "jackpot" during the normal gaming state is, for example, 1/199 (when the setting is "6") to 1/259 (when the setting is "6"). 1"). On the other hand, the probability of winning a "jackpot" during the variable probability gaming state varies, for example, in the range of 1/39.9 (when set to "6") to 1/51.8 (when set to "1").

Furthermore, the types of gaming states controlled and managed by the main CPU 6101 include "time-saving gaming states" (high winning gaming states) in which the winning probabilities of normal symbols (probability of normal symbols becoming "winning") are different from each other; There is a "non-time-saving gaming state" (low winning gaming state).

The "time-saving gaming state" as used herein refers to a gaming state in which the winning probability of normal symbols is high. That is, the time-saving game state is a game state in which the normal electric accessory 6046 (blade member) provided in the second starting port 6045 is likely to be in the open state (a gaming state in which the second starting port winning is likely to occur), and the game state is This is an advantageous gaming situation for players. Incidentally, the time saving game state ends when a "jackpot" is determined or when the variable display of special symbols is executed a predetermined number of times (for example, 100 times, etc.).

On the other hand, the "non-time-saving gaming state" is a gaming state in which the winning probability of normal symbols is lower than that of the "time-saving gaming state." Therefore, the non-time-saving gaming state is a gaming state in which the normal electric accessory 6046 (blade member) is difficult to open (a gaming state in which it is difficult for the second starting opening prize to occur), and is a gaming state that is disadvantageous for the player. be.

In the pachinko gaming machine 6001 of this embodiment, the combinations of the above-mentioned gaming states other than the jackpot gaming state and the small winning gaming state change. Note that this combination of gaming states changes depending on, for example, the performance mode managed and transition controlled by the sub-control circuit 6200.

Specifically, in this embodiment, there is a gaming state in which a variable probability gaming state and a time-saving gaming state occur simultaneously (a state with "high probability time saving"), and a gaming state in which a variable probability gaming state and a non-time-saving gaming state occur simultaneously. A gaming state (“no high accuracy time saving” state) is provided. In addition, in the state of "no high probability time saving", it is difficult for the player to determine whether the gaming state is a variable probability gaming state or not, so it is also called a "potential probability gaming state". In addition, in this embodiment, a gaming state in which a normal gaming state and a time-saving gaming state occur simultaneously (a state with "low probability time-saving"), and a gaming state in which a normal gaming state and a non-time-saving gaming state occur simultaneously ( A state of "low certainty no time saving") is also provided.

<Special symbol simultaneous variation function>
As described above, the pachinko gaming machine 6001 of this embodiment is a gaming machine in which the first special symbol and the second special symbol can be changed simultaneously. When the special symbol simultaneous variation function is activated, the following various processes are performed.

When one of the first special symbol and second special symbol starts to fluctuate, if the other special symbol is already fluctuating to become a jackpot, the fluctuation display of one special symbol will indicate a loss or a small hit. The display is controlled so that the display changes as follows. In other words, when one special symbol starts changing, if the other special symbol is already in the process of becoming a jackpot, the lottery result of one special symbol will not become a jackpot, and internally, one of the special symbols will be changed. In response to the variable display of the special symbol, a lottery is performed for a variable display (losing symbol or small winning symbol) such that a loss or small winning symbol confirmation process is forcibly performed.

Also, when one of the first special symbol and the second special symbol is determined (stop display), one of the special symbols is a jackpot symbol (specific mode), and the other special symbol is changing. In this case, symbol confirmation processing is performed such that the variable display of the other special symbol is forcibly displayed as a losing variable display (losing symbol).

In addition, when transitioning to a jackpot operation when one special symbol is confirmed, processing is performed to prevent the other special symbol from starting to fluctuate. Specifically, when transitioning to the jackpot operation when the symbol of one special symbol is confirmed, the special symbol suspension flag provided for the other special symbol is set to the ON state so that the other special symbol does not start fluctuating. After the jackpot game performed by confirmation of the jackpot of one special symbol ends, the special symbol suspension flag of the other special symbol is set to an OFF state (cleared).

In addition, when transitioning to a small hit operation when one special symbol (second special symbol in this embodiment) is confirmed, a process is performed to interrupt the variable display of the other special symbol. Specifically, when transitioning to a small hit operation when the symbol of one special symbol is confirmed, the special symbol pause flag of the other special symbol is set to ON state, the fluctuating display of the other special symbol is interrupted, and one After the completion of the small winning game which is performed by confirming the small winning of the special symbol, the special symbol suspension flag of the other special symbol is set to an OFF state (cleared). In addition, when the special symbol fluctuation display is interrupted, the measurement of the special symbol fluctuation time is interrupted, and the special symbol remains fluctuated.

Furthermore, in this embodiment, for example, when the variable display time of one special symbol (special symbol waiting time described below) has elapsed and the confirmed symbol of one of the special symbols is a jackpot symbol (when the jackpot symbol is confirmed), When the other special symbol shifts from the demonstration waiting state to the start of fluctuation (the other special symbol wins), that is, when the fluctuating display of one special symbol ends with a jackpot symbol (specific pattern), If the start of fluctuation of the other special symbol (at the time of winning) overlaps, the following process is performed.

Here, with reference to FIG. 165A, an example of processing will be described in a case where the time when the fluctuating display of one special symbol ends with a jackpot symbol and the time when the fluctuating start of the other special symbol overlaps. FIG. 165A shows processing details for each special symbol in a case where the fluctuating display of one special symbol ends with a jackpot symbol (specific mode) and the time when the fluctuation of the other special symbol starts (at the time of winning a prize) overlaps. It is a time chart for explaining.

In this case, first, when the symbol of one special symbol is confirmed (when the jackpot is confirmed: t1 in Fig. 165A), the special symbol suspension flag of the other special symbol is set to ON state, and the other special symbol starts changing. Try not to. Next, after the end of the jackpot game performed by confirmation of the jackpot of one special symbol (t2 in FIG. 165A), the special symbol suspension flag of the other special symbol is set to an OFF state (cleared). As a result, the variable display of the other special symbol is started. In addition, if a game feature is provided in which an electric support is attached in a variable probability game state after the end of the jackpot game, the special symbol suspension flag of the other special symbol is set to the off state after the end of the game period of the electric support, and the special symbol of the other special symbol is The variable display of will start. Further, when the electric support is not attached after the end of the jackpot game, the special symbol suspension flag of the other special symbol is set to the off state at the end of the jackpot game, and the variable display of the other special symbol is started.

However, in this case, the other special symbol will not be forced to display a variable display that causes the stop symbol to be a loss or a small hit, and the lottery results (results of a jackpot lottery, etc.) of the other special symbol will be maintained. , the variable display of the other special symbol is not started. Therefore, by performing such processing, it is possible to prevent one reserved ball of the other special symbol from being used up in vain. In addition, in this case, when the lottery result of the other special symbol is a jackpot, the other special symbol will not be forcibly stopped changing due to a losing symbol immediately after the end of the jackpot game of one special symbol, so at the same time. It is possible to suppress a decrease in interest in games with respect to variable functions.

In addition, in this embodiment, when the fluctuating display of one special symbol ends with a jackpot symbol and the time when the fluctuation of the other special symbol starts (at the time of winning a prize) overlaps, the other special symbol does not start fluctuating. Although an example in which control is performed has been described, the present invention is not limited to this. In addition to cases where the fluctuating display of one special symbol ends with a jackpot symbol and the start of fluctuating (winning) the other special symbol, as shown in Figure 165B, Whether the timing of the fluctuation start is during the period from when the fluctuation display of one special symbol ends with the jackpot symbol (t1 in FIG. 165B) to a predetermined time (Δt=t1-t0 in FIG. 165B). For example, the special symbol suspension flag of the other special symbol may be internally set to an on state to prevent the other special symbol from starting to fluctuate. In this case as well, the same effects as in this embodiment can be obtained. Note that the period (Δt=t1-t0) from when the variable display of one special symbol ends with the jackpot symbol (t1) to a predetermined time before can be set as appropriate.

<Configuration of special design work area table and special design related definition data table>
Next, the configuration of each special symbol work area table and each special symbol related definition data table provided in the main RAM 6103 will be explained with reference to FIGS. 166 to 169. Note that FIG. 166 is a configuration diagram of the first special symbol work area table, and FIG. 167 is a configuration diagram of the first special symbol related definition data table. Further, FIG. 168 is a configuration diagram of the second special symbol work area table, and FIG. 169 is a configuration diagram of the second special symbol related definition data table.

[First special design work area table]
The first special symbol work area table stores various information used in various control processes (various modules) for variable display of the first special symbol.

Specifically, as shown in FIG. 166, the first special symbol work area table includes, as storage areas, a first special symbol control state number area, a first special symbol per flag area, and a first special symbol reservation number area. , 1st special symbol gaming state number area, 1st special symbol number area, 1st special symbol demo display status flag area, 1st special symbol gaming state transition offset area, 1st special symbol waiting time management timer area, 1st special A symbol pause flag area, a first special symbol game state designation parameter area, a first special symbol effect variation table parameter area, and a first special symbol stop symbol management number parameter area are provided, and these storage areas are used for the first special symbol work. They are arranged in this order from the start address ("W_T1_YY00") side of the area table. In addition, in the first special symbol work area table, as shown in FIG. 166, the address of each storage area is defined by an offset value (relative value) from the top address of the first special symbol work area table.

In the first special symbol working area table, the first special symbol waiting time management timer area is composed of a 4-byte area, and each other storage area is composed of a 1-byte area.

In addition, in the first special symbol winning flag area in the first special symbol work area table, there is information indicating the result (jackpot or loss) of the jackpot lottery (first special symbol lottery) performed at the time of winning the first starting opening. Stored. In addition, the value (on value/off value) of the special symbol halt flag of the first special symbol used in processing control at the time of simultaneous fluctuation is stored in the first special symbol halt flag area.

In addition, in the first special symbol waiting time management timer area, on the address, the upper 2-byte area (starting address side) constitutes one timer, and the lower 2-byte area constitutes one timer. In this specification, the former is referred to as the upper 2-byte timer, and the latter is referred to as the lower 2-byte timer. Each 2-byte timer is managed separately, and each 2-byte area stores the count value of the timer.

In the pachinko gaming machine 6001 of this embodiment, the variable display time (special symbol waiting time) of the special symbols (first and second special symbols) is divided into a first half variable display time and a second half variable display time, and each variation is divided into a first half variable display time and a second half variable display time. Each display time is managed separately using a 2-byte timer. Specifically, in this embodiment, the variable display time of the first half of the special symbol (special symbol waiting time) is managed by the upper 2 byte timer, and the variable display time of the latter half of the special symbol (special symbol waiting time) is managed by the lower 2 byte timer. Manage with byte timer. However, the present invention is not limited to this, and the variable display time of the first half of the special symbol may be managed by the lower 2-byte timer, and the variable display time of the latter half of the special symbol may be managed by the upper 2-byte timer.

In addition, in this embodiment, in the control process of the first special symbol, various monitoring times other than the variable display time (special symbol waiting time) of the first special symbol are set in the upper two byte timer of the first special symbol. Ru. For example, as described below, the interval time until the start of the jackpot game (special symbol per start display time described below), the interval time until the end of the jackpot game (the special symbol per end display time described later), the confirmation waiting time for a specific symbol, The inter-round display time, etc. are set in the upper 2 byte timer. Note that the present invention is not limited to this, and a configuration may be adopted in which these monitoring times other than the variable display time (special symbol waiting time) are set in the lower 2 byte timer.

Furthermore, in this embodiment, an example has been described in which two timers (upper 2 byte timer and lower 2 byte timer) are both configured with 2 bytes, but the present invention is not limited to this. The configuration of the two timers can be arbitrarily set depending on the nature and the like. For example, each timer may be configured with a number of bytes other than 2 bytes, or the two timers may be configured with different numbers of bytes.

Furthermore, in this embodiment, an example has been described in which the variable display time of the special symbol is divided into the first half and the second half, and each time is managed by the upper 2 byte timer and the lower 2 byte timer. but not limited to. The periods managed by the upper 2-byte timer and the lower 2-byte timer may be different from each other. For example, the upper 2-byte timer manages the period from the start of the variable display time of the special symbol to the time that can be counted by the 2-byte timer, and after the upper 2-byte timer finishes counting, the lower 2-byte timer manages the remaining period. It can be managed by

Furthermore, in this embodiment, even for a predetermined monitoring time other than the variable display time of the special symbol, if that time is a long period of time (a period that cannot be counted by a 2-byte timer), the monitoring time The monitoring time may be divided into two, and the divided monitoring time may be managed by an upper 2-byte timer and a lower 2-byte timer, respectively.

By providing the timer with the above-described configuration, for example, the following effects can be obtained.

In this embodiment, the system cycle time (gaming control related processing cycle) is 6 msec, so the period that can be monitored with a 2-byte timer is 65536 x 6 msec, and if a longer period of time is to be monitored, 4 A byte timer is required. For example, if the entire variable display time of special symbols (special symbol waiting time) is a long time of about 10 minutes, a 4-byte timer is required. However, if you use a 4-byte timer to monitor times that can be monitored with a 2-byte timer, such as the overall variable display time of short-term special symbols or the interval time until the start of a jackpot game, the 4-byte timer will Of the timer area, the upper 2 bytes of the timer area are unused, which is not efficient.

On the other hand, as in this embodiment, the 4-byte timer is configured with two separate 2-byte timers, and the first-half variable display time and the second-half variable display time of the special symbol are separately (independently) ) If you configure the system to be managed using a 2-byte timer, both 2-byte timers will be used even if the overall variable display time of the special symbol is short, so there will be no unused timers. . Furthermore, in the configuration of this embodiment, one of the 2-byte timers is used to monitor a short period of time, such as an interval time until the start of a jackpot game. Therefore, with the timer configuration of this embodiment, various monitoring times can be managed using the timer area efficiently. That is, with the timer configuration of this embodiment, various processes performed by the main control circuit 6100 can be efficiently executed, and the processing load on the main control circuit 6100 can be reduced.

Also, for example, if two 2-byte timers are installed to monitor the short-term fluctuating display time of special symbols or the interval time until the start of a jackpot game, one 2-byte timer is used to monitor the long-term display time. When monitoring the variable display time of the special symbol, a method of monitoring by adding up the count value of the upper 2 byte timer and the count value of the lower 2 byte timer can also be considered. However, as in this embodiment, the 4-byte timer is configured with two separate 2-byte timers, and the first half variable display time and the second half variable display time of the special symbol are each separately (independently) 2 bytes long. If the configuration is such that the timer is used for management, there is no need to add up the count value of the upper 2-byte timer and the count value of the lower 2-byte timer. In this case, since the process of adding up the count values of the timers can be omitted, the capacity of the processing program managed by the main control circuit 6100 can be reduced. In this embodiment, an example in which two timers are used to manage various times has been described, but the present invention is not limited to this, and may be configured to manage various times with one timer.

[First special symbol related definition data table]
The first special symbol related definition data table (index table) contains various information (storage area, data area, constant definition value address) are stored. Therefore, in various control processes for the variable display of the first special symbol, desired information can be directly read from the main RAM 6103 by referring to the various addresses defined in the first special symbol related definition data table. . Note that the index table here may be any information storage body in which reference information is stored, and may be a structure or a collection of variables.

As shown in FIG. 167, the first special symbol related definition data table includes a storage area for the first special symbol selection value (“0” in this embodiment), and a storage area for the second special symbol in the second special symbol work area table. Storage area for the address of the hit flag area (lower address), storage area for the address of the second special symbol pause flag area in the second special symbol work area table, start address (lower address) of the first special symbol reservation storage area ) storage area, storage area for the address (lower address) of the first special symbol retention memory read pointer area, storage area for the address (lower address) of the first special symbol retention memory write pointer area, first special symbol work Storage area for the start address of the first special symbol waiting time management timer area in the area table, storage area for the address of the first special symbol gaming state specification parameter area in the first special symbol work area table, second special symbol work area Storage area for the start address of the table, storage area for the start address of the first special symbol fluctuation start setting data table, storage area for the start address of the first special symbol confirmation setting data table 1, storage area for the start address of the first special symbol confirmation setting data table 2, A storage area for the start address, a storage area for the start address of the first special symbol game end setting data table, and a storage area for the start address of the second special symbol related definition data table are provided. They are arranged in this order from the top address (“D_T1_XX00”) side of the special symbol related definition data table. In addition, in the first special symbol-related definition data table, as shown in FIG. 167, the address of each storage area is defined by an offset value (relative value) from the top address of the first special symbol-related definition data table. There is.

In addition, in the first special symbol related definition data table, there is a storage area for the first special symbol selection value (0), and a storage area for the address (lower side address) of the second special symbol per flag area in the second special symbol work area table. area, a storage area for the start address (lower address) of the first special symbol retention storage area, a storage area for the address (lower address) of the first special symbol retention storage read pointer area, and a first special symbol retention storage write area. The storage areas for addresses (lower addresses) in the pointer area each consist of a 1-byte area, and each of the other storage areas consists of a 2-byte area.

As described above, the first special symbol related definition data table collectively stores address information of various types of information necessary for the control process of the variable display of the first special symbol. For example, as shown in FIG. 167, the first special symbol related definition data table includes the addresses of the first special symbol waiting time management timer area and the first special symbol gaming state specification parameter area in the first special symbol work area table. is stored. Therefore, in this embodiment, in various control processes for the variable display of the first special symbol, by setting the address of the first special symbol related definition data table in the IX register etc. in advance, the first special symbol related definition data table The information stored in each storage area in the main RAM 6103 can be directly called from the work area of the main RAM 6103.

That is, by providing the first special symbol-related definition data table having the above configuration, when reading necessary information from the work area of the main RAM 6103, the process of referring to the address data of the information stored in the work area is omitted. be able to. In this case, in various control processes for the variable display of the first special symbol, when reading necessary information, an instruction code for referring to the address data of the information is not required. Therefore, when the first special symbol related definition data table having the above configuration is provided, the capacity of the processing program managed by the main control circuit 6100 can be reduced.

In addition, the first special symbol related definition data table includes, as shown in FIG. 167, the start address of the second special symbol work area table, the second special symbol per flag area in the second special symbol work area table, and the second The address of the special symbol pause flag area is stored. When such a configuration is provided, information on the second special symbol hit flag and second special symbol suspension flag in the second special symbol work area table is required in various control processes for the variable display of the first special symbol. In this case, special symbol related definition data table switching processing (processing of switching the address of the first special symbol related definition data table set in advance in the IX register etc. to the address of the second special symbol related definition data table) is performed. Information on the second special symbol hit flag and second special symbol pause flag can be directly read out from the second special symbol work area table using the first special symbol related definition data table without having to do so.

In this case, in various control processes of the variable display of the first special symbol, an instruction code for executing the switching process of the special symbol related definition data table is not required. Therefore, when the first special symbol related definition data table having the above configuration is provided, the capacity of the processing program managed by the main control circuit 6100 can be further reduced.

Furthermore, the storage area (the last storage area) for the last two bytes (the final address and the address immediately before it) of the first special symbol-related definition data table is stored at the beginning of the second special symbol-related definition data table. Address is stored. Further, as will be described later, the first address of the first special symbol-related definition data table is stored in the last 2-byte storage area of the second special symbol-related definition data table (see FIG. 169, which will be described later). When such a configuration is provided, mutual access is possible between the first special symbol related definition data table and the second special symbol related definition data table, and processing at the time of simultaneous fluctuation can be executed more efficiently. , the processing load on the main control circuit 6100 can be further reduced.

[Second special design work area table]
The second special symbol work area table stores various information used in various control processes (various modules) for variable display of the second special symbol.

Specifically, as shown in FIG. 168, the second special symbol work area table includes, as storage areas, a second special symbol control state number area, a second special symbol per flag area, and a second special symbol pending number area. , 2nd special symbol gaming state number area, 2nd special symbol number area, 2nd special symbol demo display status flag area, 2nd special symbol gaming state transition offset area, 2nd special symbol waiting time management timer area, 2nd special A symbol pause flag area, a second special symbol game state designation parameter area, a second special symbol effect variation table parameter area, and a second special symbol stop symbol management number parameter area are provided, and these storage areas are used for the second special symbol work. They are arranged in this order starting from the first address ("W_T2_YY00") of the area table. In addition, in FIG. 168, for convenience of explanation, the illustration of the offset value from the start address of each storage area in the second special symbol work area table is omitted, but in the second special symbol work area table, each storage area The address of the area is defined by an offset value (relative value) from the top address of the second special symbol work area table.

In addition, in the second special symbol work area table, the second special symbol waiting time management timer area is composed of a 4-byte area, and each other storage area is composed of a 1-byte area. That is, the configuration of the second special symbol work area table (type of stored information, storage order, size of each storage area) is the same as that of the first special symbol work area table.

In addition, the result (big hit, small hit, or loss) of the jackpot lottery (second special symbol lottery) held at the time of winning the second starting opening is shown in the second special symbol winning flag area in the second special symbol work area table. The information shown is stored. In addition, the value (on value/off value) of the special symbol halt flag of the second special symbol used in processing control at the time of simultaneous fluctuation is stored in the second special symbol halt flag area.

Also, the second special symbol waiting time management timer area (4-byte area) is composed of an upper 2-byte timer and a lower 2-byte timer, similar to the first special symbol management timer area.

In this embodiment, the first half variable display time of the second special symbol is managed by the upper 2 byte timer, and the second half variable display time of the second special symbol is managed by the lower 2 byte timer. In addition, in the present embodiment, in the control process of the second special symbol, the monitoring time other than the variable display time (special symbol waiting time) of the second special symbol (for example, the interval time until the start of the jackpot game, the interval time until the end of the jackpot game) (interval time, specific symbol waiting time, inter-round display time, etc.) are managed by the upper 2 byte timer of the second special symbol, but the configuration may be such that these monitoring times are managed by the lower 2 byte timer.

As described above, in this embodiment, the timer configuration and monitoring time management method for the second special symbol are the same as those for the first special symbol. Therefore, by adopting the timer configuration and monitoring time management method of the second special symbol, the same effects as those obtained by the timer configuration and monitoring time management method of the first special symbol can be obtained. It will be done.

[Second special symbol related definition data table]
The second special symbol related definition data table contains various information (storage area, data area, constant address of the defined value) is stored. Therefore, in various control processes for the variable display of the second special symbol, desired information can be directly read from the main RAM 6103 by referring to the various addresses defined in the second special symbol related definition data table. .

As shown in FIG. 169, the second special symbol related definition data table includes a storage area for the second special symbol selection value (“1” in this embodiment), and a storage area for the first special symbol in the first special symbol work area table. A storage area for the address of the hit flag area (lower address), a storage area for the address of the first special symbol suspension flag area in the first special symbol work area table, a storage area for the address of the second special symbol reservation storage area (lower address) ) storage area, storage area for the address (lower address) of the second special symbol retention memory read pointer area, storage area for the address (lower address) of the second special symbol retention memory write pointer area, second special symbol work Storage area for the start address of the second special symbol waiting time management timer area in the area table, storage area for the address of the second special symbol gaming state specification parameter area in the second special symbol work area table, first special symbol work area Storage area for the start address of the table, storage area for the start address of the second special symbol fluctuation start setting data table, storage area for the start address of the second special symbol confirmation setting data table 1, storage area for the start address of the second special symbol confirmation setting data table 2, A storage area for the start address, a storage area for the start address of the second special symbol game end setting data table, and a storage area for the start address of the first special symbol related definition data table are provided. They are arranged in this order from the top address (“D_T2_XX00”) side of the special symbol related definition data table. In addition, in FIG. 169, for convenience of explanation, the illustration of the offset value from the start address of each storage area in the second special symbol-related definition data table is omitted; however, in the second special symbol-related definition data table, The address of each storage area is defined by an offset value (relative value) from the top address of the second special symbol related definition data table.

In addition, in the second special symbol related definition data table, a storage area for the second special symbol selection value, a storage area for the address (lower side address) of the first special symbol per flag area in the first special symbol work area table, A storage area for the start address (lower address) of the 2nd special symbol retention storage area, a storage area for the address (lower address) of the 2nd special symbol retention storage read pointer area, and a storage area for the 2nd special symbol retention storage write pointer area. Each storage area for addresses (lower addresses) consists of a 1-byte area, and each other storage area consists of a 2-byte area. That is, the configuration of the second special symbol-related definition data table (type of stored information, storage order, size of each storage area) is the same as that of the first special symbol-related definition data table.

As described above, the second special symbol related definition data table collectively stores the address information of various information necessary for the control process of the variable display of the second special symbol. For example, as shown in FIG. 169, the second special symbol related definition data table includes the addresses of the second special symbol waiting time management timer area and the second special symbol gaming state specification parameter area in the second special symbol work area table. is stored. Therefore, in this embodiment, in various control processes for the variable display of the second special symbol, by setting the address of the second special symbol related definition data table in the IX register etc. in advance, the second special symbol related definition data table The information stored in each storage area in the main RAM 6103 can be directly called from the work area of the main RAM 6103.

That is, by providing the second special symbol-related definition data table having the above configuration, when reading necessary information from the work area of the main RAM 6103, the process of referring to the address data of the information stored in the work area can be omitted. be able to. In this case, in various control processes for the variable display of the second special symbol, when reading necessary information, an instruction code for referring to the address data of the information becomes unnecessary. Therefore, when the second special symbol related definition data table having the above configuration is provided, the capacity of the processing program managed by the main control circuit 6100 can be reduced.

In addition, the second special symbol related definition data table includes, as shown in FIG. 169, the start address of the first special symbol work area table, the first special symbol per flag area in the first special symbol work area table, and the first The address of the special symbol pause flag area is stored. When such a configuration is provided, information on the first special symbol hit flag and first special symbol pause flag in the first special symbol work area table is required in various control processes for the variable display of the second special symbol. In this case, special symbol related definition data table switching processing (processing of switching the address of the second special symbol related definition data table set in advance in the IX register etc. to the address of the first special symbol related definition data table) is performed. Information on the first special symbol hit flag and the first special symbol suspension flag can be directly read from the first special symbol work area table using the second special symbol related definition data table without having to do so.

In this case, in various control processes of the variable display of the second special symbol, an instruction code for executing the switching process of the special symbol related definition data table is not required. Therefore, when the second special symbol related definition data table having the above configuration is provided, the capacity of the processing program managed by the main control circuit 6100 can be further reduced.

Furthermore, the storage area (the last storage area) for the last 2 bytes (the final address and the address immediately before it) of the second special symbol-related definition data table is stored at the beginning of the first special symbol-related definition data table. Address is stored. Furthermore, as described above, the first address of the second special symbol-related definition data table is stored in the last 2-byte storage area of the first special symbol-related definition data table (see FIG. 167). When such a configuration is provided, mutual access is possible between the first special symbol related definition data table and the second special symbol related definition data table, and processing at the time of simultaneous fluctuation can be executed more efficiently. , the processing load on the main control circuit 6100 can be further reduced.

[Various variations of special design work area table]
(1) Modification example 1
As described above, in this embodiment, the configuration of the first special symbol work area table (type of stored information, storage order, size of each storage area) and the configuration of the second special symbol work area table are different from each other. Although the same example has been described, the present invention is not limited thereto. For example, the configuration of the first special symbol work area table and the configuration of the second special symbol work area table may be different from each other.

In addition, as in the present embodiment, if the configuration of the first special symbol work area table and the configuration of the second special symbol work area table are the same, then The offset value of the address to the storage area of the information of the predetermined item is the same as the offset value of the address from the head address of the second special symbol work area table to the storage area of the information of the predetermined item. In this case, the offset value setting process when reading information on predetermined items from each special symbol work table can be shared, and the capacity of the processing program managed by the main control circuit 6100 can be further reduced.

However, for example, if the number of information items (number of types) stored in each special symbol work area table is different from each other, the address from the first address of the first special symbol work area table to the storage area of the information of the predetermined item There is a possibility that a situation may occur in which the offset value is different from the offset value of the address from the top address of the second special symbol work area table to the storage area of the information of the predetermined item. In this case, an offset value setting process when reading information on a predetermined item from the first special symbol work area table, and an offset value setting process when reading information on a predetermined item from the second special symbol work area table. It is necessary to provide a separate program, which may increase the capacity of the processing program.

A modification of the special symbol work area table for solving such problems is shown in FIG. 170. FIG. 170 is a diagram showing the configuration of the first special symbol work area table in Modification 1.

Note that the items (types) of storage areas provided in the first special symbol work area table in this example, the arrangement order, and the size of each storage area are the same as the configuration of this embodiment shown in FIG. 166. Although not shown, in this example, the configuration after the first special symbol game state specification parameter area (final address side) in the first special symbol work area table and the second special symbol in the second special symbol work area table The configuration after the symbol gaming state specification parameter area is the same, and the configuration on the first address side from the first special symbol gaming state specification parameter area in the first special symbol work area table is the same as the configuration after the symbol gaming state specification parameter area. 2. The configuration is different from that on the start address side of the special symbol gaming state designation parameter area.

In this example, in the first special symbol work area table, the start address ("W_T1_YY0A") of the first special symbol work area table is defined as the first start address (start address A), and the first special symbol game The address immediately before (upper side) of the state specification parameter area ("W_T1_YY0B") is defined as the second start address (start address B). Then, as shown in FIG. 170, the respective addresses are assigned to the first special symbol gaming state specification parameter area, the first special symbol effect variation table parameter area, and the first special symbol stop symbol management number parameter area, and the starting address is Two types of offset values are defined: an offset value from A and an offset value from the start address B.

Although not shown, in this example, the first address ("W_T2_YY0C") of the second special symbol work area table is also defined as the first address (first address C) in the second special symbol work area table. In both cases, the address ("W_T2_YY0D") immediately before (upper side) of the second special symbol game state designation parameter area is defined as the second start address (start address D). Then, input the respective addresses to the second special symbol game state specification parameter area, the second special symbol effect variation table parameter area, and the second special symbol stop symbol management number parameter area, and the offset value from the start address C and the start address. It is defined by two types of offset values from address D.

When the configuration of this example is adopted as the configuration of the first special symbol work area table and the second special symbol work area table, each item after the first special symbol game state specification parameter area in the first special symbol work area table The offset value from the head address B of the storage area is the same as the offset value from the head address D of the storage area of each item after the second special symbol game state designation parameter area in the second special symbol work area table. In this case, by using the start address B and the start address D as the reference for the offset value, the offset value setting process when reading the information after the first special symbol game state specification parameter area from the first special symbol work area table. , it is possible to share the offset value setting process when reading information after the second special symbol game state designation parameter area from the second special symbol work area table. Furthermore, in this case, the process of reading out the information after the first special symbol gaming state specification parameter area and the process of reading out the information after the second special symbol gaming state specification parameter area can be made common. Therefore, when the above configurations of the first special symbol work area table and the second special symbol work area table in this example are adopted, the processing program managed by the main control circuit 6100 even if the two table configurations are different from each other. capacity can be reduced.

(2) Modification 2
In this embodiment, the first special symbol working area table defines only information regarding the first special symbol, and the second special symbol working area table defines only information regarding the second special symbol. However, the present invention is not limited thereto. At least a part of the information regarding the other special symbol is defined in one special symbol work area table, and the storage position of the information regarding the other special symbol stored in one special symbol work area table is set in one of the same items. It may be a position (next storage address) one level lower than the storage position (storage address) of information regarding the special symbol.

For example, a second special symbol flag area is provided at the next (one level lower) address of the first special symbol flag area in the first special symbol work area table shown in FIG. It may be configured such that the first special symbol flag area is provided at the next (one level lower) address of the second special symbol flag area in the symbol work area table.

In this case, in the control process of the variable display of the first special symbol, when referring to the first special symbol per flag (its own information), the first special symbol work area table is When reading the 1 special symbol per flag and referring to the 2nd special symbol per flag (opponent's information), add 1 (+1) to the address and read the 2nd special symbol from the 1st special symbol work area table. Read out the symbol hit flag. On the other hand, in the process of controlling the variable display of the second special symbol, when referring to the second special symbol per flag (its own information), the second special symbol is displayed from the second special symbol work area table without correcting the address. When reading the special symbol per flag and referring to the first special symbol per flag (opponent's information), add 1 (+1) to the address and read the first special symbol from the second special symbol work area table. Read the hit flag.

That is, in this example, in the control process of the variable display of the first special symbol, information regarding the first special symbol (own information) or information regarding the second special symbol (opponent's information) is obtained from the first special symbol work area table. In the reading process (address setting process) and the control process for variable display of the second special symbol, information regarding the second special symbol (own information) or information regarding the first special symbol is obtained from the second special symbol work area table. Since the process (address setting process) when reading (other party's information) is the same, both processes can be shared. Therefore, when the configuration of the special symbol work area table of this example is adopted, the capacity of the processing program managed by the main control circuit 6100 can be reduced.

(3) Modification example 3
In this embodiment, the first special symbol work area table defines only information regarding the first special symbol, and the second special symbol work area table defines only information regarding the second special symbol. However, the present invention is not limited thereto.

For example, similar to the first special symbol related definition data table (see FIG. 167) and the second special symbol related definition data table (see FIG. 169) of this embodiment, the last 2 bytes of the first special symbol work area table The start address of the second special symbol work area table is stored in the storage area (last storage area) of (the final address and the address immediately before it), and the last 2 bytes of the second special symbol work area table are stored. The configuration may be such that the first address of the first special symbol work area table is stored in the storage area. When such a configuration is provided, mutual access is possible between the first special symbol work area table and the second special symbol work area table, and processing at the time of simultaneous fluctuation can be executed more efficiently. , the processing load on the main control circuit 6100 can be further reduced.

In addition, in this invention, you may make the structure of the 1st special symbol work area table and the 2nd special symbol work area table into the structure which combined the said modification 2 and the said modification 3, for example. In this case as well, the same effects as those obtained in Modifications 2 and 3 can be obtained.

[Modified example of special design related definition data table]
As described above, in this embodiment, an example in which the first special symbol-related definition data table and the second special symbol-related definition data table are provided separately has been described, but the present invention is not limited to this. For example, the first special symbol related definition data table and the second special symbol related definition data table may be configured as one special symbol related definition data table (index table). In addition, also in such a structure, within the special symbol related definition data table, the address of each storage area can be defined by an offset value (relative value) from the top address of the special symbol related definition data table.

In this case, the data for mutual access (the other party's (start address of the special symbol-related definition data table) becomes unnecessary, and the capacity of data managed by the main control circuit 6100 can be further reduced.

In addition, as will be described later, when performing processing on the first special symbol in the control process of the variable display of special symbols, the first address of the first special symbol related definition data table is set in the IX register, and the second special symbol is When processing a symbol, the start address of the second special symbol-related definition data table is set in the IX register. That is, in the control process of the variable display of special symbols, the process of setting the start address of the special symbol-related definition data table to the IX register is switched depending on the type of special symbol to be processed. However, if the first special symbol-related definition data table and the second special symbol-related definition data table are configured as one special symbol-related definition data table, the special symbol-related definition data There is no need to switch the process of setting the start address of the table to the IX register, and the capacity of the processing program managed by the main control circuit 6100 can be further reduced.

<Operation explanation of main control circuit>
Next, the contents of various processes (various modules) executed by the main CPU 6101 of the main control circuit 6100 will be explained with reference to FIGS. 171 to 204.

[External maskable interrupt processing]
First, with reference to FIG. 171, the external maskable interrupt processing executed under the control of the main CPU 6101 will be described. This process is an interrupt process that is performed in response to an external interrupt request that occurs, for example, during a power outage. Note that FIG. 171 is a flowchart showing the procedure of external maskable interrupt processing.

First, the main CPU 6101 performs protection register saving processing (S6001). The protection registers to be saved in this process are accumulators A and A', flag registers F and F', pair registers BC and B'C', pair registers DE and D'E', and pair registers HL and H. 'L', IX register and IY register.

Next, the main CPU 6101 reads the status of input port 2 (S6002).

The main control circuit 6100 is provided with three types of input ports: input port 0, input port 1, and input port 2. Input port 0 sets the on/off state of each starting opening winning ball switch, setting key 6080, out ball count switch (not shown), etc. At the input port 1, the on/off states of count switches 6053c, 6054c, general winning ball switches 6051a, 6052a, big prize opening switch, ejection opening switch, passing ball switch 6043a, etc. are set. Further, in the input port 2, the on/off states of a power cut signal, RAM clear switch 6121, sensor abnormality detection signal, frame radio wave sensor, open signal, magnetic sensor, vibration sensor, solenoid monitoring sensor, etc. are set.

Next, the main CPU 6101 determines whether a power outage signal is being detected (S6003).

If the main CPU 6101 determines in S6003 that a power outage signal is not being detected (NO determination in S6003), the main CPU 6101 performs processing in S6005, which will be described later. On the other hand, if the main CPU 6101 determines in S6003 that a power outage signal is being detected (YES in S6003), the main CPU 6101 sets the XINT detection flag to the on state (on value) (S6004) . Note that the XINT detection flag is a flag indicating whether or not power is being cut off, and its value is stored in the XINT detection flag area in the work area of the main RAM 6103.

After the process in S6004, or if the determination in S6003 is NO, the main CPU 6101 performs a process to restore the protection register saved in S6001 (S6005). Next, the main CPU 6101 performs interrupt permission processing (S6006), and ends the external maskable interrupt processing.

[System timer interrupt processing]
Next, with reference to FIG. 172, system timer interrupt processing executed at a 2 msec cycle (interrupt cycle) under the control of the main CPU 6101 will be described. Note that FIG. 172 is a flowchart showing the procedure of system timer interrupt processing.

First, the main CPU 6101 performs protection register saving processing (S6011). The protection registers to be saved in this process are accumulators A and A', flag registers F and F', pair registers BC and B'C', pair registers DE and D'E', and pair registers HL and H. 'L', IX register and IY register.

Next, the main CPU 6101 determines whether the XINT detection flag is in the on state (S6012).

In S6012, if the main CPU 6101 determines that the XINT detection flag is in the on state (when a power outage is detected) (YES in S6012), the main CPU 6101 performs processing in S6026, which will be described later. On the other hand, if the main CPU 6101 determines in S6012 that the XINT detection flag is not on (NO in S6012), the main CPU 6101 performs interrupt permission processing (S6013).

Next, the main CPU 6101 performs processing to read the state of the input port (S6014).

Next, the main CPU 6101 determines whether or not the game is permitted (S6015). In this process, the main CPU 6101 determines whether or not the game is allowed to play based on the value of the activation control flag (activation state).

Note that the startup control flag is a flag for determining the type of startup state, such as power failure recovery, setting change, setting confirmation, RAM clear, etc., and is stored in the startup control flag area in the main RAM 6103. The value of the startup control flag is the state information of the RAM clear switch 6121 (on value (Low) or off value (High): operation information) when the power is turned on, and the state information of the setting key 6080 (on value (High) or Off value (Low): operation information). In this embodiment, the type of current startup state (recovery from power failure/setting change/setting confirmation/RAM clear) is determined based on the combination of both status information (value of the startup control flag).

Specifically, when the RAM clear switch 6121 is at the off value (High) and the setting key 6080 is at the off value (Low) (for example, the value of the startup control flag = "10B"), the power is turned off. It is determined that it is time to return. When the RAM clear switch 6121 is on value (Low) and the setting key 6080 is on value (High) (for example, the value of the startup control flag = "01B"), it is determined that the settings are being changed, When the RAM clear switch 6121 is at the off value (High) and the setting key 6080 is at the on value (High) (for example, the value of the startup control flag = "11B"), it is determined that the setting is being checked. . Furthermore, when the RAM clear switch 6121 is on value (Low) and the setting key 6080 is off value (Low) (for example, the value of the startup control flag = "00B"), it is determined that the RAM is cleared. be done. In the determination process of S6015, if the value of the activation control flag is a value indicating anything other than setting change and setting confirmation, a YES determination (game permission state) is made. In addition, in this embodiment, an example has been described in which the ON value of the RAM clear switch 6121 is set to Low level and the OFF value is set to High level, but the ON value of RAM clear switch 6121 is set to High level and the OFF value is set to Low level. Good too. Furthermore, in this embodiment, an example has been described in which the on value of the setting key 6080 is set to High level and the off value is set to Low level, but the on value of setting key 6080 may be set to Low level and the off value may be set to High level. .

In S6015, if the main CPU 6101 determines that the game is not in the gaming permission state (NO in S6015), the main CPU 6101 performs setting control processing (S6016). In this process, the main CPU 6101 performs setting change processing or setting confirmation processing. That is, in this embodiment, the setting change process and the setting confirmation process are performed within the system timer interrupt process that is performed every 2 msec, and are performed when the game is not permitted. Note that details of the setting control process will be described later with reference to FIG. 173, which will be described later. After processing in S6016, the main CPU 6101 performs processing in S6026, which will be described later.

On the other hand, if the main CPU 6101 determines in S6015 that the game is allowed (YES in S6015), the main CPU 6101 increments the value of the interrupt counter by 1 (S6017). Note that the interrupt counter is a counter for counting (managing) interrupt prohibition periods during main control main processing (see FIGS. 182 to 185 described later), and the count value of the interrupt counter is based on the work of the main RAM 6103. Stored in the interrupt counter area within the area.

Next, the main CPU 6101 performs update processing of the interrupt cycle timer (S6018). Note that the interrupt cycle timer is a timer for managing interrupt cycles (2 msec), and the count value of the interrupt cycle timer is stored in the interrupt cycle management timer area in the work area of the main RAM 6103.

Next, the main CPU 6101 performs updating processing of various random numbers (S6019). Next, the main CPU 6101 performs switch input detection processing (S6020). Note that details of the switch input detection process will be described later with reference to FIG. 178, which will be described later.

Next, the main CPU 6101 performs winning information command setting processing (S6021). In this process, the main CPU 6101 performs a transmission reservation process of an effect control command (winning information command).

Next, the main CPU 6101 performs production control command transmission processing (S6022). In this process, the main CPU 6101 transmits the command reserved for transmission from the main control circuit 6100 to the sub control circuit 6200.

Next, the main CPU 6101 performs register saving processing (S6023). Note that the registers to be saved in this process are accumulators A and A' and flag registers F and F'.

Next, the main CPU 6101 performs control processing for the performance display monitor 6070 (S6024). In this process, the main CPU 6101 performs a game determination process, a prize ball addition determination process, a process for updating the display content of the performance display monitor 6070, and the like. Further, this processing is performed using an extra-area work area in the main RAM 6103. Next, the main CPU 6101 performs restoration processing for the registers saved in S6023 (S6025).

After the processing in S6025 or S6016, or if the determination in S6012 is YES, the main CPU 6101 performs processing to restore the protection register saved in S6011 (S6026), and ends the system timer interrupt processing.

As described above, in the system timer interrupt processing of this embodiment, when the current startup state is the gaming disallowed state (NO in S6015), the setting control processing (setting change processing or setting confirmation processing) is executed. and does not perform various processes (for example, interrupt cycle timer update process (S6018), random value update process (S6019), performance display monitor 6070 control process (S6024), etc.) that are executed in the game permission state. In this case, unnecessary processing can be prevented from being performed when the game is not permitted, and the processing can be simplified. Therefore, by performing the above-described processing in the system timer interrupt processing, the processing performed by the main control circuit 6100 can be executed more efficiently, and the processing load on the main control circuit 6100 can be reduced.

Further, as described above, in this embodiment, the type of the current startup state is determined using the startup control flag configured by the combination of the state information of the RAM clear switch 6121 and the state information of the setting key 6080 when the power is turned on. (Power loss recovery/setting change/setting confirmation/RAM clear) can be determined. In other words, the type of startup state (recovery from power failure/setting change/setting confirmation/RAM clear) can be determined using a common flag (there is no need to provide a determination flag for each type of startup state), so this In the embodiment, the amount of data managed by the main control circuit 6100 can be further reduced.

[Setting control processing]
Next, with reference to FIG. 173, the setting control process performed in S6016 during the system timer interrupt process (see FIG. 172) will be described. Note that FIG. 173 is a flowchart showing the procedure of the setting control process.

First, the main CPU 6101 determines whether the value of the activation control flag is a value indicating a setting change (S6031).

In S6031, if the main CPU 6101 determines that the value of the startup control flag is a value indicating a setting change (YES in S6031), the main CPU 6101 performs a setting change process (S6032). Note that details of the setting change process will be described later with reference to FIG. 174, which will be described later.

On the other hand, if the main CPU 6101 determines in S6031 that the value of the startup control flag is not a value indicating a setting change (NO determination in S6031), the main CPU 6101 performs a setting confirmation process (S6033). Note that details of the setting confirmation process will be described later with reference to FIG. 175, which will be described later.

After the processing in S6032 or S6033, the main CPU 6101 performs setting operation display processing (S6034). In this process, currently set setting values are displayed.

Next, the main CPU 6101 performs production control command transmission processing (S6035). In this process, the main CPU 6101 transmits to the sub control circuit 6200 a command (initialization command or power failure recovery command) reserved for transmission in the setting change process (S6032) or the setting confirmation process (S6033).

Next, the main CPU 6101 performs output processing of a WDT (watchdog timer) (S6036). In this process, the main CPU 6101 performs a process of reading the WDT clear register address, a process of clearing the built-in WDT, and a process of restarting the built-in WDT in this order. After the processing in S6036, the main CPU 6101 ends the setting control processing and returns the processing to the processing in S6026 of the system timer interrupt processing (FIG. 172).

[Settings change process]
Next, with reference to FIG. 174, the setting change process performed in S6032 in the setting control process (see FIG. 173) will be described. Note that FIG. 174 is a flowchart showing the procedure of the setting change process.

First, the main CPU 6101 determines whether the RAM clear switch 6121 has been pressed (S6041). This determination process is performed based on the information on the on/off state of the RAM clear switch 6121 included in the information on the various input ports that has been read.

If the main CPU 6101 determines in S6041 that the RAM clear switch 6121 is not pressed (NO determination in S6041), the main CPU 6101 performs processing in S6043, which will be described later. On the other hand, if the main CPU 6101 determines in S6041 that the RAM clear switch 6121 is pressed (YES in S6041), the main CPU 6101 performs a set value within-range update process (S6042).

After the processing in S6042, or if the determination in S6041 is NO, the main CPU 6101 determines whether the setting key 6080 is turned off (S6043). In this process, the main CPU 6101 uses the on/off information of the setting key 6080 included in the input port information read in the current system timer interrupt process and the input port information read in the previous system timer interrupt process. The included on/off information of the setting key 6080 is compared (masked by exclusive OR operation), and based on the comparison result, it is determined whether or not the state of the setting key 6080 has changed from the on state to the off state. , it is determined whether an off edge of the setting key 6080 is detected.

Note that the setting control processing is executed by detecting the on edge of the setting key 6080 (when the state of the setting key 6080 changes from the off state to the on state), but in this case also, the current system timer interrupt processing The on/off information of the setting key 6080 read in is compared with the on/off information of the setting key 6080 read in the previous system timer interrupt processing (masked by exclusive OR operation), and the comparison result is Based on this, the on-edge of the setting key 6080 is detected. That is, in this embodiment, when detecting the off edge and on edge of the setting key 6080, the on/off information of the setting key 6080 read in the current system timer interrupt processing and the setting key read in the previous system timer interrupt processing are used. By using the comparison result (result of exclusive OR operation) with the on/off information of 6080 as a common flag, the start and end of the setting control process is determined.

In S6043, if the main CPU 6101 determines that the setting key 6080 is not turned off (NO in S6043), the main CPU 6101 ends the setting change process and repeats the process in the setting control process (FIG. 173). The process returns to step S6034.

On the other hand, in S6043, when the main CPU 6101 determines that the setting key 6080 is turned off (YES in S6043), the main CPU 6101 performs the first normal game pre-processing (S6044). In this process, various setting processes are performed when clearing the RAM. The details of the first normal game pre-processing will be explained later with reference to FIG. 176, which will be described later. After the process of S6044, the main CPU 6101 ends the setting change process and returns the process to S6034 of the setting control process (FIG. 173).

[Settings confirmation process]
Next, with reference to FIG. 175, the setting confirmation process performed in S6033 in the setting control process (see FIG. 173) will be described. Note that FIG. 175 is a flowchart showing the procedure of the setting confirmation process.

First, the main CPU 6101 determines whether the setting key 6080 is turned off (S6051). This determination process is performed in the same manner as the process of S6043 in the setting change process (see FIG. 174) described above.

In S6051, if the main CPU 6101 determines that the setting key 6080 is not turned off (NO in S6051), the main CPU 6101 ends the setting confirmation process and repeats the process in the setting control process (FIG. 173). The process returns to step S6034.

On the other hand, in S6051, when the main CPU 6101 determines that the setting key 6080 is turned off (YES in S6051), the main CPU 6101 performs the second normal game pre-processing (S6052). In this process, various setting processes at the time of power recovery are performed. The details of the second normal game pre-processing will be explained later with reference to FIG. 177, which will be described later. After the process of S6052, the main CPU 6101 ends the setting confirmation process and returns the process to S6034 of the setting control process (FIG. 173).

[First normal game pre-processing]
Next, with reference to FIG. 176, the first normal game pre-processing performed in S6044 during the setting change process (see FIG. 174) will be described. FIG. 176 is a flowchart showing the procedure of the first normal game pre-processing. As described later, the first normal game pre-processing performed in S6044 during the setting change process (see FIG. 174) is the game control-related process during the main control main process (see FIGS. 182 to 185 described later). In the startup initialization process (see FIG. 187 described later) that is performed before the initialization process, this process is also executed as the initialization process when clearing the RAM.

First, the main CPU 6101 performs RAM setting processing at the time of backup clearing (S6061). In this process, the main CPU 6101 loads the RAM setting data table at the time of backup clearing (when the RAM clear switch 6121 is pressed), and stores the data of this data table in a predetermined area in the main RAM 6103. Through this RAM setting process, the game is allowed to play.

Next, the main CPU 6101 performs a first special symbol address setting process (S6062). In this process, the main CPU 6101 sets the address of the first special symbol related definition data table (see FIG. 167) in the main RAM 6103 to the IX register, and sets the address of the first special symbol work area table (see FIG. 166) to the IY register. Set in register.

Next, the main CPU 6101 performs a game state designation parameter setting process (S6063). In this process, the main CPU 6101 generates various data (parameters) specifying the gaming state, and stores the generated data in a predetermined area in the first special symbol work area table (see FIG. 166). Specifically, the main CPU 6101 stores the information stored in each of the first special symbol game state number area, the first special symbol game state designation parameter, and the first special symbol performance variation table parameter area in the first special symbol work area table. Generate data (parameters) and store the generated data in the corresponding area.

Next, the main CPU 6101 performs an initialization command transmission reservation process (S6064). In addition, if the first normal game pre-processing is called by the setting change processing, the transmission of the initialization command reserved in the processing of S6064 to the sub-control circuit 6200 is performed by the setting control processing (FIG. 173). (see) is performed in the production control command transmission process (S6035). In addition, if the first normal game pre-processing is called in the startup initialization process during the main control main process (see FIG. 187 described later), the initialization command reserved in the process of S6064 is called. Transmission to the sub-control circuit 6200 is performed in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172). That is, in this embodiment, the process of transmitting an initialization command to the sub-control circuit 6200, which is performed when the RAM is cleared, is also performed when the setting change process is executed.

After the processing in S6064, the main CPU 6101 ends the first normal game pre-processing and also ends the setting change processing (FIG. 174).

[Second normal game pre-processing]
Next, with reference to FIG. 177, the second normal game pre-processing performed in S6052 during the setting confirmation process (see FIG. 175) will be described. FIG. 177 is a flowchart showing the procedure of the second normal game pre-processing. In addition, as described later, the second normal game pre-processing performed in S6052 during the setting confirmation process (see FIG. 175) is the game control-related process during the main control main process (see FIGS. 182 to 185 described later). In the startup initialization process (see FIG. 187 described later) that is performed before the initialization process, the initialization process is also performed as the initialization process when the power is restored.

First, the main CPU 6101 reads the RAM setting data table at the time of power recovery (S6071). Also, in this process, the read data is stored in a predetermined area within the main RAM 6103. Through this RAM setting process, the game is allowed to play.

Next, the main CPU 6101 determines whether the gaming state is a variable probability gaming state (high probability gaming state) (S6072). In addition, this determination process is performed based on the data (special symbol probability variation state flag value) stored in the special symbol probability variation state flag area provided in the main RAM 6103. The special symbol probability variable state flag is a flag indicating whether or not the current gaming state is a variable probability gaming state, and is set to an on state when the current gaming state is a variable probability gaming state.

In S6072, if the main CPU 6101 determines that the gaming state is not a variable probability gaming state (it is a low probability gaming state) (NO in S6072), the main CPU 6101 performs processing in S6074, which will be described later. On the other hand, in S6072, if the main CPU 6101 determines that the gaming state is a variable probability gaming state (YES in S6072), the main CPU 6101 sets the special symbol probability variable state notification flag value to an on state (on value). (S6073).

The special symbol probability variable state notification flag is a flag indicating whether or not to notify that the current gaming state is a variable probability gaming state, and is set to the on state when the current gaming state is a variable probability gaming state. Ru. Further, the special symbol probability change state notification flag value is stored in the special symbol probability change state notification flag area provided in the main RAM 6103. In addition, in this embodiment, what is called a fixed variable lamp that informs that the gaming state is a fixed variable gaming state is provided, but this fixed variable lamp is in a fixed variable gaming state when the power is cut off, and it is not possible to recover from the power cut. If the special symbol probability variation state notification flag is in the on state at the time of return, it lights up, but in other cases, the probability variation lamp does not light up even if the special symbol probability variation state notification flag is in the on state. In addition, in this embodiment, what is called a time-saving lamp is also provided to notify that the gaming state is a time-saving gaming state, and the time-saving lamp lights up during the time-saving gaming state.

After the processing in S6073, or if the determination in S6072 is NO, the main CPU 6101 performs transmission reservation processing for a power failure recovery command (S6074). In addition, if the second normal game pre-processing is called by the setting change processing, the transmission of the power failure recovery command reserved in the processing of S6074 to the sub-control circuit 6200 is performed by the setting control processing (Fig. 173)) is performed in the production control command transmission process (S6035). In addition, if the second normal game pre-processing is called in the startup initial setting process during the main control main process (see FIG. 187 described later), the power failure recovery command reserved in the process of S6074 The transmission to the sub-control circuit 6200 is performed in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172). That is, in this embodiment, the process of transmitting a power failure recovery command to the sub control circuit 6200, which is performed at the time of power failure recovery, is also performed when the setting change process is executed.

After the processing in S6074, the main CPU 6101 ends the second normal game pre-processing and also ends the setting confirmation processing (FIG. 175).

As described above, in the pachinko gaming machine 6001 of this embodiment, the setting control process (setting change process and setting confirmation process) is performed within the system timer interrupt process that is performed at a 2 msec cycle. Further, when the setting control process is performed, as described above, the normal game pre-processing (first or second normal game pre-processing) according to the control type (setting change or setting confirmation) is performed. The normal game pre-processing (first and second normal game pre-processing) performed within this setting control processing is performed before the processing related to game control within the main control main processing (see FIGS. 182 to 185 described later). This process is similar to the normal game pre-processing (initial setting process) that is performed. Therefore, in this embodiment, the normal game pre-processing (first and second normal game pre-processing) performed within the setting control processing and the normal game processing performed before the game control-related processing during the main control main processing. Preprocessing (initial setting processing) can be shared, and the capacity of processing programs managed by main control circuit 6100 can be reduced.

[Switch input detection processing]
Next, with reference to FIG. 178, the switch input detection process performed in S6020 during the system timer interrupt process (see FIG. 172) will be described. Note that FIG. 178 is a flowchart showing the procedure of switch input detection processing.

First, the main CPU 6101 performs abnormal state monitoring processing (S6081). Note that details of the abnormal state monitoring process will be described later with reference to FIG. 179, which will be described later.

Next, the main CPU 6101 performs a normal symbol related check process (S6082). In this process, the main CPU 6101 performs a check process for the first starting opening winning ball switch 6044a, the passing ball switch 6043a, and the second starting opening winning ball switch 6045a (normal electric accessory 6046). In this check process, if the on-edge of the first starting opening winning ball switch 6044a or the on-edge of the passing ball switch 6043a is detected, random number acquisition processing, random number transfer processing, etc. are performed. In addition, in this check process, if the on-edge of the second starting opening winning ball switch 6045a is detected, depending on the situation, updating processing of the normal electric accessory winning counter, winning invalidation processing, etc. are performed.

Next, the main CPU 6101 performs a special symbol related check process (S6083). In this process, the main CPU 6101 performs check processing of the count switches 6053c, 6054c, the first starting opening winning ball switch 6044a, and the second starting opening winning ball switch 6045a. In this check process, if the on-edge of the count switches 6053c, 6054c is detected, the special electric accessory winning counter is updated, the winning invalidation process, etc. are performed depending on the situation. In addition, in this check process, if the on-edge of each starting opening winning ball switch is detected (the number of reserved special symbols is updated) and a pre-reading effect is implemented, the transmission reservation process of the specific pending addition command is executed. It will be done. On the other hand, in this check process, if the on-edge of each starting opening winning ball switch is detected (the number of reserved special symbols is updated) and the pre-reading performance is not performed, a reservation process for sending a pending addition command is performed. .

Next, the main CPU 6101 performs a prize ball related switch check process (S6084). In this process, the main CPU 6101 updates the data (prize ball management pointer value) stored in the payout management table at the time of prize ball. After the processing in S6084, the main CPU 6101 ends the switch input detection processing and returns the processing to the processing in S6021 of the system timer interrupt processing (FIG. 172).

[Abnormal state monitoring processing]
Next, with reference to FIG. 179, the abnormal state monitoring process performed in S6081 during the switch input detection process (see FIG. 178) will be described. Note that FIG. 179 is a flowchart showing the procedure of abnormal state monitoring processing.

First, the main CPU 6101 performs abnormal state monitoring preprocessing (S6091). In this process, the main CPU 6101 updates the abnormality detection information (information on various sensor bits of the input port 2). Note that details of the abnormal state monitoring preprocessing will be described later with reference to FIG. 180, which will be described later.

Next, the main CPU 6101 performs general-purpose abnormality detection determination processing (S6092). In this process, the main CPU 6101 performs a process of determining whether or not there is an abnormality for each monitoring target (for each abnormality item). Note that details of the general-purpose abnormality detection and determination process will be described later with reference to FIG. 181, which will be described later.

Next, the main CPU 6101 performs induced magnetic field monitoring processing (S6093). In this process, the main CPU 6101 determines whether or not the induced magnetic field is being detected, and if the induced magnetic field is not being detected, sets the induced magnetic field detection information bit to an on state (on value). After the process of S6093, the main CPU 6101 ends the abnormal state monitoring process and returns the process to the process of S6082 of the switch input detection process (FIG. 178).

[Abnormal condition monitoring preprocessing]
Next, with reference to FIG. 180, the abnormal state monitoring preprocessing performed in S6091 in the abnormal state monitoring process (see FIG. 179) will be described. Note that FIG. 180 is a flowchart showing the procedure of abnormal state monitoring pre-processing.

First, the main CPU 6101 performs a process of reading abnormality detection information (information on various sensor bits of the input port 2) (S6101). Next, the main CPU 6101 determines whether the door/frame is being opened (whether the base door 6003 and/or the glass door 6004 is open) (S6102).

If the main CPU 6101 determines in S6102 that the door/frame is not being opened (NO determination in S6102), the main CPU 6101 performs processing in S6104, which will be described later. On the other hand, if the main CPU 6101 determines in S6102 that the door/frame is being opened (YES in S6102), the main CPU 6101 clears the magnetic sensor bit of input port 2 (S6103). As a result, the detection level of the magnetic sensor is turned off, and abnormality detection by the magnetic sensor is no longer performed.

After the process in S6103, or if the determination in S6102 is NO, the main CPU 6101 performs an update process for the abnormality detection information (S6104). After the processing in S6104, the main CPU 6101 ends the abnormal state monitoring pre-processing and returns the processing to the processing in S6092 of the abnormal state monitoring processing (FIG. 179).

In addition, in the abnormal state monitoring preprocessing of this embodiment, as described above, when the door/frame is open (when S6102 is YES), the magnetic sensor bit of input port 2 is cleared (S6103), and the magnetic Although an example has been described in which the detection level of the sensor is turned off (non-detection level), the present invention is not limited to this. For example, the detection level of the magnetic sensor may be lowered while the door/frame is open. At this time, control may be performed to gradually lower the detection level of the magnetic sensor every time the system timer interrupt process is processed (2 msec cycle), and finally turn off the detection level of the magnetic sensor. Control may be performed such that the detection level is lowered to a low level that is not affected by magnetic disturbance when the door/frame is opened, and then the detection level is maintained. Furthermore, in the present embodiment, an example has been described in which the magnetic sensor bit of input port 2 is cleared (S6103) while the door/frame is open (YES in S6102), but the present invention is not limited to this. If a vibration sensor is provided, not only the magnetic sensor bit of the input port 2 but also the vibration sensor bit may be cleared while the door/frame is being opened.

As described above, in this embodiment, while the door/frame is open, the detection level of various sensors for abnormality detection (e.g. magnetic sensor, vibration sensor, etc.) is lowered or turned off in the abnormal state monitoring pre-processing. do. Therefore, when such a configuration is provided, even if magnetic disturbance or vibration occurs when the door/frame (base door 6003 and/or glass door 6004) of the pachinko gaming machine 6001 is opened, the gaming machine will not be affected. It is possible to suppress adverse effects on the various sensors provided (for example, magnetic sensors, vibration sensors, etc.).

[General-purpose abnormality detection judgment processing]
Next, with reference to FIG. 181, the general-purpose abnormality detection determination process performed in S6092 in the abnormal state monitoring process (see FIG. 179) will be described. Note that FIG. 181 is a flowchart showing the procedure of general-purpose abnormality detection and determination processing.

First, the main CPU 6101 acquires the number of abnormality monitoring targets (the number of abnormal items to be monitored) (S6111). In this process, the main CPU 6101 refers to the address immediately before the start address of the abnormality monitoring table and reads out the number of monitoring targets (number of monitoring checks) stored at that address. In this embodiment, the monitoring targets (abnormality items) include, for example, sensor abnormality monitoring, magnetic monitoring, door/frame opening/closing monitoring, tray full monitoring, dispensing abnormality monitoring, and touch state monitoring.

Next, the main CPU 6101 determines whether there is an abnormality in the monitoring target (abnormal item) currently being processed (S6112).

Here, the details of the determination process in S6112 will be explained in detail. In this process, the main CPU 6101 performs an AND operation between the information stored in the monitoring target area of the monitoring target currently being processed and the abnormal state detection mask value (monitoring specific information). Note that the information stored in the monitoring target area of the monitoring target is information that indicates the presence or absence of an abnormality in the monitoring target, and the abnormal state detection mask value indicates whether or not the monitoring target is the target of checking for abnormality detection. This is the information shown.

The abnormal state detection mask value is composed of, for example, 1 byte of data, and each bit of data (“0” or “1”) specifies whether or not to perform abnormality detection check processing for the corresponding monitoring target. be done. Then, "1" is stored in the bit corresponding to the monitoring target for which the abnormality detection check process is performed, and "0" is stored in the bit corresponding to the monitoring target for which the abnormality detection check process is not performed.

Therefore, if the monitoring target that is currently being processed is a check target and an abnormality has occurred in the monitoring target, the information stored in the monitoring target area of the monitoring target and the abnormal state detection The result of the logical product operation with the mask value is "1", and it is determined in S6112 that there is an abnormality; otherwise, the result of the logical product operation is "0", and it is determined that there is no abnormality in S6112. . That is, if the monitoring target currently being processed is not the target of the abnormality detection check process, it is determined that there is no abnormality even if an abnormality has occurred in the monitoring target. In this case, various processes related to the abnormal state flag (processing at the time of abnormality detection), which will be described later, are not performed.

For example, when the number of monitoring targets is "8" and the abnormal state detection mask value is "00111100B", in the general-purpose abnormality detection determination process shown in FIG. 181, the processes of S6112 to S6119 (abnormality detection check process) is repeated 8 times, and the anomaly detection check process is actually performed only on the target monitoring target in the 3rd to 6th processes from the start of the general-purpose anomaly detection judgment process. , the monitoring targets targeted in the seventh and eighth processes are all determined to have no abnormality, and the abnormality detection check process is not performed.

Here, returning to the explanation of FIG. 181 again, if the main CPU 6101 determines in S6112 that there is no abnormality in the monitoring target (NO determination in S6112), the main CPU 6101 performs the processing in S6114 described below. . On the other hand, if the main CPU 6101 determines in S6112 that there is an abnormality in the monitoring target (YES in S6112), the main CPU 6101 sets an abnormal state flag for the monitoring target (S6113).

After the processing in S6113, or if the determination in S6112 is NO, the main CPU 6101 determines whether or not there is a change in the abnormal state flag of the monitoring target (S6114).

If the main CPU 6101 determines in S6114 that there is no change in the abnormal state flag (NO determination in S6114), the main CPU 6101 performs processing in S6116, which will be described later. On the other hand, if the main CPU 6101 determines in S6114 that there is a change in the abnormal state flag (YES in S6114), the main CPU 6101 sets a monitoring timer (S6115).

After the processing in S6115, or if the determination in S6114 is NO, the main CPU 6101 determines whether the monitoring timer has elapsed (S6116).

In S6116, if the main CPU 6101 determines that the monitoring timer has not elapsed (NO in S6116), the main CPU 6101 performs processing in S6119, which will be described later. On the other hand, if the main CPU 6101 determines in S6116 that the monitoring timer has elapsed (YES in S6116), the main CPU 6101 determines whether there is a change in the abnormal state flag (S6117).

In S6117, if the main CPU 6101 determines that there is no change in the abnormal state flag (NO in S6117), the main CPU 6101 performs processing in S6119, which will be described later. On the other hand, if the main CPU 6101 determines in S6117 that there is a change in the abnormal state flag (YES in S6117), the main CPU 6101 updates the abnormal state flag (S6118).

After the process in S6118, or if the determination in S6116 or S6117 is NO, the main CPU 6101 updates the number of monitored targets by subtracting 1, and determines whether the updated number of monitored targets is "0" ( S6119).

In S6119, if the main CPU 6101 determines that the updated number of monitoring targets is not "0" (NO in S6119), the main CPU 6101 changes the monitoring target to the monitoring target corresponding to the updated number of monitoring targets. Then, the process from S6112 onward is performed. On the other hand, if the main CPU 6101 determines in S6119 that the number of monitored objects after the update is "0" (YES in S6119), the main CPU 6101 ends the general-purpose abnormality detection determination process, and executes the process as follows. The process returns to S6093 of the abnormal state monitoring process (FIG. 179).

As described above, in the general-purpose abnormality detection determination process of this embodiment, the abnormality detection check process is performed only on the monitoring targets that are specified as check targets ("1") by the abnormal state detection mask value, For a monitoring target that is defined as a non-check target (“0”) by the abnormal state detection mask value, it is determined that there is no abnormality, and the abnormality detection check process is not actually performed. When such processing is performed, the general-purpose abnormality detection and determination processing can be further simplified. Therefore, in this case, the processing performed by main control circuit 6100 can be executed more efficiently, and the processing load on main control circuit 6100 can be reduced.

[Main control main processing]
Next, main processing (main control main processing) controlled by the main CPU 6101 will be described with reference to FIGS. 182 to 185. Note that FIGS. 182 to 185 are flowcharts showing the procedure of main control main processing.

First, the main CPU 6101 performs stack pointer setting processing (S6201). Next, the main CPU 6101 performs an interrupt vector table address setting process (S6202). In this process, the address of the interrupt vector table is stored in the I register.

Next, the main CPU 6101 determines whether the power interruption signal is at High level (S6203). If the main CPU 6101 determines in S6203 that the power interruption signal is not at the High level (NO determination in S6203), the main CPU 6101 repeats the determination process in S6203.

On the other hand, if the main CPU 6101 determines in S6203 that the power outage signal is at High level (YES in S6203), the main CPU 6101 performs flag management processing for the RAM clear switch 6121 and the setting key 6080. (S6204). In this process, the main CPU 6101 saves the state information of the RAM clear switch 6121 and the state information of the setting key 6080.

Next, the main CPU 6101 performs wait processing (S6205). In this process, the main CPU 6101 performs a startup wait process on the side of the sub control circuit 6200. The startup waiting time (wait period) is 12000.07 msec. Also, during this startup waiting time, the main CPU 6101 performs processing for checking the interrupt request signal, processing for outputting the WDT when the interrupt request signal is generated, and processing for outputting the magnetic sensor initialization signal at a predetermined timing. Note that details of the wait process will be described later with reference to FIG. 186, which will be described later.

Next, the main CPU 6101 determines whether the power outage before startup was a normal power outage (S6206). In this process, the main RAM 6103 compares the value stored in the power outage detection flag area in the main RAM 6103 with a predetermined power outage detection flag value ("0A5H"), and if the two are the same, It is determined that it was a normal power outage (YES determination), but if the two are different, it is determined that it was an abnormal power outage (NO determination).

If the main CPU 6101 determines in S6206 that the power outage was not normal (NO determination in S6206), the main CPU 6101 performs processing in S6210, which will be described later.

On the other hand, if the main CPU 6101 determines in S6206 that there was a normal power outage (YES in S6206), the main CPU 6101 calculates the checksum value of the work area stored in the main RAM 6103 (S6207). . Next, the main CPU 6101 performs processing to verify the checksum value of the work area (S6208).

Next, the main CPU 6101 determines whether the verification result is normal (S6209).

In S6209, if the main CPU 6101 determines that the verification result is normal (YES in S6209), the main CPU 6101 performs processing in S6217, which will be described later. On the other hand, if the main CPU 6101 determines in S6209 that the verification result is not normal (NO determination in S6209), the main CPU 6101 performs processing in S6210, which will be described later.

If the determination in S6206 or S6209 is NO, the main CPU 6101 determines whether the setting key 6080 and the RAM clear switch 6121 are in the on state (S6210). This determination process is performed with reference to the value (on/off value) of the setting key switch bit of input port 0 and the value of the RAM clear bit of input port 2.

In S6210, if the main CPU 6101 determines that the setting key 6080 and the RAM clear switch 6121 are in the on state (YES in S6210), the main CPU 6101 performs processing in S6216, which will be described later. On the other hand, if the main CPU 6101 determines in S6210 that the setting key 6080 and the RAM clear switch 6121 are not in the ON state (NO determination in S6210), the main CPU 6101 outputs the security signal of the external terminal (the security bit of the output port). is set to the on state (S6211).

Next, the main CPU 6101 displays an error on the performance display monitor 6070 (S6212). In this process, the main CPU 6101 sets error display bit data to the output port to the performance display monitor 6070. As a result, a predetermined LED in the performance display monitor 6070 lights up, indicating that an error has occurred.

Next, the main CPU 6101 performs a WDT clear register address setting process (S6213). Next, the main CPU 6101 clears the built-in WDT (S6214). In this process, the main CPU 6101 sets a built-in WDT clear value. Next, the main CPU 6101 performs restart processing of the built-in WDT (S6215). In this process, the main CPU 6101 sets a built-in WDT restart value. After the process in S6215, the main CPU 6101 repeats the processes in S6213 to S6215 (WDT output process) until the power is turned off (performs an eternal loop process).

Here, returning to the process of S6210 again, if the determination in S6210 is YES, the main CPU 6101 stores the setting change state value in the activation control flag area in the main RAM 6103 (S6216). Through this process, the setting change state value is stored as the value of the activation control flag.

After the processing in S6216, or if the determination in S6209 is YES, the main CPU 6101 performs processing to clear the XINT detection flag area and the power failure detection flag area in the main RAM 6103 (S6217).

Next, the main CPU 6101 performs activation state determination processing (S6218). In this process, the main CPU 6101 determines the current startup state (power failure recovery/setting change/setting confirmation/RAM clear) based on the value stored in the startup control flag area (startup control flag value).

Next, the main CPU 6101 performs RAM clear processing at startup (S6219). In this process, the main CPU 6101 performs a process to clear the area specified at startup in the main RAM 6103.

Next, the main CPU 6101 performs startup initialization processing (S6220). In this processing, the main CPU 6101 performs initial setting processing according to the current startup state (recovery from power failure/setting change/setting confirmation/RAM clearing). Note that details of the startup initialization process will be described later with reference to FIG. 187, which will be described later.

Next, the main CPU 6101 performs interrupt prohibition processing (S6221). Next, the main CPU 6101 performs power cutoff processing (S6222). Note that the details of the power interruption process will be described later with reference to FIG. 189, which will be described later.

Next, the main CPU 6101 performs an initial value random number update process (S6223). In this process, the main CPU 6101 performs a process of updating the initial value random number for special symbol determination.

Next, the main CPU 6101 determines whether or not the game is in a playable state (S6224). Note that this determination process is performed based on the value of the startup control flag, and if the value of the startup control flag (current startup state) is a value that corresponds to recovery from power failure, S6224 becomes YES, and startup is not performed. If the value of the control flag is a value other than the value corresponding to recovery from power failure, a NO determination is made in S6224.

If the main CPU 6101 determines in S6224 that the game is not in a playable state (NO determination in S6224), the main CPU 6101 performs interrupt permission processing (S6225). After the process in S6225, the main CPU 6101 returns the process to S6221 and performs the processes from S6221 onwards.

On the other hand, if the main CPU 6101 determines in S6224 that the game is ready (YES in S6224), the main CPU 6101 performs register saving processing (S6226). Note that in this process, the main CPU 6101 performs a process of saving the accumulator A and the flag register F.

Next, the main CPU 6101 performs performance display monitor total subtraction processing (S6227). In this process, the main CPU 6101 calculates and updates various base values. Further, this processing is performed using an extra-area work area in the main RAM 6103.

Next, the main CPU 6101 performs restoration processing for the registers saved in S6226 (S6228). Next, the main CPU 6101 performs interrupt permission processing (S6229).

Next, the main CPU 6101 determines whether the system cycle time (6 msec: 3 times the interrupt cycle (2 msec)) has elapsed (S6230). Specifically, the main CPU 6101 determines whether the value obtained by subtracting 3 from the value stored in the interrupt counter area in the main RAM 6103 (current interrupt counter count value) is "0". Note that the value of the interrupt counter is incremented by 1 for each system timer interrupt process (see S6017 in FIG. 172), and becomes "3" when the system cycle time has elapsed. Therefore, if the value obtained by subtracting 3 from the value of the interrupt counter is "0", S6230 makes a YES decision, and if the value obtained by subtracting 3 from the interrupt counter value is not "0", S6230 makes a NO decision. becomes.

In S6230, if the main CPU 6101 determines that the system cycle time has not elapsed (NO in S6230), the main CPU 6101 returns the process to S6221 and performs the processes from S6221 onwards.

On the other hand, if the main CPU 6101 determines in S6230 that the system cycle time has elapsed (YES in S6230), the main CPU 6101 subtracts 1 from the value stored in the interrupt counter area (value of the interrupt counter). The process is performed three times (S6231). Through this processing, the value of the interrupt counter that manages the interrupt-prohibited section in the main control main processing is reset (becomes "0").

As described above, in this embodiment, in the main control main processing, an interrupt prohibition period of 6 msec (processing period of S6221 to S6230) is provided before execution of various processing related to game control to be described later. Therefore, in this embodiment, various processes related to game control, which will be described later, are executed every 6 msec (every system cycle). In addition, in this embodiment, an example in which the interrupt prohibition period is three times the interrupt period has been described, but the present invention is not limited to this. The value may be set to .

Next, the main CPU 6101 performs system timer update processing (S6232). Note that the system timer is a timer for managing the system cycle (6 msec), and the value of the system timer is stored in the system cycle management timer area in the work area of the main RAM 6103.

Next, the main CPU 6101 performs main control command transmission/reception processing (S6233). In this process, the main CPU 6101 mainly performs command transmission/reception processing for payout control.

Next, the main CPU 6101 performs special symbol control processing (S6234). In this process, the main CPU 6101 performs a control process for the special symbol game. The details of the special symbol control process will be explained later with reference to FIGS. 190 and 191, which will be described later.

Next, the main CPU 6101 performs normal symbol control processing (S6235). In this processing, the main CPU 6101 performs control processing for the normal symbol game. The details of the normal symbol control process will be explained later with reference to FIG. 204, which will be described later.

Next, the main CPU 6101 performs game operation display unit control processing (S6236). In this process, the main CPU 6101 performs setting processing of display data to be output to the first special symbol display LED, second special symbol display LED, normal symbol display LED, pending display LED, etc.

Next, the main CPU 6101 performs game information data generation processing (S6237). In this process, the main CPU 6101 performs control processing of external terminal board pulse signals, processing of setting output data, processing of generation of sight-firing test signals, and the like. Note that the generation process of the sight test signal is performed using the out-of-area work area in the main RAM 6103.

Next, the main CPU 6101 performs port output processing (S6238). In this process, the main CPU 6101 performs a process of setting (transferring) output data to an output port and a process of outputting the WDT.

Next, the main CPU 6101 performs status monitoring processing (S6239). In this process, the main CPU 6101 performs a firing position determination process (if there is a change in the firing position, performs a firing position command transmission reservation process), a game abnormality detection determination process (if there is an abnormality, a game abnormality detection command transmission reservation process), processing), and performs a payout abnormality detection determination process (if there is an abnormality, performs a transmission reservation process of a payout abnormality detection command).

After the processing in S6239, the main CPU 6101 returns the processing to S6221 and performs the processing from S6221 onwards.

As described above, in the main control main processing of this embodiment, after startup and before executing the wait processing (S6205) (before checking the checksum is completed), the status information of the RAM clear switch 6121 and the setting key 6080 are The state information saving process (flag management process in S6204) is performed. If such processing is provided, for example, even if the setting key 6080 is operated (on/off) during the wait period, the value of the startup control flag at power-on (state information at startup) ) can be secured. Therefore, in this embodiment, the operation status of the setting key 6080 and the operation status of the RAM clear switch 6121 at the time of startup can be grasped more reliably, and the activation state of the pachinko game machine 6001 can be accurately identified.

Furthermore, as described above, in this embodiment, in the main control main processing, an interrupt prohibition period of 6 msec (processing period from S6221 to S6230) is provided before executing various processing related to game control (processing from S6231 onward). , power interruption processing (S6222), initial value random number updating processing (S6223), performance display monitor total subtraction processing (S6227), etc. are performed within the interrupt prohibited section. That is, in this embodiment, management processing of values that affect the ball payout performance of the game and values that are totaled throughout the game is performed in the interrupt-prohibited section. Therefore, by providing such an interrupt-prohibited section, game management becomes easier, the processing performed by the main control circuit 6100 can be executed more efficiently, and the processing load on the main control circuit 6100 is reduced. be able to.

Further, in this embodiment, the performance display monitor total subtraction process (S6227) is performed only when the game is possible in the interrupt-prohibited section in the main control main process. That is, in this embodiment, the performance display monitor 6070 is updated only when the game is possible, so the processing becomes simpler. Therefore, with such a processing configuration, the processing performed by the main control circuit 6100 can be executed even more efficiently, and the processing load on the main control circuit 6100 can be further reduced.

[Wait processing]
Next, with reference to FIG. 186, the wait process performed in S6205 in the main control main process (see FIGS. 182 to 185) will be described. Note that FIG. 186 is a flowchart showing the procedure of wait processing.

First, the main CPU 6101 sets the number of first loops to, for example, "60" (S6301). Next, the main CPU 6101 sets the second loop count to, for example, "47761" (S6302). Note that the first loop count and the second loop count are parameters for managing the progress of the wait period, and the first loop count is set in the B register, and the second loop count is set in the DE register.

Next, the main CPU 6101 determines whether the current timing is a timing other than the output timing of the magnetic sensor initialization signal (S6303). In this embodiment, when the first loop number is, for example, 10 times, the bit data of the magnetic sensor initialization signal is output to the corresponding output port (output port 1). Therefore, in the determination process of S6303, the main CPU 6101 determines whether the first loop number is a number other than 10, for example, and if the first loop number is a number other than 10, for example, The determination result in S6303 is YES, and if the number of times of the first loop is, for example, 10, the determination result in S6303 is NO.

In S6303, if the main CPU 6101 determines that the current timing is a timing other than the output timing of the magnetic sensor initialization signal (YES in S6303), the main CPU 6101 performs processing in S6305, which will be described later. On the other hand, if the main CPU 6101 determines in S6303 that the current timing is not a timing other than the output timing of the magnetic sensor initialization signal (NO determination in S6303), the main CPU 6101 outputs the bit data of the magnetic sensor initialization signal. Output to the address of the corresponding output port (output port 1) (S6304).

After the processing in S6304, or if the determination in S6303 is YES, the main CPU 6101 acquires the address information of the interrupt wait monitor register (S6305). Next, the main CPU 6101 checks the data stored in the interrupt wait monitor register (S6306).

Next, the main CPU 6101 determines whether an interrupt request signal is generated (S6307). In this determination process, the main CPU 6101 determines whether an interrupt request signal is generated according to the on/off information of a specific bit in the interrupt wait monitor register, and if the specific bit is in the on state, the main CPU 6101 performs step S6307. The determination result is YES, and if the specific bit is in the off state, the determination result in S6307 is NO.

If the main CPU 6101 determines in S6307 that an interrupt request signal has not been generated (NO in S6307), the main CPU 6101 returns the process to S6306 and performs the processes from S6306 onwards.

On the other hand, if the main CPU 6101 determines in S6307 that an interrupt request signal is generated (YES in S6307), the main CPU 6101 performs a WDT clear register address setting process (S6308). Next, the main CPU 6101 clears the built-in WDT (S6309). Next, the main CPU 6101 performs restart processing of the built-in WDT (S6310).

Next, the main CPU 6101 subtracts 1 from the second loop count and sets (updates) the subtraction result as a new second loop count (S6311). Next, the main CPU 6101 determines whether the second loop count is not "0" (S6312).

In S6312, if the main CPU 6101 determines that the second loop count is not "0" (YES in S6312), the main CPU 6101 returns the process to S6305 and performs the processes from S6305 onwards.

On the other hand, if the main CPU 6101 determines in S6312 that the second loop number is "0" (NO determination in S6312), the main CPU 6101 subtracts 1 from the first loop number, and uses the subtraction result as a new It is set (updated) as the number of first loops, and it is determined whether the subtraction result (the number of first loops after updating) is not "0" (S6313).

In S6313, if the main CPU 6101 determines that the number of first loops after the update is not "0" (YES in S6313), the main CPU 6101 returns the process to the process in S6302 and performs the process from S6302 onwards. .

On the other hand, if the main CPU 6101 determines in S6313 that the number of first loops after the update is "0" (NO determination in S6313), the main CPU 6101 ends the wait process and controls the process under the main control. The process returns to S6206 of the main process (FIGS. 182 to 185).

As described above, in the pachinko gaming machine 6001 of this embodiment, the magnetic sensor initialization signal output process (S6304) is performed at a predetermined timing during the wait process (the first loop number is 10 times, for example), and the magnetic sensor The sensor is initialized. Therefore, in this embodiment, even if magnetic disturbance occurs when the door/frame (base door 6003 and/or glass door 6004) of the pachinko gaming machine 6001 is opened, the magnetic sensor is reset by this process. , it is possible to suppress the adverse effect on the magnetic sensor due to magnetic disturbance.

Note that "to initialize (clear) the magnetic sensor" here may include "the magnetic sensor is initialized", and may include "to initialize the settings (driver, etc.) of the magnetic sensor itself". ”, “Initialize the detection state of the magnetic sensor (for example, forcefully turn off detection, or set the detection signal to a value other than 0 if magnetism is detected when the detection signal = 0). ) is possible. In addition, as a magnetic sensor initialization signal, if it is assumed that magnetism has been detected when the detection signal = 0 to change the detection state of the magnetic sensor, a value other than 0 should be transmitted as the magnetic sensor initialization signal. Alternatively, a predetermined signal (1, 0, etc.) can be sent to a predetermined input terminal (port, etc.) of the magnetic sensor in order to make it possible to initialize the settings (driver, etc.) of the magnetic sensor itself. It is also possible to do so.

[Initial setting processing at startup]
Next, with reference to FIG. 187, the startup initial setting process performed in S6220 in the main control main process (see FIGS. 182 to 185) will be described. Note that FIG. 187 is a flowchart showing the procedure of initial setting processing at startup.

First, the main CPU 6101 performs processing to read the activation control flag (S6321).

Next, the main CPU 6101 determines whether the startup state is recovery from power failure (S6322). Note that this determination process is performed based on the value of the activation control flag.

In S6322, if the main CPU 6101 determines that the startup state is power failure recovery (YES in S6322), the main CPU 6101 performs the second normal game preprocessing (power failure recovery) described with reference to FIG. various initial setting processes) are performed (S6323). After the processing in S6323, the main CPU 6101 ends the startup initialization processing and returns the processing to the processing in S6221 of the main control main processing (FIGS. 182 to 185).

On the other hand, if the main CPU 6101 determines in S6322 that the startup state is not recovery from power failure (NO determination in S6322), the main CPU 6101 determines whether the startup state is setting change or setting confirmation ( S6324). Note that this determination process is performed based on the value of the activation control flag.

In S6324, if the main CPU 6101 determines that the activation state is setting change or setting confirmation (YES in S6324), the main CPU 6101 performs setting operation preprocessing (S6325). Note that details of the setting operation preprocessing will be described later with reference to FIG. 188, which will be described later. After the processing in S6325, the main CPU 6101 ends the startup initialization processing and returns the processing to the processing in S6221 of the main control main processing (FIGS. 182 to 185).

On the other hand, in S6324, if the main CPU 6101 determines that the startup state is neither setting change nor setting confirmation (NO determination in S6324), the main CPU 6101 executes the first normal game described with reference to FIG. Preprocessing (various setting processing when clearing RAM) is performed (S6326). After the processing in S6326, the main CPU 6101 ends the startup initialization processing and returns the processing to the processing in S6221 of the main control main processing (FIGS. 182 to 185).

[Setting operation preprocessing]
Next, with reference to FIG. 188, the setting operation pre-processing performed in S6325 during the startup initial setting process (see FIG. 187) will be described. Note that FIG. 188 is a flowchart showing the procedure of setting operation pre-processing.

In the setting operation preprocessing, the main CPU 6101 performs a setting operation command transmission reservation process (S6331). The setting operation command reserved in this process is transmitted to the sub-control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172).

After the processing in S6331, the main CPU 6101 ends the setting operation preprocessing and also ends the startup initial setting processing (FIG. 187).

As described above, in this embodiment, the setting change processing (see FIG. 174) or setting confirmation processing (see FIG. 175) is performed within the system timer interrupt processing (see FIG. 172), but the setting change processing or setting confirmation processing (see FIG. 172) is The transmission reservation processing of the setting operation command, which is transmitted from the main control circuit 6100 to the sub-control circuit 6200 when performed, is performed within the main control main processing.

When the setting operation command transmission reservation processing is performed within the system timer interrupt processing, the setting operation command transmission reservation processing is performed for each interrupt processing for the executed setting operation, so the transmission reservation processing of the setting operation command can be performed multiple times. May be executed twice. On the other hand, when the setting operation command transmission reservation process is performed in the main control main process as in this embodiment, the setting operation command transmission reservation process is executed only once for the executed setting operation. It's over. Therefore, in this embodiment, there is no need to execute the transmission reservation process for an extra setting operation command. As a result, in this embodiment, the processing performed by the main control circuit 6100 can be executed more efficiently, and the processing load on the main control circuit 6100 can be reduced.

[Power outage processing]
Next, with reference to FIG. 189, the power interruption process performed in S6222 in the main control main process (see FIGS. 182 to 185) will be described. Note that FIG. 189 is a flowchart showing the procedure of power cutoff processing.

First, the main CPU 6101 determines whether the XINT detection flag is on (S6341).

In S6341, if the main CPU 6101 determines that the XINT detection flag is not in the on state (NO in S6341), the main CPU 6101 ends the power-off process and converts the process to the main control main process (FIGS. 182 to 182). 185) returns to the process of S6223. On the other hand, if the main CPU 6101 determines in S6341 that the XINT detection flag is on (YES in S6341), the main CPU 6101 performs checksum value calculation processing (S6342).

Next, the main CPU 6101 determines whether the checksum value calculation process is completed (S6343).

If the main CPU 6101 determines in S6343 that the checksum value calculation process is not completed (NO in S6343), the main CPU 6101 returns the process to S6342 and performs the processes from S6342 onwards. On the other hand, if the main CPU 6101 determines in S6343 that the checksum value calculation processing is completed (YES in S6343), the main CPU 6101 calculates the checksum value and the power failure detection flag value (“0A5H”). Each is stored in a corresponding predetermined storage area in the main RAM 6103 (S6344).

Next, the main CPU 6101 performs processing to clear the XINT detection flag (S6345). Next, the main CPU 6101 performs a RAM access prohibition value setting process (S6346). After the process of S6346, the main CPU 6101 repeats the CPU reset wait process (S6347).

[Special pattern control processing]
Next, with reference to FIGS. 190 and 191, the special symbol control process performed in S6234 in the main control main process (see FIGS. 182 to 185) will be described. In addition, FIGS. 190 and 191 are flowcharts showing the procedure of special symbol control processing.

First, the main CPU 6101 performs a first special symbol address setting process (S6401). In this process, the main CPU 6101 sets the address of the first special symbol related definition data table (see FIG. 167) in the main RAM 6103 to the IX register, and sets the address of the first special symbol work area table (see FIG. 166) to the IY register. Set in register.

Next, the main CPU 6101 performs special symbol related timer update processing (S6402). In this process, the main CPU 6101 mainly updates (subtracts) the variable display time of the first special symbol (first special symbol waiting time), and determines whether or not the variable display time of the first special symbol has elapsed. Perform processing, etc. Details of the special symbol related timer update process will be described later with reference to FIG. 192, which will be described later. In addition, in the management process of the variable display time of the special symbols (first and second special symbols) of this embodiment, as described above, the first half variable display time and the second half variable display time are determined by the upper 2 byte timer and the second half, respectively. It is managed separately by the lower 2 byte timer.

Next, the main CPU 6101 performs a second special symbol address setting process (S6403). In this process, the main CPU 6101 sets the address of the second special symbol related definition data table (see FIG. 169) in the main RAM 6103 to the IX register, and sets the address of the second special symbol work area table (see FIG. 168) to the IY register. Set in register.

Next, the main CPU 6101 performs special symbol related timer update processing (S6404). In this process, the main CPU 6101 mainly updates (subtracts) the variable display time of the second special symbol (second special symbol waiting time), and determines whether or not the variable display time of the second special symbol has elapsed. Perform processing, etc. The details of the special symbol related timer update process will be explained later with reference to FIG. 192, which will be described later. Further, in this embodiment, the special symbol related timer update process called in S6404 is the same as that called in S6402, and a common process is called and executed in both processes.

Next, the main CPU 6101 refers to the second special symbol work area table (see FIG. 168) in the main RAM 6103 and reads the control state number of the second special symbol stored in the second special symbol control state number area. (S6405). In addition, the control state number of the special symbol is a number indicating the transition destination (transition destination) of the control processing state (control state) regarding the variable display of the special symbol (special symbol game) (in this embodiment, as described below) 0” to “6”).

Next, the main CPU 6101 determines whether the control state of the second special symbol is the start of variation of the second special symbol (S6406). In this determination process, it is determined whether the control state number of the second special symbol read in S6405 is the special symbol fluctuation start value ("0").

In S6406, if the main CPU 6101 determines that the control state of the second special symbol is the start of variation of the second special symbol (YES in S6406), the main CPU 6101 performs the process of S6409, which will be described later.

On the other hand, in S6406, if the main CPU 6101 determines that the control state of the second special symbol is not the start of fluctuation of the second special symbol (NO determination in S6406), the main CPU 6101 executes the second special symbol address setting process. Execute (S6407). Note that in this process, the same process as that performed in S6403 is performed.

Next, the main CPU 6101 performs special symbol management processing (S6408). In this process, the main CPU 6101 mainly performs a control process corresponding to the control state number of the second special symbol read in S6405. The details of the special symbol management process will be explained later with reference to FIG. 193, which will be described later.

After the process of S6408, or if S6406 is YES, the main CPU 6101 refers to the first special symbol work area table (see FIG. 166) in the main RAM 6103, and stores the special symbol in the first special symbol control state number area. The control state number of the first special symbol is read out (S6409).

Next, the main CPU 6101 determines whether the control state of the first special symbol is the start of variation of the first special symbol (S6410). In this determination process, it is determined whether the control state number of the first special symbol read in S6409 is the special symbol variation start value ("0").

In S6410, if the main CPU 6101 determines that the control state of the first special symbol is the start of variation of the first special symbol (YES in S6410), the main CPU 6101 performs the process of S6413, which will be described later.

On the other hand, in S6410, if the main CPU 6101 determines that the control state of the first special symbol is not the start of fluctuation of the first special symbol (NO determination in S6410), the main CPU 6101 executes the first special symbol address setting process. Execute (S6411). Note that in this process, the same process as that performed in S6401 is performed.

Next, the main CPU 6101 performs special symbol management processing (S6412). In this process, the main CPU 6101 mainly performs a control process corresponding to the control state number of the first special symbol read in S6409. The details of the special symbol management process will be explained later with reference to FIG. 193, which will be described later. Further, in this embodiment, the special symbol management process called in S6412 is the same as that called in S6408, and a common process is called and executed in both processes.

After the process of S6412, or if S6410 is YES, the main CPU 6101 refers to the second special symbol work area table (see FIG. 168) in the main RAM 6103, and stores the special symbol in the second special symbol control state number area. The control state number of the second special symbol is read out (S6413).

Next, the main CPU 6101 determines whether the control state of the second special symbol is the start of variation of the second special symbol (S6414). Note that in this process, the same process as the determination process performed in S6406 is performed.

In S6414, if the main CPU 6101 determines that the control state of the second special symbol is not the start of variation of the second special symbol (NO determination in S6414), the main CPU 6101 performs the process of S6417, which will be described later.

On the other hand, in S6414, if the main CPU 6101 determines that the control state of the second special symbol is the start of fluctuation of the second special symbol (YES in S6414), the main CPU 6101 performs the second special symbol address setting process. (S6415). Note that in this process, the same process as that performed in S6403 is performed.

Next, the main CPU 6101 performs special symbol management processing (S6416). In this process, the main CPU 6101 mainly performs a control process corresponding to the control state number of the second special symbol read in S6413. The details of the special symbol management process will be explained later with reference to FIG. 193, which will be described later. Further, in this embodiment, the special symbol management process called in S6416 is the same as that called in S6408 and S6412, and common processes are called and executed in these processes.

After the process of S6416, or if the determination is NO in S6414, the main CPU 6101 refers to the first special symbol work area table (see FIG. 166) in the main RAM 6103, and stores the information in the first special symbol control state number area. The control state number of the first special symbol is read out (S6417).

Next, the main CPU 6101 determines whether the control state of the first special symbol is the start of variation of the first special symbol (S6418). Note that in this process, the same process as the determination process performed in S6410 is performed.

In S6418, if the main CPU 6101 determines that the control state of the first special symbol is not the start of fluctuation of the first special symbol (NO determination in S6418), the main CPU 6101 ends the special symbol control process and continues the process. , the process returns to S6235 of the main control main process (FIGS. 182 to 185).

On the other hand, in S6418, if the main CPU 6101 determines that the control state of the first special symbol is the start of fluctuation of the first special symbol (YES in S6418), the main CPU 6101 performs the first special symbol address setting process. (S6419). Note that in this process, the same process as that performed in S6401 is performed.

Next, the main CPU 6101 performs special symbol management processing (S6420). In this process, the main CPU 6101 mainly performs a control process corresponding to the control state number of the first special symbol read in S6417. The details of the special symbol management process will be explained later with reference to FIG. 193, which will be described later. Moreover, in this embodiment, the special symbol management process called in S6420 is the same as that called in each of S6408, S6412, and S6416, and in these processes, a common process is called and executed. After the process of S6420, the main CPU 6101 ends the special symbol control process and returns the process to the process of S6235 of the main control main process (FIGS. 182 to 185).

As described above, in this embodiment, before each of the special symbol related timer process and the special symbol management process are executed, the special symbol address setting process is performed, and the special symbol to be processed (the first special symbol or the first special symbol) is set. 2) Set the address of the special symbol work area table in the IY register. In this case, when reading (obtaining) various data used in special symbol related timer processing and special symbol management processing from the work area table, the data is directly read from the special symbol work area table based on the address set in the IY register. , the necessary data can be read (obtained). That is, in this embodiment, when reading (obtaining) various data used in special symbol related timer processing and special symbol management processing from the working area table, it is necessary to perform reference processing of the address of the special symbol working area table. It disappears. Therefore, when such a special symbol address setting process is provided, the process of referring to the address of the special symbol work area table can be omitted, thereby reducing the capacity of the processing program managed by the main control circuit 6100. be able to.

[Special symbol related timer update process]
Next, with reference to FIG. 192, the special symbol related timer update process performed in S6402 and S6404 in the special symbol control process (see FIGS. 190 and 191) will be described. FIG. 192 is a flowchart showing the procedure of special symbol related timer update processing.

In addition, in the special symbol-related timer update process described below, the "special symbol" to be processed corresponds to the address of the special symbol work area table that is set in the IY register at the start of the special symbol-related timer update process. It is a special design. For example, when the special symbol related timer update process is called and executed in S6402 during the special symbol control process, the "special symbol" to be processed in the following explanation becomes the first special symbol. On the other hand, for example, when the special symbol related timer update process is called and executed in S6404 during the special symbol control process, the "special symbol" to be processed in the following explanation becomes the second special symbol.

First, the main CPU 6101 reads the control state number (in this embodiment, any one of "0" to "6" as described later) of the special symbol (S6431). In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol control state number area in the special symbol work area table (the first special symbol control state in FIG. 166). The control state number of the special symbol is read from the number area or the second special symbol control state number area in FIG. 168). In this case, the main CPU 6101 can directly read the control state number of the special symbol from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

Next, the main CPU 6101 determines whether the special symbol is changing (S6432). In this determination process, it is determined whether the control state number of the special symbol read in S6431 is the special symbol fluctuation end value ("1"), and the control state number of the special symbol is the special symbol fluctuation end value ("1"). If it is not "1"), it is determined that the special symbol is changing (YES determination).

In S6432, if the main CPU 6101 determines that the special symbol is not changing (NO determination in S6432), the main CPU 6101 performs the process of S6435, which will be described later.

On the other hand, in S6432, when the main CPU 6101 determines that the special symbol is changing (YES in S6432), the main CPU 6101 reads the value of the special symbol suspension flag of the special symbol (S6433). In this process, similar to the process of S6431 above, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol suspension flag area (in FIG. 166) in the special symbol work area table. The value of the special symbol suspension flag is read from the first special symbol suspension flag area (or the second special symbol suspension flag area in FIG. 168). In this case, the main CPU 6101 can directly read the value of the special symbol suspension flag from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table. In addition, the special symbol suspension flag is a flag for setting the stop of the fluctuation start or fluctuation interruption of the subsequent special symbol when the first special symbol and the second special symbol fluctuate simultaneously, that is, the fluctuation display of the subsequent special symbol. It is a flag for determining the control mode, and is provided separately for the first special symbol and the second special symbol.

Next, the main CPU 6101 determines whether or not a special symbol suspension flag is set for the special symbol to be processed (S6434). In this process, the main CPU 6101 determines whether or not the special symbol pause flag is on (whether the stop of the start of variation or the interruption of variation of the special symbol is set), and the special symbol pause flag is turned on. If it is in the state, S6434 becomes a YES determination, and if the special symbol suspension flag is in an OFF state, S6434 becomes a NO determination.

In S6434, if the main CPU 6101 determines that the special symbol suspension flag is set for the special symbol to be processed (YES in S6434), the main CPU 6101 ends the special symbol related timer update process. , the process returns to the special symbol control process (see FIGS. 190 and 191). At this time, if the special symbol-related timer update process is called in S6402 during the special symbol control process, the process returns to S6403, and the special symbol-related timer update process is called in S6404 during the special symbol control process. If so, the process returns to S6405.

On the other hand, if the main CPU 6101 determines in S6434 that the special symbol suspension flag is not set for the special symbol to be processed (if the determination is NO in S6434), or if the determination in S6432 is NO, the main CPU 6101 reads the value (value of the upper 2 byte timer) stored in the address of the special symbol waiting time management timer area of the special symbol (S6435). In this process, the main CPU 6101 uses the address of the special symbol working area table set in the IY register to use the special symbol waiting time management timer area in the special symbol working area table (the first special symbol waiting time in FIG. 166). The value of the upper 2-byte timer stored in the time management timer area or the second special symbol waiting time management timer area in FIG. 168 is read. In this case, the main CPU 6101 can directly read the upper 2 byte timer value of the special symbol from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

Next, the main CPU 6101 performs word counter subtraction processing (S6436). In this process, the main CPU 6101 performs a subtraction process (update process) of the upper 2 byte timer (the special symbol waiting time in the first half of the special symbol) read in S6435.

Next, the main CPU 6101 determines whether or not the special symbol waiting time for the first half of the special symbol has elapsed based on the value of the upper 2 byte timer after the subtraction (S6437).

In S6437, if the main CPU 6101 determines that the special symbol waiting time for the first half of the special symbol has not elapsed (NO determination in S6437), the main CPU 6101 ends the special symbol related timer update process and continues the process. , return to the special symbol control process (see FIGS. 190 and 191). At this time, if the special symbol-related timer update process is called in S6402 during the special symbol control process, the process returns to S6403, and the special symbol-related timer update process is called in S6404 during the special symbol control process. If so, the process returns to S6405.

On the other hand, in S6437, if the main CPU 6101 determines that the special symbol waiting time for the first half of the special symbol has elapsed (YES in S6437), the main CPU 6101 determines that the current timing is the special symbol waiting time for the first half of the special symbol. It is determined whether or not it is the timing when (the value of the upper 2 byte timer) becomes "0" (S6438). Specifically, the main CPU 6101 determines whether the special symbol waiting time (value of the upper 2 byte timer) in the first half of the special symbol has just become "0" by the current subtraction process in S6436.

Note that if the process of determining whether the value of the upper 2 byte timer has exactly reached "0" is not performed, that is, if the process of determining the progress of the upper 2 byte timer is limited to the process of S6437, Even at the timing when the value of the upper 2 byte timer becomes exactly "0" (at the end of counting the first half of the special symbol waiting time), the process of S6440 (lower 2 byte timer (the second half of the special symbol waiting time of the special symbol), which will be described later) is executed. (subtraction processing) will be performed. In this case, the subtraction process of the low-order 2-byte timer is performed by 1 at a timing that is not the time to perform the subtraction (update) process of the low-order 2-byte timer (timing before the first subtraction process of the special symbol waiting time in the second half). Since the waiting time for the special symbol in the second half of the special symbol cannot be counted accurately. However, when the process of S6438 is provided as in this embodiment, the subtraction process of the lower 2-byte timer is not performed at the timing when the value of the upper 2-byte timer just becomes "0", so such a process is not performed. It is possible to prevent malfunctions in the counting process of the lower 2-byte timer and accurately count the special symbol waiting time in the latter half of the special symbol.

In S6438, if the main CPU 6101 determines that the timing is when the special symbol waiting time of the first half of the special symbol becomes "0" (YES in S6438), the main CPU 6101 executes the special symbol related timer update process. It ends and the process returns to the special symbol control process (see FIGS. 190 and 191). At this time, if the special symbol-related timer update process is called in S6402 during the special symbol control process, the process returns to S6403, and the special symbol-related timer update process is called in S6404 during the special symbol control process. If so, the process returns to S6405.

On the other hand, in S6438, the main CPU 6101 is not at the timing when the special symbol waiting time for the first half of the special symbol becomes "0" (the special symbol waiting time for the first half has already become "0" before the subtraction processing in S6436). If the main CPU 6101 determines that the special symbol waiting time management timer area of the special symbol is a The special symbol waiting time in the second half of the symbol is read out (S6439).

Next, the main CPU 6101 performs word counter subtraction processing (S6440). In this process, the main CPU 6101 performs a subtraction process (update process) of the lower 2 byte timer (the special symbol waiting time in the second half of the special symbol) read in S6439.

After the process of S6440, the main CPU 6101 ends the special symbol related timer update process and returns the process to the special symbol control process (see FIGS. 190 and 191). At this time, if the special symbol-related timer update process is called in S6402 during the special symbol control process, the process returns to S6403, and the special symbol-related timer update process is called in S6404 during the special symbol control process. If so, the process returns to S6405.

[Special design management processing]
Next, with reference to FIG. 193, the special symbol management process performed in S6408, S6412, S6416, and S6420 in the special symbol control process (see FIGS. 190 and 191) will be described. FIG. 193 is a flowchart showing the procedure of special symbol management processing.

In addition, in the special symbol management process described below, the "special symbol" to be processed is the special symbol that corresponds to the address of the special symbol work area table set in the IY register at the start of the special symbol management process. be. For example, when the special symbol management process is called and executed in S6408 or S6416 during the special symbol control process, the "special symbol" to be processed in the following explanation becomes the second special symbol, and the special symbol management process When called and executed in S6412 or S6420 during the special symbol control process, the "special symbol" to be processed in the following explanation becomes the first special symbol.

In addition, the numerical values in parentheses (“0” to “6”) written alongside the symbols of each processing step shown in FIG. 193 are the control state numbers of the special symbols to be processed, and are in the special symbol work area table. It is stored in the special symbol control state number area (the first special symbol control state number area in FIG. 166 or the second special symbol control state number area in FIG. 168). Then, the main CPU 6101 advances the special symbol game by executing each processing step corresponding to the control state number.

First, the main CPU 6101 reads the value of the upper 2 byte timer and determines whether there is a special symbol waiting time for the first half of the special symbol (first half special symbol waiting time management timer value≠0) (S6451) . In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol waiting time management timer area (the first special symbol in FIG. 166) in the special symbol work area table. The value of the upper 2 byte timer stored in the waiting time management timer area (or the second special symbol waiting time management timer area in FIG. 168) is read. In this case, the main CPU 6101 can directly read the upper 2 byte timer value of the special symbol from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

In S6451, if the main CPU 6101 determines that there is a special symbol waiting time for the first half of the special symbol (YES in S6451), the main CPU 6101 ends the special symbol management process, and replaces the process with the special symbol control process. (See FIGS. 190 and 191). At this time, if the special symbol management process is called in S6408 during the special symbol control process, the process returns to the process in S6409, and if the special symbol management process is called in S6412 during the special symbol control process, returns the process to S6413. Also, if the special symbol management process is called in S6416 during the special symbol control process, the process returns to the process in S6417, and if the special symbol management process is called in S6420 during the special symbol control process, , the special symbol control process also ends.

On the other hand, in S6451, if the main CPU 6101 determines that there is no special symbol waiting time for the first half of the special symbol (NO determination in S6451), the main CPU 6101 reads the value of the lower 2 byte timer, It is determined whether there is a special symbol waiting time (second half special symbol waiting time management timer value≠0) (S6452). In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol waiting time management timer area (the first special symbol in FIG. 166) in the special symbol work area table. The value of the lower 2-byte timer stored in the waiting time management timer area (or the second special symbol waiting time management timer area in FIG. 168) is read. In this case, the main CPU 6101 can directly read the value of the lower 2 byte timer of the special symbol from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

In S6452, if the main CPU 6101 determines that there is a special symbol waiting time for the latter half of the special symbol (YES in S6452), the main CPU 6101 ends the special symbol management process and transfers the process to the special symbol control process. (See FIGS. 190 and 191). At this time, if the special symbol management process is called in S6408 during the special symbol control process, the process returns to the process in S6409, and if the special symbol management process is called in S6412 during the special symbol control process, returns the process to S6413. Also, if the special symbol management process is called in S6416 during the special symbol control process, the process returns to the process in S6417, and if the special symbol management process is called in S6420 during the special symbol control process, , the special symbol control process also ends.

On the other hand, in S6452, when the main CPU 6101 determines that there is no special symbol waiting time in the latter half of the special symbol (NO determination in S6452), the main CPU 6101 reads the control state number of the special symbol (S6453). In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol control state number area (the first special symbol control in FIG. 166) in the special symbol work area table. The control state number of the special symbol stored in the state number area or the second special symbol control state number area in FIG. 168 is read. In this case, the main CPU 6101 can directly read the control state number of the special symbol from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

Next, the main CPU 6101 performs a special symbol control branch table reference process (S6454). In addition, in the special symbol control branch table, the correspondence relationship between each control state number (“0” to “6”) of the special symbol and the storage address of the corresponding processing program is defined.

Then, the main CPU 6101 performs the processing from S6455 onwards in accordance with the control state number of the special symbol read out at S6453. In addition, the processing contents after S6455 include, for example, the control state number of the special symbol read out in S6453 (any one of "0" to "6"), and the update of the control state number of the special symbol within each processing step. It changes depending on the presence or absence of the special symbol game, that is, the playing situation of the special symbol game.

First, the main CPU 6101 performs special symbol variation start processing (S6455). However, the process of S6455 is performed when the control state number of the special symbol is "0" (special symbol variation start value) at the start of the process. In this process, the main CPU 6101 performs various processes for starting variable display of special symbols (special symbol game). The details of the special symbol variation start process will be described later with reference to FIG. 194, which will be described later. On the other hand, when the control state number of the special symbol is other than "0" at the start of the process of S6455, the process of S6455 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs special symbol variation end processing (S6456). However, the process of S6456 is performed when the control state number of the special symbol is "1" (special symbol variation end value) at the start of the process. In this process, the main CPU 6101 performs various processes when ending the variable display of special symbols. The details of the special symbol variation end process will be described later with reference to FIGS. 196 and 197, which will be described later. On the other hand, when the control state number of the special symbol is other than "1" at the start of the process of S6456, the process of S6456 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs special symbol game determination processing (S6457). However, the process of S6457 is performed when the control state number of the special symbol is "2" (special symbol game determination value) at the start of the process. In this process, the main CPU 6101 performs a process of determining the special symbol derivation result (big hit/small hit/loss). The details of the special symbol game determination process will be explained later with reference to FIGS. 198 and 199, which will be described later. On the other hand, when the control state number of the special symbol is other than "2" at the start of the process of S6457, the process of S6457 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs a grand prize opening preparation process (S6458). However, the process of S6458 is performed when the control state number of the special symbol is "3" (big winning opening opening start value) at the start of the process. In this process, the main CPU 6101 performs, for example, selection processing of the type of big winning opening (special electric accessory), opening pattern of the big winning opening, generation process of opening/closing control data of the special electric accessory, and the like. The details of the grand prize opening preparation process will be described later with reference to FIG. 201, which will be described later. On the other hand, when the control state number of the special symbol is other than "3" at the start of the process of S6458, the process of S6458 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs a big prize opening control process (S6459). However, the process of S6459 is performed when the control state number of the special symbol is "4" (big winning opening control value) at the start of the process. In this processing, the main CPU 6101 performs, for example, opening/closing control processing of the special electric accessory (big prize opening). The details of the big winning opening control process will be described later with reference to FIG. 202, which will be described later. On the other hand, when the control state number of the special symbol is other than "4" at the start of the process of S6459, the process of S6459 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs a grand prize opening preparation process (S6460). However, the process of S6460 is performed when the control state number of the special symbol is "5" (big winning opening preparation value) at the start of the process. In this process, the main CPU 6101 performs, for example, selection processing of the type of big winning opening, opening pattern of the big winning opening, etc., processing of generating opening/closing control data for the special electric accessory, and the like. The details of the grand prize opening preparation process will be described later with reference to FIG. 201, which will be described later. On the other hand, when the control state number of the special symbol is other than "5" at the start of the process of S6460, the process of S6460 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs special symbol per end processing (S6461). However, the process of S6461 is performed when the control state number of the special symbol is "6" (end value per special symbol) at the start of the process. In this process, the main CPU 6101 performs various processes when ending a game (special symbol game) when a special symbol is won. The details of the special symbol per end processing will be explained later with reference to FIG. 203, which will be described later. On the other hand, when the control state number of the special symbol is other than "6" at the start of the process of S6461, the process of S6461 is not performed internally and the process moves to the next process step.

After the process of S6461, the main CPU 6101 ends the special symbol management process and returns the process to the special symbol control process (see FIGS. 190 and 191). At this time, if the special symbol management process is called in S6408 during the special symbol control process, the process returns to the process in S6409, and if the special symbol management process is called in S6412 during the special symbol control process, returns the process to S6413. Also, if the special symbol management process is called in S6416 during the special symbol control process, the process returns to the process in S6417, and if the special symbol management process is called in S6420 during the special symbol control process, , the special symbol control process also ends.

[Special symbol variation start processing]
Next, with reference to FIG. 194, the special symbol variation start process performed in S6455 in the special symbol management process (see FIG. 193) will be described. FIG. 194 is a flowchart showing the procedure of special symbol variation start processing. In addition, in the special symbol variation start process described below, the "special symbol" to be processed is the special symbol corresponding to the address of the special symbol work area table set in the IY register at the start of the special symbol variation start process. It is.

First, the main CPU 6101 determines whether the control state number of the special symbol is "0" (S6471).

In S6471, if the main CPU 6101 determines that the control state number of the special symbol is not "0" (NO determination in S6471), the main CPU 6101 ends the special symbol fluctuation start process and transfers the process to special symbol management. The process returns to S6456 of the process (FIG. 193).

On the other hand, in S6471, when the main CPU 6101 determines that the control state number of the special symbol is "0" (YES in S6471), the main CPU 6101 performs a special symbol game standby process (S6472). In this process, the main CPU 6101 mainly performs a process of checking the game status ("game start" or "game standby"). The details of the special symbol game standby process will be explained later with reference to FIG. 195, which will be described later.

Next, the main CPU 6101 determines whether the gaming state is "game standby" (S6473).

In S6473, if the main CPU 6101 determines that the gaming state is "game standby" (YES in S6473), the main CPU 6101 ends the special symbol fluctuation start process and transfers the process to the special symbol management process ( The process returns to step S6456 in FIG. 193).

On the other hand, in S6473, if the main CPU 6101 determines that the gaming state is not "game standby" ("game start") (NO determination in S6473), the main CPU 6101 performs special symbol storage transfer processing ( S6474). In this process, the main CPU 6101 performs a process of subtracting the number of reserved special symbols, a process of transferring a random number value (lottery result), a process of reserving transmission of a pending subtraction command, etc. In addition, in the transfer process of the random number value (lottery result), the random number value stored in the random number storage area at the time of winning of the special symbol that starts to fluctuate is transferred to the random number work area of the special symbol. Also, at this time, a process of moving the random number value acquired at the time of winning the next variation special symbol to the random number storage area (process of shifting the reserved ball) is also performed.

Next, the main CPU 6101 performs special symbol hit determination processing (S6475). In this process, the main CPU 6101 performs a process of determining the lottery result (big hit/small hit/loss). In addition, in the special symbol hit determination process, first, a process is performed to determine whether or not it is a jackpot, and if it is determined that it is not a jackpot in this process, a process is performed to determine whether or not it is a small hit. If it is determined in the process that it is not a small hit, the determination result is determined to be a loss. The contents of the special symbol hit determination process (S6475) will be detailed later.

Next, the main CPU 6101 performs special symbol determination processing (S6476). In this process, the main CPU 6101 performs a process of determining a special symbol to be stopped corresponding to the lottery determination result (big hit/small hit/loss).

Next, the main CPU 6101 performs special symbol variation pattern setting processing (S6477). In this process, the main CPU 6101 performs lottery processing for the first half variable display pattern and the second half variable display pattern of the special symbol corresponding to the lottery determination result (big hit/small win/loss), and sets each variable display pattern. . Next, the main CPU 6101 performs a special symbol fluctuation display time setting process (S6478). In this process, the main CPU 6101 sets the first half variable display time (first half special symbol waiting time) and the second half variable display time (second half special symbol waiting time) of the special symbol to the upper 2 byte timer and lower 2 byte timer, respectively. set.

Next, the main CPU 6101 performs clearing processing of the designated storage area (S6479). In this process, the random number work area of the special symbol in the main RAM 6103 is cleared, and the random number value acquired at the time of winning of the special symbol whose variation is started is cleared.

Next, the main CPU 6101 sets the control state number of the special symbol to "1" (S6480). Due to this special symbol control state number update process, after the special symbol variation start process ends, a special symbol variation end process (S6456) is performed.

Next, the main CPU 6101 performs gaming state designation parameter setting processing (S6481). In this process, the main CPU 6101 sets (updates) the gaming state number area, gaming state specification parameter area, and production variation table parameter area in the special symbol work area table (see FIG. 166 or 168), and the gaming state specification parameter Transfer processing is performed.

Next, the main CPU 6101 performs interrupt prohibition processing (S6482).

Next, the main CPU 6101 performs gaming state management processing (S6483). In this process, the main CPU 6101 mainly updates various flags related to the management of gaming status. In addition, as other processing, the main CPU 6101 performs, for example, gaming state offset value generation processing, special symbol production mode management processing, etc.

Next, the main CPU 6101 performs transmission reservation processing of a special symbol presentation start command (S6484). The special symbol production start command reserved in this process is transmitted to the sub-control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172).

Next, the main CPU 6101 performs interrupt permission processing (S6485). After the process of S6485, the main CPU 6101 ends the special symbol variation start process and returns the process to the process of S6456 of the special symbol management process (FIG. 193).

(Contents of special symbol hit determination process)
Here, the contents of the special symbol hit determination process performed in S6475 will be explained in more detail. First, the contents of the special symbol hit determination process when the simultaneous fluctuation function is in operation will be explained.

In the special symbol hit determination process, if the special symbol that is not the target of processing (the other special symbol) is already changing, a jackpot will be determined for the special symbol that is the target of processing (the other special symbol). A small hit or a loss determination process is performed without performing a process of determining whether or not the result is a small hit. At this time, if the random number (lottery result) of one special symbol is a random number corresponding to a small hit or loss, the judgment result will be a small hit or a loss, respectively, but the random number of one special symbol If is a random number value corresponding to a jackpot, the random number is determined to be a random number other than a small hit (a random number corresponding to a loss), and the determination result is forced to be a loss. In other words, when one special symbol that is being processed in the special symbol hit determination process starts to fluctuate, if the other special symbol that is not being processed is already fluctuating, the random value of one special symbol Even if is a random number corresponding to a jackpot (even if the lottery result is a jackpot), the variable display of one of the special symbols is controlled to be a variable display corresponding to a loss.

Next, the specific contents of the jackpot/small hit/loss lottery determination process performed in the special symbol hit determination process (S6475) will be explained in more detail.

First, the main CPU 6101 reads the address of the jackpot determination value data table (not shown) of the special symbol to be processed. In addition, in the special symbol jackpot determination value data table, a range of random numbers (lottery value) that will result in a jackpot is defined for each set value (“1” to “6”). In addition, in the special symbol jackpot determination value data table, the range of random numbers that will result in a jackpot in the normal gaming state (low probability gaming state) and variable probability gaming state (high probability gaming state) is defined for each set value. ing. In the special symbol jackpot determination value data table, the range of random numbers that will result in a jackpot is defined in order from the top address side to the smallest setting value. Specifically, in the special symbol jackpot judgment value data table, from the first address side, the range of random numbers that will be a jackpot when the setting is "1" and the normal gaming state is set, and the range of random numbers that will be a jackpot when the setting is "1" and the variable probability gaming state The range of random numbers that will result in a jackpot when the setting is "2" and the normal gaming state is the range of random numbers that will result in a jackpot when the setting is "2" and the variable probability gaming state. The range of numerical values...The range of random numbers that will result in a jackpot when the setting is "6" and the normal gaming state is set. The range of random numbers that will result in a jackpot when the setting is "6" and the variable probability gaming state is this. stored in order.

Next, the main CPU 6101 reads the setting value (loads the contents of the setting value area in the main RAM 6103). Next, the main CPU 6101 doubles the read setting value, and further adds a special symbol probability change state flag value (“0” if it is a normal gaming state, “1” if it is a probability variable game state) to the doubled value. to add. As a result, the address offset value (offset value from the top address) of the storage area where the range of random numbers (lottery value) referred to in the special symbol jackpot determination value data table is stored is calculated. Then, by adding the address offset value to the start address of the jackpot judgment value data table of the special symbol, the storage area of the random number range (lottery value) to be referenced in the jackpot judgment value data table is specified, and the corresponding random number is specified. You can obtain the numerical range (lottery value).

Next, the main CPU 6101 calls a lottery determination process, refers to the random number value and the lottery value, executes the lottery determination process, and obtains a jackpot lottery determination result. At this time, if the special symbol is a jackpot, the lottery determination result will be a value other than "0 (00H)" (for example, "FFH"), and if the special symbol is not a jackpot, the lottery determination result will be "0". . Next, the main CPU 6101 performs an AND operation between the lottery determination result and a preset jackpot flag value (for example, a value other than "0" such as "001H"). Then, if the result of the AND operation is "1", the main CPU 6101 determines that the special symbol being processed is a jackpot, and if the result of the AND operation is "0", the special symbol is determined not to be a jackpot.

Next, if the result of the above-mentioned AND operation is "0" and it is determined that the special symbol is not a jackpot, the main CPU 6101 reads the special symbol selection value. In addition, in this process, the main CPU 6101 uses the address of the special symbol-related definition data table set in the IX register to store the storage area of the special symbol selection value in the special symbol-related definition data table that is the processing target. The special symbol selection value (storage area for the first special symbol selection value in FIG. 167 or storage area for the second special symbol selection value in FIG. 169) stored in is read out. The special symbol selection value is a value indicating the type of special symbol (first special symbol or second special symbol), and is "0" when the special symbol to be processed is the first special symbol; If the special symbol is the second special symbol, it is "1".

Next, the main CPU 6101 reads the address of the special symbol small hit determination value data selection table (not shown). In addition, in the special symbol small hit determination value data selection table, the address of the special symbol small hit determination value data table (not shown) is defined for each type of special symbol. However, for special symbol types that do not have a small hit as a special symbol lottery result, the address of the special symbol small hit judgment value data table is not specified in the special symbol small hit judgment value data selection table. do not have. That is, in this embodiment, the address of the small hit determination value data table for the first special symbol is not defined in the special symbol small hit determination value data selection table.

Next, the main CPU 6101 refers to the special symbol selection value (type of special symbol) and the special symbol small hit determination value data selection table, and sets a small win in the lottery result of the special symbol to be processed. (Whether or not the address of the special symbol small hit determination value data table is defined in the special symbol small hit determination value data selection table.)

In this determination process, if it is determined that a small hit is provided in the lottery result of the special symbol to be processed, the main CPU 6101 selects a random number that is referred to in the small hit determination value data table for the special symbol. Calculate the address of the numerical range (lottery value). In addition, in this determination process, if it is determined that a small win is not provided in the lottery result of the special symbol to be processed, the main CPU 6101 determines that the special symbol is a loss.

Next, if the special symbol lottery results include a small win, the main CPU 6101 calls a lottery determination process, refers to the random number value and the lottery value, executes the lottery determination process, and determines the small win lottery result. Obtain the judgment result. At this time, if the special symbol is a small win, the lottery determination result will be a value other than "0", and if the special symbol is not a small win, the lottery determination result will be "0". Note that the lottery determination process read out in this small hit determination process is the same as the lottery determination process read out in the jackpot determination process described above. That is, in this embodiment, a common process (module) is used for the lottery determination process of jackpot/small win/loss.

Next, the main CPU 6101 performs an AND operation between the small winning lottery determination result and a preset small winning flag value (for example, a value other than "0" such as "002H"). Then, if the result of the AND operation is "1", the main CPU 6101 determines that the special symbol being processed is a small hit, and if the result of the AND operation is "0", the main CPU 6101 determines that the special symbol being processed is a small hit. It is determined that the pattern is a loss.

As described above, in this embodiment, a common process (module) is used for the jackpot/small win/loss lottery determination process performed in the special symbol hit determination process (S6475). Therefore, in this embodiment, the capacity of the processing program managed by the main control circuit 6100 can be reduced.

In addition, in this embodiment, as mentioned above, the small hit determination value data selection table of the special symbol is referred to, and only when a small hit is provided in the lottery result of the special symbol to be processed, the small hit is determined. Although an example has been described in which a winning lottery determination process is performed, the present invention is not limited to this.

For example, the read special symbol selection value is used as an argument for lottery determination processing (an identifier indicating the type of special symbol), and the lottery determination processing is executed by referring to the random number value and lottery value corresponding to this argument. A winning lottery determination result may be obtained. In this case, there is no need to provide the above-mentioned special symbol small hit determination value data selection table, and the capacity of data managed by the main control circuit 6100 can be further reduced. In addition, in this case, various processes executed by referring to the special symbol small hit judgment value data selection table can be omitted, so the capacity of the processing program managed by the main control circuit 6100 can also be reduced. .

[Special symbol game standby processing]
Next, with reference to FIG. 195, the special symbol game standby process performed in S6472 during the special symbol variation start process (see FIG. 194) will be described. FIG. 195 is a flowchart showing the procedure of special symbol game standby processing. In addition, in the special symbol game standby process explained below, the "special symbol" to be processed is the special symbol corresponding to the address of the special symbol work area table set in the IY register at the start of the special symbol game standby process. It is.

First, the main CPU 6101 reads the value of the special symbol suspension flag (S6491). In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol rest flag area in the special symbol work area table (the first special symbol rest flag area in FIG. 166). Or read the value of the special symbol suspension flag stored in the second special symbol suspension flag area (in FIG. 168). In this case, the main CPU 6101 can directly read the value of the special symbol suspension flag from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

Next, the main CPU 6101 determines whether the special symbol pause flag is set (on state) or not (S6492).

In S6492, if the main CPU 6101 determines that the special symbol suspension flag is set (YES in S6492), the main CPU 6101 performs the process of S6503, which will be described later.

On the other hand, in S6492, when the main CPU 6101 determines that the special symbol suspension flag is not set (NO in S6492), the main CPU 6101 reads the number of reserved special symbols (S6493). In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol reservation number area in the special symbol work area table (the first special symbol reservation number area in FIG. 166). Alternatively, the number of reserved special symbols stored in the second special symbol reserved number area in FIG. 168 is read out. In this case, the main CPU 6101 can directly read the reserved number of special symbols from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

Next, the main CPU 6101 determines whether the number of reserved special symbols is "0" (S6494).

In S6494, if the main CPU 6101 determines that the number of reserved special symbols is not "0" (NO in S6494), the main CPU 6101 sets the gaming state to "game start" (S6495). After the process of S6495, the main CPU 6101 ends the special symbol game standby process and returns the process to the process of S6473 of the special symbol variation start process (FIG. 194).

On the other hand, in S6494, when the main CPU 6101 determines that the number of reserved special symbols is "0" (YES in S6494), the main CPU 6101 reads the special symbol demo flag value (S6496). The special symbol demo flag is a flag indicating whether or not the current gaming state is in a demonstration (on standby), and if the current gaming state is on standby, the special symbol demo flag is turned on. In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol demo display state flag area (the first special symbol demo in FIG. 166) in the special symbol work area table. The special symbol demo flag value stored in the display state flag area (or the second special symbol demo display state flag area in FIG. 168) is read out. In this case, the main CPU 6101 can directly read the special symbol demo flag value from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

Next, the main CPU 6101 determines whether the current gaming state is in the demonstration based on the value of the special symbol demo flag read in S6496 (S6497).

In S6497, if the main CPU 6101 determines that the current gaming state is in the demonstration mode (YES in S6497), the main CPU 6101 performs processing in S6503, which will be described later.

On the other hand, if the main CPU 6101 determines in S6497 that the current gaming state is not in the demonstration mode (NO determination in S6497), the main CPU 6101 sets the demo display command sent flag (S6498). In this process, the main CPU 6101 subtracts 1 from the value of the special symbol demo display state flag area in the special symbol work area table using the data set in the IY register (address of the special symbol work area table).

Next, the main CPU 6101 performs interrupt prohibition processing (S6499). Next, the main CPU 6101 performs gaming state designation parameter setting processing (S6500). In this process, the main CPU 6101 sets (updates) the gaming state number area, gaming state specification parameter area, and production variation table parameter area in the special symbol work area table (see FIG. 166 or 168), and the gaming state specification parameter Transfer processing is performed.

Next, the main CPU 6101 performs transmission reservation processing for a demonstration display command (S6501). The demonstration display command reserved in this process is transmitted to the sub-control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172). Next, the main CPU 6101 performs interrupt permission processing (S6502).

After the process of S6502, or if the determination is YES in S6492 or S6497, the main CPU 6101 sets the gaming state to "game standby" (S6503). After the process of S6503, the main CPU 6101 ends the special symbol game standby process and returns the process to the process of S6473 of the special symbol variation start process (FIG. 194).

As mentioned above, in the special symbol game standby process of this embodiment, if the special symbol suspension flag is set (on state) for the special symbol to be processed, the special symbol is suspended. A series of processes from S6493 to S6502, including various processes related to numbers, various processes related to demonstration display, etc., are not executed. Therefore, in the pachinko game machine 6001 of this embodiment, the special symbol game standby process can be simplified. In this case, the capacity of the processing programs managed by the main control circuit 6100 can be reduced, and the processing performed by the main control circuit 6100 can be executed more efficiently, thereby reducing the processing load on the main control circuit 6100. .

[Special symbol variation end processing]
Next, with reference to FIGS. 196 and 197, the special symbol variation end process performed at S6456 in the special symbol management process (see FIG. 193) will be described. FIG. 196 and FIG. 197 are flowcharts showing the procedure of special symbol variation end processing. In addition, in the special symbol fluctuation end processing described below, "one special symbol" to be processed corresponds to the address of the special symbol work area table set in the IY register at the start of the special symbol fluctuation end processing. It is a special symbol, and the "other special symbol" is a special symbol corresponding to the address of the special symbol work area table that is not set in the IY register at the start of the special symbol variation end process.

First, the main CPU 6101 determines whether the control state number of one special symbol is "1" (S6511).

In S6511, if the main CPU 6101 determines that the control state number of one of the special symbols is not "1" (NO determination in S6511), the main CPU 6101 ends the special symbol variation end process, and continues the process with the special symbol. The process returns to S6457 of the symbol management process (FIG. 193).

On the other hand, in S6511, if the main CPU 6101 determines that the control state number of one special symbol is "1" (YES in S6511), the main CPU 6101 determines the special symbol pause flag value of one special symbol. is read out (S6512). In this process, the main CPU 6101 uses the address of one special symbol work area table set in the IY register to use the special symbol suspension flag area (the first special symbol in FIG. 166) in one special symbol work area table. The special symbol suspension flag value stored in the symbol suspension flag area (or the second special symbol suspension flag area in FIG. 168) is read out. In this case, the main CPU 6101 can directly read the special symbol suspension flag value of one special symbol from the work area in the main RAM 6103 without performing address reference processing of the one special symbol work area table.

Next, the main CPU 6101 determines whether the special symbol suspension flag of one of the special symbols is set (on state) or not (S6513).

In S6513, if the main CPU 6101 determines that the special symbol suspension flag of one of the special symbols is set (YES in S6513), the main CPU 6101 terminates the special symbol fluctuation end processing, and The process returns to S6457 of the special symbol management process (FIG. 193).

On the other hand, in S6513, if the main CPU 6101 determines that the special symbol suspension flag of one of the special symbols is not set (NO determination in S6513), the main CPU 6101 changes the control state number of one of the special symbols to " 2” (S6514). By this updating process of the control state number of one special symbol, a special symbol game determination process (S6457) is performed for one special symbol after the end of the special symbol variation end process.

Next, the main CPU 6101 performs transmission reservation processing of a special symbol production stop command for one of the special symbols (S6515). Note that the special symbol production stop command for one of the special symbols reserved in this process is sent to the sub control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172). be exposed.

Next, the main CPU 6101 adds 1 to the value of the confirmed symbol number counter (S6516). The confirmed symbol number counter is a counter for counting the number of confirmed special symbols (the number of times the special symbol is displayed in a variable manner), and the counted value is stored in the confirmed symbol number counter area in the main RAM 6103.

Next, the main CPU 6101 reads the address of the storage area of the special symbol suspension flag value of the other special symbol (S6517). In this process, the main CPU 6101 uses the address of one special symbol-related definition data table set in the IX register to create a special symbol of the other special symbol stored in one special symbol-related definition data table. Read the address of the pause flag storage area (the storage area for the address of the second special symbol pause flag area in FIG. 167 or the storage area for the address of the first special symbol pause flag area in FIG. 169). In this case, the main CPU 6101 uses the main RAM 6103 without performing address reference processing (reading processing) of the other special symbol-related definition data table and switching processing of the address of the special symbol-related definition data table set in the IX register. It is possible to directly read the address of the storage area of the special symbol suspension flag value of the other special symbol from the work area (one special symbol related definition data table).

Next, the main CPU 6101 performs a small hit confirmation process (S6518). In this process, the main CPU 6101 stores data in the special symbol per flag area (the first special symbol per flag area in FIG. 166 or the second special symbol per flag area in FIG. 168) in one of the special symbol work area tables. Based on the value, a process is performed to confirm whether the fluctuating display of one of the special symbols corresponds to a small hit.

Next, the main CPU 6101 determines whether the fluctuating display of one of the special symbols is a small hit (S6519).

In S6519, if the main CPU 6101 determines that the fluctuating display of one of the special symbols is not a small hit (NO determination in S6519), the main CPU 6101 performs processing in S6521, which will be described later. On the other hand, in S6519, if the main CPU 6101 determines that the fluctuating display of one special symbol is a small hit (YES in S6519), the main CPU 6101 sets the special symbol pause flag in the other special symbol pause flag area. A value (on value) is set (S6520).

After the process in S6520, or if the determination in S6519 is NO, the main CPU 6101 performs a jackpot confirmation process (S6521). In this process, the main CPU 6101 stores data in the special symbol per flag area (the first special symbol per flag area in FIG. 166 or the second special symbol per flag area in FIG. 168) in one of the special symbol work area tables. Based on the value, a confirmation process is performed to determine whether the fluctuating display of one of the special symbols corresponds to a jackpot.

Next, the main CPU 6101 determines whether the fluctuating display of one of the special symbols is a jackpot (S6522).

In S6522, if the main CPU 6101 determines that the fluctuating display of one of the special symbols is not a jackpot (NO determination in S6522), the main CPU 6101 ends the special symbol fluctuation end process and transfers the process to the special symbol management process. The process returns to step S6457 (FIG. 193).

On the other hand, in S6522, if the main CPU 6101 determines that the fluctuating display of one special symbol is a jackpot (YES in S6522), the main CPU 6101 sets the special symbol pause flag value in the other special symbol pause flag area. (ON value) is set (S6523).

Next, the main CPU 6101 sets the address of the other special symbol related definition data table in the main RAM 6103 to the IX register, and sets the address of the other special symbol work area table to the IY register (S6524).

Next, the main CPU 6101 determines whether the other special symbol is being displayed in a variable manner (S6525). In this process, the main CPU 6101 controls the special symbol control state number area in the other special symbol work area table (the first special symbol control state number area in FIG. 166 or the second special symbol control state number area in FIG. 168). It is determined whether the control state number of the other special symbol stored in is "1" or not, and if the control state number of the other special symbol is "1", the determination process of S6525 is determined as YES. Therefore, if the control state number of the other special symbol is not "1", the determination process of S6525 becomes a NO determination.

In S6525, if the main CPU 6101 determines that the other special symbol is not being displayed in a variable manner (NO determination in S6525), the main CPU 6101 ends the special symbol variation end process and transfers the process to the special symbol management process ( The process returns to step S6457 in FIG. 193).

On the other hand, in S6525, when the main CPU 6101 determines that the other special symbol is being displayed in a variable manner (YES in S6525), the main CPU 6101 adds 1 to the value of the determined symbol number counter (S6526).

Next, the main CPU 6101 performs a fluctuation stop flag setting process (S6527). Through this process, the sight test signal is output to the outside.

Next, the main CPU 6101 sets a loss to the hit flag of the other special symbol (S6528). Specifically, the main CPU 6101 places a loss in the special symbol per flag area (the first special symbol per flag area in FIG. 166 or the second special symbol per flag area in FIG. 168) in the other special symbol work area table. Set the value corresponding to .

Next, the main CPU 6101 performs processing to clear the work area related to the variable display of the other special symbol (S6529). Next, the main CPU 6101 sets a predetermined fixed waiting time in the upper 2 byte timer for special symbol waiting time management of the other special symbol (S6530).

Next, the main CPU 6101 sets the control state number of the other special symbol to "2" (S6531). By this process of updating the control state number of the other special symbol, the special symbol variation end process is no longer performed for the other special symbol.

Next, the main CPU 6101 performs a game state designation parameter setting process for the other special symbol (S6532). In this process, the main CPU 6101 performs setting (update) processing of the gaming state number area, gaming state specification parameter area, and production variation table parameter area in the other special symbol work area table (see FIG. 166 or 168), and the gaming state Performs transfer processing of specified parameters.

Next, the main CPU 6101 performs transmission reservation processing of the special symbol production stop command for the other special symbol (S6533). Note that the special symbol production stop command for the other special symbol reserved in this process is sent to the sub-control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172). be exposed. After the process of S6533, the main CPU 6101 ends the special symbol variation end process and returns the process to the process of S6457 of the special symbol management process (FIG. 193).

As mentioned above, in the special symbol variation end process of this embodiment, if the special symbol suspension flag is set (on state) for one special symbol, small hit confirmation for one special symbol is performed. Processing after S6514, including processing and jackpot confirmation processing, is not performed. Therefore, in the pachinko game machine 6001 of this embodiment, the special symbol variation termination process can be simplified. In this case, the capacity of the processing programs managed by the main control circuit 6100 can be reduced, and the processing performed by the main control circuit 6100 can be executed more efficiently, thereby reducing the processing load on the main control circuit 6100. .

In addition, as described above, in the special symbol variation end process of this embodiment, if the lottery result of one special symbol is a jackpot or a small win in the series of processing from S6518 to S6524, in any case, , sets the special symbol pause flag for the other special symbol (turns it on). That is, when the lottery result of one special symbol is a jackpot or a small prize, the stop or interruption of the start of fluctuation of the other special symbol can be controlled using a common flag (special symbol suspension flag). Therefore, in the pachinko gaming machine 6001 of this embodiment, the special symbol variation termination process can be simplified, and the capacity of the processing program managed by the main control circuit 6100 can be reduced.

Furthermore, as described above, in the special symbol variation end process of this embodiment, the special symbol suspension flag is not set for one of the special symbols, and the lottery result of one of the special symbols is a jackpot, and When the other special symbol is being displayed in a variable manner, a control process (loss confirmation process) is forcibly performed to confirm the loss in the variable display of the other special symbol. Specifically, in the loss confirmation process, the special symbol hit flag of the other special symbol is set to loss (S6528), and the control state number of the other special symbol is set to "2" (S6531: Processing such as preventing the special symbol variation end processing from being performed is performed. If such a loss confirmation process is provided, the special symbol suspension flag is not set for one special symbol, the lottery result of one special symbol is a jackpot, and the other special symbol is displayed in a variable manner. When it is inside, the fluctuation display of the other special symbol is forcibly changed to a loss, and the control status number of the other special symbol is advanced, so unnecessary processing such as confirmation processing of jackpot or small hit for the other special symbol is unnecessary. (Special symbol variation end processing) can be omitted. That is, when the above process of S6531 is provided in a pachinko game machine equipped with a simultaneous variation function as in this embodiment, normally the special symbol variation end process is performed when the special symbol variation display time has elapsed. In this embodiment, when the stop mode of the fluctuation display of one identification information is to shift to a special gaming state, the processing at the end of fluctuation of the other special symbol can be simplified. Therefore, in this embodiment, by providing the above-mentioned loss confirmation process, the special symbol variation end process can be simplified. As a result, the processing performed by the main control circuit 6100 can be executed more efficiently, and the processing load on the main control circuit 6100 can be reduced.

[Special symbol game judgment processing]
Next, with reference to FIGS. 198 and 199, the special symbol game determination process performed in S6457 in the special symbol management process (see FIG. 193) will be described. 198 and 199 are flowcharts showing the procedure of special symbol game determination processing. In addition, in the special symbol game determination process described below, the "special symbol" to be processed is the special symbol corresponding to the address of the special symbol work area table set in the IY register at the start of the special symbol game determination process. It is.

First, the main CPU 6101 determines whether the control state number of the special symbol is "2" (S6541).

In S6541, if the main CPU 6101 determines that the control state number of the special symbol is not "2" (NO determination in S6541), the main CPU 6101 ends the special symbol game determination process and transfers the process to special symbol management. The process returns to step S6458 of the process (FIG. 193). On the other hand, in S6541, when the main CPU 6101 determines that the control state number of the special symbol is "2" (YES in S6541), the main CPU 6101 performs interrupt prohibition processing (S6542).

Next, the main CPU 6101 performs jackpot confirmation processing (S6543). In this process, the main CPU 6101 uses the data set in the IY register (the address of the special symbol work area table) to use the special symbol per flag area in the special symbol work area table (the first special symbol in FIG. 166). The winning flag value of the special symbol is directly read from the winning flag area or the second special symbol winning flag area in FIG. conduct.

Next, the main CPU 6101 determines whether or not it is a jackpot time (S6544).

In S6544, if the main CPU 6101 determines that it is a jackpot (YES determination in S6544), the main CPU 6101 performs processing in S6549, which will be described later.

On the other hand, if the main CPU 6101 determines in S6544 that it is not a jackpot (NO determination in S6544), the main CPU 6101 performs a small hit confirmation process (S6545). In this process, the main CPU 6101 uses the data set in the IY register (the address of the special symbol work area table) to use the special symbol per flag area in the special symbol work area table (the first special symbol in FIG. 166). The winning flag value of the special symbol is directly read from the winning flag area (or the second special symbol winning flag area in FIG. 168), and based on this winning flag value, it is confirmed whether the lottery result of the special symbol is a small hit or not. I do.

Next, the main CPU 6101 determines whether or not it is a small hit (S6546).

In S6546, when the main CPU 6101 determines that it is a small hit (YES determination in S6546), the main CPU 6101 performs processing in S6549, which will be described later.

On the other hand, in S6546, if the main CPU 6101 determines that it is not a small hit (NO determination in S6546), the main CPU 6101 performs special symbol game end processing (S6547). The details of the special symbol game ending process will be explained later with reference to FIG. 200, which will be described later.

Next, the main CPU 6101 performs interrupt permission processing (S6548). After the process of S6548, the main CPU 6101 ends the special symbol game determination process and returns the process to the process of S6458 of the special symbol management process (FIG. 193).

Here, returning to the processing of S6544 and S6546 again, if the determination is YES in S6544 or S6546, the main CPU 6101 performs a start setting process for the variable display of special symbols at the time of a jackpot or a small win (S6549). In this process, the main CPU 6101 generates and updates a special symbol hit signal (big hit signal or small hit signal) that is output via the external terminal board 6140 according to the specified special symbol (special symbol selection value). I do.

Next, the main CPU 6101 performs a process of setting round display LED data according to the designated special symbol (S6550). Next, the main CPU 6101 performs processing to set the upper limit of the number of openings of the big winning hole according to the designated special symbol (S6551).

Next, the main CPU 6101 performs a process of setting a large winning opening operation selection offset value according to the specified special symbol (S6552). In addition, the big winning opening operation selection offset value is a relative address value from the top address of the selection table when determining the opening/closing operation pattern of the big winning opening from the selection table. Next, the main CPU 6101 performs processing to set a jackpot signal according to the designated special symbol (S6553).

Next, the main CPU 6101 sets the start display time per special symbol (S6554). In this process, the main CPU 6101 determines the start display time per special symbol in the special symbol waiting time management timer area in the special symbol work area table (the first special symbol waiting time management timer area in FIG. 166 or the first special symbol waiting time management timer area in FIG. 168). 2) Set in the upper 2 byte timer of the special symbol waiting time management timer area).

Next, the main CPU 6101 sets the control state number of the special symbol to "3" (S6555). By the updating process of the control state number of this special symbol, after the end of the special symbol game determination process, the big winning opening preparation process (S6458) is performed.

Next, the main CPU 6101 performs special symbol game state designation parameter setting processing (S6556). In this process, the main CPU 6101 sets (updates) the gaming state number area, gaming state specification parameter area, and production variation table parameter area in the special symbol work area table (see FIG. 166 or 168), and the gaming state specification parameter Transfer processing is performed.

Next, the main CPU 6101 performs a transmission reservation process of a start display command per special symbol (S6557). Note that the special symbol per start display command reserved in this process is transmitted to the sub control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172).

Next, the main CPU 6101 performs interrupt permission processing (S6558). After the process of S6558, the main CPU 6101 ends the special symbol game determination process and returns the process to the process of S6458 of the special symbol management process (FIG. 193).

[Special symbol game end processing]
Next, with reference to FIG. 200, the special symbol game end process performed in S6547 in the special symbol game determination process (see FIGS. 198 and 199) will be described. FIG. 200 is a flowchart showing the procedure of special symbol game end processing. In addition, in the special symbol game end process described below, the "special symbol" to be processed is the special symbol corresponding to the address of the special symbol work area table set in the IY register at the start of the special symbol game end process. It is.

First, the main CPU 6101 sets the control state number of the special symbol to "0" (S6561). Next, the main CPU 6101 performs special symbol game state designation parameter setting processing (S6562). In this process, the main CPU 6101 sets (updates) the gaming state number area, gaming state specification parameter area, and production variation table parameter area in the special symbol work area table (see FIG. 166 or 168), and the gaming state specification parameter Transfer processing is performed.

Next, the main CPU 6101 performs transmission reservation processing of a special symbol game end command (S6563). Note that the special symbol game end command reserved in this process is sent to the sub control circuit 6200 in the performance control command sending process (S6022) in the next system timer interrupt process (FIG. 172). After the process of S6563, the main CPU 6101 ends the special symbol game end process and returns the process to the process of S6548 of the special symbol game determination process (FIGS. 198 and 199).

[Big prize opening preparation process]
Next, with reference to FIG. 201, the big winning opening preparation process performed in S6458 and S6460 in the special symbol management process (see FIG. 193) will be described. FIG. 201 is a flowchart showing the procedure of the grand prize opening preparation process. In addition, in the grand prize opening preparation process described below, the "special symbol" to be processed corresponds to the address of the special symbol work area table that is set in the IY register at the start of the grand prize opening preparation process. It is a special design.

First, the main CPU 6101 determines whether the control state number of the special symbol is "3" or "5" (S6571).

In S6571, if the main CPU 6101 determines that the control state number of the special symbol is neither "3" nor "5" (NO determination in S6571), the main CPU 6101 ends the grand prize opening preparation process. Then, the process returns to the special symbol management process (FIG. 193). At this time, if the big winning opening preparation process is called in S6458 during the special symbol management process, the process is returned to S6459, and the big winning opening preparation process is called in S6460 during the special symbol management process. If so, the process returns to S6461.

On the other hand, in S6571, if the main CPU 6101 determines that the control state number of the special symbol is "3" or "5" (YES in S6571), the main CPU 6101 sets the grand prize opening number counter value. Read out (S6572). The big winning hole opening number counter is a counter that counts the number of times the big winning hole is opened, and the counted value (big winning hole opening number counter value) is stored in the big winning hole opening number counter area in the main RAM 6103. .

Next, the main CPU 6101 determines whether the grand prize opening number counter value is the upper limit value of the number of openings of the grand prize opening (S6573).

In S6573, when the main CPU 6101 determines that the grand prize opening number counter value is not the upper limit value of the number of openings of the grand prize opening (NO in S6573), the main CPU 6101 performs the process of S6578, which will be described later.

On the other hand, in S6573, if the main CPU 6101 determines that the grand prize opening count counter value is the upper limit of the number of openings of the grand prize opening (YES in S6573), the main CPU 6101 determines the end display time per special symbol. is set (S6574). In this process, the main CPU 6101 calculates the end display time per special symbol in the special symbol waiting time management timer area in the special symbol work area table (the first special symbol waiting time management timer area in FIG. 166 or the first special symbol waiting time management timer area in FIG. 168). 2) Set in the upper 2 byte timer of the special symbol waiting time management timer area).

Next, the main CPU 6101 sets the control state number of the special symbol to "6" (S6575). By the update process of the control state number of this special symbol, the special symbol per end process (S6461) is performed after the completion of the big winning opening preparation process.

Next, the main CPU 6101 performs special symbol game state designation parameter setting processing (S6576). In this process, the main CPU 6101 sets (updates) the gaming state number area, gaming state specification parameter area, and production variation table parameter area in the special symbol work area table (see FIG. 166 or 168), and the gaming state specification parameter Transfer processing is performed.

Next, the main CPU 6101 performs a transmission reservation process for a special symbol per end display command (S6577). Note that the special symbol per end display command reserved in this process is sent to the sub control circuit 6200 in the production control command sending process (S6022) during the next system timer interrupt process (FIG. 172). After the process of S6577, the main CPU 6101 ends the big winning opening preparation process and returns the process to the special symbol management process (FIG. 193). At this time, if the big winning opening preparation process is called in S6458 during the special symbol management process, the process is returned to S6459, and the big winning opening preparation process is called in S6460 during the special symbol management process. If so, the process returns to S6461.

Here, returning to the process of S6573 again, if the determination in S6573 is NO, the main CPU 6101 increments the grand prize opening number counter value by 1 (S6578). Next, the main CPU 6101 performs selection processing of the opening pattern of the grand prize opening (S6579). Next, the main CPU 6101 performs a process of selecting a big winning opening (S6580).

Next, the main CPU 6101 performs a process of selecting an opening pattern in the round of the selected big winning hole (S6581). Next, the main CPU 6101 performs a selection process of setting data (table) for controlling the opening of the selected big winning hole (S6582).

Next, the main CPU 6101 performs opening/closing control processing for the special electric accessory (S6583). In this process, the main CPU 6101 performs a process of generating opening/closing control data for the special electric accessories (shutters 6053a, 6054a).

Next, the main CPU 6101 sets the control state number of the special symbol to "4" (S6584). By the process of updating the control state number of this special symbol, after the completion of the special winning hole opening preparation process, the big winning hole opening control process (S6459) is performed.

Next, the main CPU 6101 performs special symbol game state designation parameter setting processing (S6585). In this process, the main CPU 6101 sets (updates) the gaming state number area, gaming state specification parameter area, and production variation table parameter area in the special symbol work area table (see FIG. 166 or 168), and the gaming state specification parameter Transfer processing is performed.

Next, the main CPU 6101 performs transmission reservation processing of the large prize opening display command (S6586). In addition, the transmission of the big prize opening display command reserved in this process to the sub-control circuit 6200 is performed in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172). After the process of S6586, the main CPU 6101 ends the big winning opening preparation process and returns the process to the special symbol management process (FIG. 193). At this time, if the big winning opening preparation process is called in S6458 during the special symbol management process, the process is returned to S6459, and the big winning opening preparation process is called in S6460 during the special symbol management process. If so, the process returns to S6461.

[Big prize opening control process]
Next, with reference to FIG. 202, the big winning opening control process performed in S6459 in the special symbol management process (see FIG. 193) will be described. FIG. 202 is a flowchart showing the procedure of the big winning opening control process. In addition, in the big winning opening control process described below, the "special symbol" to be processed corresponds to the address of the special symbol work area table that is set in the IY register at the start of the big winning opening opening control process. It is a special design.

First, the main CPU 6101 determines whether the control state number of the special symbol is "4" (S6591).

In S6591, if the main CPU 6101 determines that the control state number of the special symbol is not "4" (NO determination in S6591), the main CPU 6101 ends the big winning opening control process and continues the process with the special symbol. The process returns to S6460 of the management process (FIG. 193).

On the other hand, in S6591, when the main CPU 6101 determines that the control state number of the special symbol is "4" (YES in S6591), the main CPU 6101 reads the big winning opening winning counter value (S6592). The grand prize opening winning counter is a counter that counts the number of winnings (number of rounds) of the grand winning opening, and the counted value (big winning opening winning counter value) is stored in the grand winning opening winning counter area in the main RAM 6103. Ru.

Next, the main CPU 6101 determines whether or not a specified number of prizes have been won in the grand prize opening (S6593). In S6593, when the main CPU 6101 determines that the specified number of prizes have been won in the grand prize opening (YES in S6593), the main CPU 6101 performs processing in S6597, which will be described later.

On the other hand, in S6593, if the main CPU 6101 determines that the specified number of prizes have not been won in the grand prize opening (NO determination in S6593), the main CPU 6101 determines whether the time of the special electric accessory operation management timer has elapsed or not. is determined (S6594).

In S6594, if the main CPU 6101 determines that the time of the special electric accessory operation management timer has not elapsed (NO determination in S6594), the main CPU 6101 ends the big prize opening control process and continues the process. , the process returns to S6460 of the special symbol management process (FIG. 193).

On the other hand, if the main CPU 6101 determines in S6594 that the time of the special electric accessory operation management timer has elapsed (YES in S6594), the main CPU 6101 controls the opening/closing of the special electric accessory (shutters 6053a, 6054a). Control processing is performed (S6595). In this process, the main CPU 6101 sets the continuation or termination of the operating state of the special electric accessory, and when continuing, performs processing to generate opening/closing control data for the special electric accessory. The special electric accessory opening/closing control process called in S6595 is the same process as the special electric accessory opening/closing control process called in S6583 during the grand prize opening preparation process (see Figure 201), and there is no difference between the two processes. In this case, a common process is used.

Next, the main CPU 6101 determines whether to continue the operating state of the special electric accessories (shutters 6053a, 6054a) (S6596).

In S6596, if the main CPU 6101 determines to continue the operating state of the special electric accessory (YES in S6596), the main CPU 6101 ends the big winning opening control process and replaces the process with the special symbol management process. The process returns to step S6460 (FIG. 193). On the other hand, in S6596, if the main CPU 6101 determines that the operating state of the special electric accessory is not to be continued (if S6596 is a NO determination), or if S6593 is a YES determination, the main CPU 6101 closes the grand prize opening. Setting processing is performed (S6597).

Next, the main CPU 6101 sets the inter-round display time (S6598). In this process, the main CPU 6101 calculates the inter-round display time in the special symbol waiting time management timer area in the special symbol work area table (the first special symbol waiting time management timer area in FIG. 166 or the second special symbol waiting time management timer area in FIG. 168). Set it in the upper 2 byte timer of the symbol waiting time management timer area).

Next, the main CPU 6101 sets the control state number of the special symbol to "5" (S6599). By the update process of the control state number of this special symbol, after the end of the big winning hole opening control process, the big winning hole opening preparation process (S6460) is performed.

Next, the main CPU 6101 performs special symbol game state designation parameter setting processing (S6600). In this process, the main CPU 6101 sets (updates) the gaming state number area, gaming state specification parameter area, and production variation table parameter area in the special symbol work area table (see FIG. 166 or 168), and the gaming state specification parameter Transfer processing is performed.

Next, the main CPU 6101 performs transmission reservation processing for an inter-round display command (S6601). Note that the inter-round display command reserved in this process is transmitted to the sub-control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172). After the process of S6601, the main CPU 6101 ends the big prize opening control process and returns the process to the process of S6460 of the special symbol management process (FIG. 193).

[Special symbol per end processing]
Next, with reference to FIG. 203, the special symbol per end process performed in S6461 in the special symbol management process (see FIG. 193) will be described. FIG. 203 is a flowchart showing the procedure of special symbol per end processing. In addition, in the special symbol per end processing explained below, the "special symbol" to be processed is the special symbol corresponding to the address of the special symbol work area table set in the IY register at the start of the special symbol per end processing. It is.

First, the main CPU 6101 determines whether the control state number of the special symbol is "6" (S6611).

In S6611, if the main CPU 6101 determines that the control state number of the special symbol is not "6" (NO determination in S6611), the main CPU 6101 terminates the special symbol per end processing and starts the special symbol management processing ( FIG. 193) also ends. On the other hand, in S6611, when the main CPU 6101 determines that the control state number of the special symbol is "6" (YES in S6611), the main CPU 6101 performs interrupt prohibition processing (S6612).

Next, the main CPU 6101 performs a process of setting end common data per special symbol (S6613). Next, the main CPU 6101 resets (turns off) the special symbol suspension flag of the special symbol (S6614). In this process, the main CPU 6101 stores the information stored in the special symbol suspension flag area (the first special symbol suspension flag area in FIG. 166 or the second special symbol suspension flag area in FIG. 168) in the special symbol work area table. Set the special symbol pause flag value to the off value.

Next, the main CPU 6101 performs special symbol per end setting data selection processing (S6615). Next, the main CPU 6101 performs special symbol game end setting processing (S6616).

Next, the main CPU 6101 performs the special symbol game end process described in FIG. 200 (S6617). In addition, by this process, the control state number of the special symbol is updated to "0".

Next, the main CPU 6101 performs interrupt permission processing (S6618). After the process of S6618, the main CPU 6101 ends the special symbol per end process and also ends the special symbol management process (FIG. 193).

[Normal symbol control processing]
Next, with reference to FIG. 204, the normal symbol control process performed at S6235 in the main control main process (see FIGS. 182 to 185) will be described. FIG. 204 is a flowchart showing the procedure of normal symbol control processing.

Furthermore, the numerical values in parentheses (“0” to “4”) written alongside the processing name of each processing step shown in FIG. 204 are the control state numbers of the normal symbols, and this control state number is Stored in the symbol control state number area. The main CPU 6101 advances the normal symbol game by executing each processing step corresponding to the control state number of the normal symbol.

First, the main CPU 6101 determines whether there is a normal symbol waiting time (remaining variable display time of the normal symbol) (whether or not the normal symbol waiting time management timer value≠0) (S6701).

In S6701, if the main CPU 6101 determines that there is a normal symbol waiting time (YES in S6701), the main CPU 6101 terminates the normal symbol control process and continues the process with the main control main process (FIGS. 182 to 182). 185) returns to the process of S6236. In addition, in S6701, when the main CPU 6101 determines that there is no normal symbol waiting time (NO determination in S6701), the main CPU 6101 reads the control state number of the normal symbol (S6702).

Then, the main CPU 6101 performs the processing from S6703 onwards in accordance with the control state number of the read normal symbol. In addition, the processing contents after S6703 include, for example, the control state number of the normal symbol read out in S6702 (any of "0" to "4"), and the update of the control state number of the normal symbol within each processing step. It changes depending on the presence or absence of the game, that is, the playing situation of the normal symbol game.

First, the main CPU 6101 performs normal symbol variation start processing (S6703). However, the process of S6703 is performed when the control state number of the normal symbol is "0" at the start of this process. In this process, the main CPU 6101 performs, for example, normal symbol information transfer processing, normal symbol hit determination processing, normal symbol determination processing, normal symbol fluctuation time setting processing, and updating of the normal symbol control state number to "1". Perform various processing as appropriate. In addition, at the start of the process of S6703, if the control state number of the normal symbol is other than "0", the process of S6703 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs normal symbol variation end processing (S6704). However, the process of S6704 is performed when the control state number of the normal symbol is "1" at the start of this process. In this process, the main CPU 6101 appropriately performs various processes when ending the fluctuating display of the normal symbols, such as selecting the waiting time after the normal symbol is confirmed and updating the control state number of the normal symbol to "2". conduct. In addition, at the start of the process of S6704, if the control state number of the normal symbol is other than "1", the process of S6704 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs normal symbol game determination processing (S6705). However, the process of S6705 is performed when the control state number of the normal symbol is "2" at the start of this process. In this process, for example, the main CPU 6101 updates the control status number of the normal symbol to "3" if the lottery result of the normal symbol is a hit, and if the lottery result of the regular symbol is a loss, Performs processing to update the control state number of the symbol to "0". In addition, at the start of the process of S6705, if the control state number of the normal symbol is other than "2", the process of S6705 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs normal electric accessory release processing (S6706). However, the process of S6706 is performed when the control state number of the normal symbol is "3" at the start of this process. In this process, the main CPU 6101 performs a process of updating the control state number of the normal symbol to "4", for example, if the number of winnings of the normal electric accessory 6046 has reached the specified number of winnings. In addition, in this process, the main CPU 6101 ends the process of S6706 without updating the control state number of the normal symbol, for example, if the operating time of the normal electric accessory 6046 has not passed for a predetermined period of time. Furthermore, in this process, the main CPU 6101 updates the control state number of the normal symbol to "4" if, for example, the operating time of the normal electric accessory 6046 has elapsed for a predetermined time and the operating state of the normal symbol is not continued. Perform the processing to do. In addition, at the start of the process of S6706, if the control state number of the normal symbol is other than "3", the process of S6706 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs normal symbol hit termination processing (S6707). However, the process of S6707 is performed when the control state number of the normal symbol is "4" at the start of this process. In this process, the main CPU 6101 performs various processes for ending the normal symbol game (including, for example, processing to update the control state number of the normal symbol to "0", etc.). Note that, at the start of the process of S6707, if the control state number of the normal symbol is other than "4", the process of S6707 is not internally performed.

After the process of S6707, the main CPU 6101 ends the normal symbol control process and returns the process to the process of S6236 of the main control main process (FIGS. 182 to 185).

C. Third Embodiment Next, the configuration and various operations of a pachinko gaming machine (gaming machine) according to a third embodiment of the present invention will be described with reference to the drawings. In the pachinko game machine of this embodiment, the configuration and various processing operations other than the configuration and various processing operations described below are the same as those of the pachinko game machine 6001 of the second embodiment. Therefore, in the following description, the same configuration (processing) as the configuration (processing) of the pachinko gaming machine 6001 of the second embodiment will be described with the same reference numeral (step number). Furthermore, although the description will be omitted below, in this embodiment, by providing the same configuration and various processing operations as the pachinko gaming machine 6001 of the second embodiment, various effects described in the second embodiment can be achieved. The same effect can be obtained.

<Overview of Pachinko machine configuration, gameplay, control, etc.>
In the pachinko gaming machine of this embodiment, as the types of gaming states controlled and managed by the main CPU 6101, a jackpot gaming state is provided, but a small winning gaming state is not provided. Therefore, in this embodiment, "small win" is not provided as a winning type in any lottery (jackpot lottery) for the first special symbol and the second special symbol.

In addition, in this embodiment, the types of gaming states controlled and managed by the main CPU 6101 are variable probability gaming state (high probability gaming state), normal gaming state (low probability gaming state), as in the second embodiment above. , a time-saving gaming state (high winnings gaming state) and a non-time-saving gaming state (low winnings gaming state) are provided. In addition, in each of the variable probability gaming state and the normal gaming state, the probability of winning a "big hit" changes depending on the set value, similarly to the second embodiment.

Furthermore, in this embodiment, as the type of gaming state controlled and managed by the main CPU 6101, as in the second embodiment described above, the state of "with high probability time saving" (variable probability gaming state and time saving gaming state are simultaneously available). (occurrence), "with low probability time saving" state (normal gaming state and time saving gaming state occur at the same time), and "low probability without time saving" state (normal gaming state and non time saving gaming state occurring at the same time). However, a state of "no high probability time saving" (probability variable gaming state and non-time saving gaming state occur simultaneously), that is, a potential probability gaming state is not provided.

Furthermore, the pachinko game machine of this embodiment does not provide a special symbol simultaneous variation function. Therefore, in this embodiment, even if a winning of the other special symbol occurs during the variable display of one of the first special symbol and the second special symbol, the variable display of the other special symbol is not started and is put on hold. treated as a ball. In addition, in this embodiment, when the reserved balls of the first special symbol and the reserved balls of the second special symbol are mixed, the variable display of one special symbol is given priority over the variable display of the other special symbol. However, the present invention is not limited to this, and when the reserved balls of the first special symbol and the reserved balls of the second special symbol are mixed, the variable display of the special symbols is executed in the order in which they are reserved. You can.

In addition, the pachinko gaming machine of this embodiment is provided with a lottery function for changing from the variable probability gaming state to the normal gaming state. The falling lottery and its judgment process are performed before the special symbols start changing in the variable probability gaming state, and when the falling lottery is won (when the fall is confirmed), the gaming state changes from the variable probability gaming state to the normal gaming state at that point. (fall).

In addition, in the pachinko game machine of this embodiment, during the time-saving game state or the jackpot game state, a predetermined external signal (hereinafter referred to as "first jackpot signal") is transmitted via the external terminal board 6140 during a series of jackpot games. An output port is provided that continues to output the signal output to the This signal is output to an externally provided data display or the like.

However, when the falling lottery function from the variable probability gaming state is provided as in this embodiment, the falling lottery and its determination are performed before the special symbols start changing in the variable probability gaming state, and the fall is confirmed. When the time-saving gaming state ends, at that point, the first jackpot signal is interrupted, and this is notified via a data display etc. before the fluctuation starts, and the player recognizes that he has fallen from the variable probability gaming state. There is a possibility that it will be stored away.

In order to solve this problem, in the pachinko gaming machine of this embodiment, when a fall is confirmed by the fall lottery conducted before the start of the change of special symbols, the first jackpot signal is not interrupted. Processing is performed to extend the output of the one jackpot signal until the end of the game when the fall is confirmed (the end of the variable display of the special symbol).

In this embodiment, a control flag (hereinafter referred to as "first jackpot signal extension flag") for realizing the output extension process of this first jackpot signal is provided, and this first jackpot signal extension flag is controlled to turn on/off. Then, the output of the first jackpot signal is extended and controlled so that the first jackpot signal is not interrupted when the fall is confirmed. Specifically, when the fall from the variable probability gaming state is confirmed by the falling lottery held before the start of the variation of the special symbols, and at that time, when the time saving gaming state also ends, the first jackpot signal extension flag is set to the on state. Then, at the end of the game when the fall is determined, the first jackpot signal extension flag is set to an OFF state to complete the output extension process of the first jackpot signal.

Therefore, in the pachinko game machine of this embodiment, the first jackpot signal is transmitted to the external terminal board 6140 not only during the time-saving gaming state and the jackpot gaming state, but also when the first jackpot signal extension flag is in the on state. You can continue outputting via . As a result, it becomes difficult for the player to recognize that the fall has been confirmed through the data display device or the like (the above-mentioned problem at the time of winning the fall lottery can be solved). Therefore, when the output extension process of the first jackpot signal described above is provided, it is possible to suppress the decrease in interest in the game when the player wins the lottery by falling.

In addition, the pachinko gaming machine of this embodiment is provided with a time-saving lamp (notification lamp) that lights up during the time-saving gaming state, and a fall from the fixed-variable gaming state is confirmed before the special symbols start changing. When the time-saving game state ends, the time-saving lamp goes out when the fluctuation starts, so there is a possibility that the player will realize that he has fallen.

Therefore, in order to solve such a problem, in the pachinko gaming machine of this embodiment, even if a "jackpot" is determined during a variable probability gaming state (at the time of a jackpot during variable probability) and the time-saving gaming state ends at that time, A configuration is provided in which the output extension process of the first jackpot signal described above is executed and the output of the first jackpot signal is extended until the end of the game at the time of the jackpot during the probability change. If such a configuration is provided, the time-saving lamp will go out even when there is a jackpot during the probability change and the time-saving gaming state ends, but since the first jackpot signal continues to be output, the time-saving lamp will not turn off due to the confirmed fall. It becomes difficult to recognize through a data display or the like whether it is a real thing or a jackpot.

Therefore, in this embodiment, by providing the above-described output extension processing of the first jackpot signal, it is possible to suppress the decrease in the interest in the game when winning the lottery by falling, and also improve the interest in the game when the time-saving lamp is turned off. be able to.

In addition, in the pachinko gaming machine of this embodiment, the main tables are similar to the special symbol work area table and special symbol related definition data table for each special symbol shown in FIGS. 166 to 169 (the second embodiment). It is provided in the RAM 6103. In addition, in this embodiment, since a simultaneous variation function is not provided, the storage area of information regarding simultaneous variation (for example, the storage area regarding the special symbol suspension flag of each special symbol, etc.) is the same as that of each special symbol in this embodiment. It is not provided in the special symbol work area table and the special symbol related definition data table.

<Operation explanation of main control circuit>
Next, the contents of various processes executed by the main CPU 6101 of the main control circuit 6100 will be described with reference to FIGS. 205 to 217. In addition, in the various processes executed by the main CPU 6101 in this embodiment, the processing content of the special symbol management process is different from that executed by the main CPU 6101 in the second embodiment, and the other processing content is the same as that in the above-mentioned second embodiment. The processing content is the same as that described in the second embodiment. Therefore, in the following, only the contents of the special symbol management process in this embodiment will be explained, and explanations of other various processes will be omitted.

[Special design management processing]
First, with reference to FIG. 205, the special symbol management process performed in this embodiment will be explained. FIG. 205 is a flowchart showing the procedure of special symbol management processing. In addition, the special symbol management process of this embodiment is performed in S6408, S6412, S6416, and S6420 in the special symbol control process (see FIG. 190 and FIG. 191) described in the second embodiment.

In addition, in the special symbol management process described below, the "special symbol" to be processed is a special symbol that corresponds to the address of the special symbol work area table that is set in the IY register at the start of the special symbol management process. . Therefore, at the start of the special symbol management process, if the data set in the IY register is the address of the first special symbol work area table, the "special symbol" to be processed becomes the first special symbol, and the IY When the data set in the register is the address of the second special symbol work area table, the "special symbol" to be processed becomes the second special symbol.

In addition, the numerical values in parentheses (“0” to “6”) written alongside the symbols of each processing step shown in FIG. 205 are the control state numbers of the special symbols to be processed, and are in the special symbol work area table. It is stored in the special symbol control state number area (the first special symbol control state number area in FIG. 166 or the second special symbol control state number area in FIG. 168). Then, the main CPU 6101 advances the special symbol game by executing each processing step corresponding to the control state number.

In addition, as is clear from comparing the flowchart of the special symbol management process of the second embodiment shown in FIG. 193 and the flowchart of the special symbol management process of the present embodiment shown in FIG. The processing flow of the management process is the same as that of the second embodiment. However, in this embodiment, as will be described later, each of the special symbol variation start processing (S6805), special symbol variation end processing (S6806), special symbol game determination processing (S6807), and special symbol per end processing (S6811) The processing content is different from the corresponding processing content in the second embodiment.

First, the main CPU 6101 reads the value of the upper 2-byte timer and determines whether there is a special symbol waiting time (variable display time) for the first half of the special symbol (first half special symbol waiting time management timer value ≠ 0). is determined (S6801). In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol waiting time management timer area (the first special symbol in FIG. 166) in the special symbol work area table. The value of the upper 2 byte timer stored in the waiting time management timer area (or the second special symbol waiting time management timer area in FIG. 168) is read. In this case, the main CPU 6101 can directly read the value of the upper 2 byte timer from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

In S6801, if the main CPU 6101 determines that there is a special symbol waiting time for the first half of the special symbol (YES determination in S6801), the main CPU 6101 ends the special symbol management process and replaces the process with the special symbol control process. (See FIGS. 190 and 191). At this time, if the special symbol management process is called in S6408 during the special symbol control process, the process returns to the process in S6409, and if the special symbol management process is called in S6412 during the special symbol control process, the process returns to the process of S6413. Also, if the special symbol management process is called in S6416 during the special symbol control process, the process returns to the process in S6417, and if the special symbol management process is called in S6420 during the special symbol control process, the special The symbol control process also ends.

On the other hand, in S6801, if the main CPU 6101 determines that there is no special symbol waiting time for the first half of the special symbol (NO determination in S6801), the main CPU 6101 reads the value of the lower 2 byte timer and waits for the special symbol. It is determined whether there is a second half special symbol waiting time (second half special symbol waiting time management timer value≠0) (S6802). In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol waiting time management timer area (the first special symbol in FIG. 166) in the special symbol work area table. The value of the lower 2-byte timer stored in the waiting time management timer area (or the second special symbol waiting time management timer area in FIG. 168) is read. In this case, the main CPU 6101 can directly read the value of the lower 2-byte timer from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

In S6802, if the main CPU 6101 determines that there is a special symbol waiting time for the latter half of the special symbol (YES in S6802), the main CPU 6101 ends the special symbol management process and transfers the process to the special symbol control process. (See FIGS. 190 and 191). At this time, if the special symbol management process is called in S6408 during the special symbol control process, the process returns to the process in S6409, and if the special symbol management process is called in S6412 during the special symbol control process, the process returns to the process of S6413. Also, if the special symbol management process is called in S6416 during the special symbol control process, the process returns to the process in S6417, and if the special symbol management process is called in S6420 during the special symbol control process, the special The symbol control process also ends.

On the other hand, in S6802, when the main CPU 6101 determines that there is no special symbol waiting time in the latter half of the special symbol (NO determination in S6802), the main CPU 6101 reads the control state number of the special symbol (S6803). In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol control state number area (the first special symbol control in FIG. 166) in the special symbol work area table. The control state number of the special symbol stored in the state number area or the second special symbol control state number area in FIG. 168 is read. In this case, the main CPU 6101 can directly read the control state number of the special symbol from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

Next, the main CPU 6101 performs a special symbol control branch table reference process (S6804). In addition, also in this embodiment, the special symbol control branch table defines the correspondence between each control state number (“0” to “6”) of the special symbol and the storage address of the corresponding processing program.

Then, the main CPU 6101 performs the processing from S6805 onwards in accordance with the control state number of the read special symbol. In addition, the processing contents after S6805 include, for example, the control state number of the special symbol read out in S6803 (any one of "0" to "6"), and the update of the control state number of the special symbol within each processing step. It changes depending on the presence or absence of the special symbol game, that is, the playing situation of the special symbol game.

First, the main CPU 6101 performs special symbol variation start processing (S6805). However, the process of S6805 is performed when the control state number of the special symbol is "0" at the start of this process. In this process, the main CPU 6101 performs various processes for starting the special symbol game. The details of the special symbol variation start process will be described later with reference to FIG. 206, which will be described later. On the other hand, when the control state number of the special symbol is other than "0" at the start of the process of S6805, the process of S6805 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs special symbol variation end processing (S6806). However, the process of S6806 is performed when the control state number of the special symbol is "1" at the start of this process. In this process, the main CPU 6101 performs various processes when ending the variable display of special symbols. The details of the special symbol variation end process will be explained later with reference to FIG. 212, which will be described later. On the other hand, when the control state number of the special symbol is other than "1" at the start of the process of S6806, the process of S6806 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs special symbol game determination processing (S6807). However, the process of S6807 is performed when the control state number of the special symbol is "2" at the start of this process. In this process, the main CPU 6101 mainly performs a process for determining the special symbol lottery result (jackpot/loss) and various processes according to the determination result. The details of the special symbol game determination process will be explained later with reference to FIGS. 213 and 214, which will be described later. On the other hand, when the control state number of the special symbol is other than "2" at the start of the process of S6807, the process of S6807 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs the big prize opening preparation process described with reference to FIG. 201 above (S6808). However, the process of S6808 is performed when the control state number of the special symbol is "3" at the start of this process. On the other hand, when the control state number of the special symbol is other than "3" at the start of the process of S6808, the process of S6808 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs the big winning opening control process described with reference to FIG. 202 above (S6809). However, the process of S6809 is performed when the control state number of the special symbol is "4" at the start of this process. On the other hand, when the control state number of the special symbol is other than "4" at the start of the process of S6809, the process of S6809 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs the big prize opening preparation process described with reference to FIG. 201 above (S6810). However, the process of S6810 is performed when the control state number of the special symbol is "5" at the start of this process. On the other hand, when the control state number of the special symbol is other than "5" at the start of the process of S6810, the process of S6810 is not performed internally and the process moves to the next process step.

Next, the main CPU 6101 performs special symbol per end processing (S6811). However, the process of S6811 is performed when the control state number of the special symbol is "6" at the start of this process. In this process, the main CPU 6101 performs various processes when ending the game when a special symbol is won. Note that details of the special symbol per end processing will be explained later with reference to FIG. 217, which will be described later. On the other hand, when the control state number of the special symbol is other than "6" at the start of the process of S6811, the process of S6811 is not performed internally and the process moves to the next process step.

After the process of S6811, the main CPU 6101 ends the special symbol management process and returns the process to the special symbol control process (see FIGS. 190 and 191). At this time, if the special symbol management process is called in S6408 during the special symbol control process, the process returns to the process in S6409, and if the special symbol management process is called in S6412 during the special symbol control process, the process returns to the process of S6413. Also, if the special symbol management process is called in S6416 during the special symbol control process, the process returns to the process in S6417, and if the special symbol management process is called in S6420 during the special symbol control process, the special The symbol control process also ends.

[Special symbol fluctuation start processing]
Next, with reference to FIG. 206, the special symbol variation start process performed in S6805 in the special symbol management process (see FIG. 205) will be described. FIG. 206 is a flowchart showing the procedure of special symbol variation start processing.

First, the main CPU 6101 determines whether the control state number of the special symbol is "0" (S6821).

In S6821, if the main CPU 6101 determines that the control state number of the special symbol is not "0" (NO determination in S6821), the main CPU 6101 ends the special symbol fluctuation start process and transfers the process to special symbol management. The process returns to step S6806 of the process (FIG. 205).

On the other hand, in S6821, when the main CPU 6101 determines that the control state number of the special symbol is "0" (YES in S6821), the main CPU 6101 performs a special symbol game standby process (S6822). In this process, the main CPU 6101 mainly performs a process of checking the game status ("game start" or "game standby"). The details of the special symbol game standby process will be explained later with reference to FIG. 207, which will be described later.

Next, the main CPU 6101 determines whether the gaming state is "game standby" (S6823).

In S6823, if the main CPU 6101 determines that the gaming state is "game standby" (YES in S6823), the main CPU 6101 ends the special symbol fluctuation start process, and transfers the process to the special symbol management process ( The process returns to step S6806 in FIG. 205).

On the other hand, in S6823, if the main CPU 6101 determines that the gaming state is not "game standby" ("game start") (NO determination in S6823), the main CPU 6101 performs special symbol storage transfer processing ( S6824). In this process, the main CPU 6101 performs a process of subtracting the number of reserved special symbols, a process of transferring lottery results, a process of reserving transmission of a pending subtraction command, and the like.

Next, the main CPU 6101 performs a special symbol fall determination process (S6825). In this process, the main CPU 6101 performs a fall lottery process if the game is in a variable probability gaming state, and if the game is won in the fall lottery, it performs processing to set various flags to change the game state to a fall. The details of the special symbol fall determination process will be described later with reference to FIG. 208, which will be described later.

Next, the main CPU 6101 performs special symbol hit determination processing (S6826). In this process, the main CPU 6101 performs a process for determining the special symbol lottery result (jackpot/loss). In this process, the same process as the special symbol hit determination process (S6475) described in the second embodiment is performed. Next, the main CPU 6101 performs special symbol determination processing (S6827). In this process, the main CPU 6101 performs a process of determining a stop symbol corresponding to the special symbol lottery result (jackpot/loss).

Next, the main CPU 6101 performs special symbol variation pattern setting processing (S6828). In this process, the main CPU 6101 performs lottery processing for the first half variable display pattern and the second half variable display pattern corresponding to the special symbol lottery result (jackpot/loss), and sets each variable display pattern. Next, the main CPU 6101 performs a special symbol fluctuation display time setting process (S6829). In this process, the main CPU 6101 sets the first half variable display time (first half special symbol waiting time) and the second half variable display time (second half special symbol waiting time) of the special symbol to the upper 2 byte timer and lower 2 byte timer, respectively. set.

Next, the main CPU 6101 performs special symbol game state setting processing (S6830). In this process, the main CPU 6101 performs processing for setting the gaming status (various gaming status flags) at the time of a jackpot. The details of the special symbol game state setting process will be explained later with reference to FIG. 211, which will be described later.

Next, the main CPU 6101 performs clearing processing of the designated storage area (S6831). Specifically, the main CPU 6101 performs processing to clear the special symbol random number work area in the main RAM 6103.

Next, the main CPU 6101 sets the control state number of the special symbol to "1" (S6832). Due to this special symbol control state number update process, after the special symbol variation start process ends, a special symbol variation end process (S6806) is performed.

Next, the main CPU 6101 performs gaming state designation parameter setting processing (S6833). In this process, the main CPU 6101 performs setting (update) processing of the control number area, gaming state specifying parameter area, and production variation table parameter area in the special symbol work area table, and transfer processing of the gaming state specifying parameter. In this process, the main CPU 6101 also performs processing for setting command parameters for external output.

Next, the main CPU 6101 performs interrupt prohibition processing (S6834).

Next, the main CPU 6101 performs transmission reservation processing of a special symbol presentation start command (S6835). The special symbol production start command reserved in this process is transmitted to the sub-control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172).

Next, the main CPU 6101 performs interrupt permission processing (S6836). After the process of S6836, the main CPU 6101 ends the special symbol variation start process and returns the process to the process of S6806 of the special symbol management process (FIG. 205).

[Special symbol game standby processing]
Next, with reference to FIG. 207, the special symbol game standby process performed in S6822 during the special symbol variation start process (see FIG. 206) will be described. FIG. 207 is a flowchart showing the procedure of special symbol game standby processing.

First, the main CPU 6101 determines whether the number of reserved special symbols is "0" (S6841). In this process, the main CPU 6101 uses the address of the special symbol work area table set in the IY register to use the special symbol reservation number area in the special symbol work area table (the first special symbol reservation number area in FIG. 166). Alternatively, the number of reserved special symbols stored in the second special symbol reserved number area in FIG. 168 is read out. In this case, the main CPU 6101 can directly read the reserved number of special symbols from the work area in the main RAM 6103 without performing address reference processing of the special symbol work area table.

In S6841, when the main CPU 6101 determines that the number of reserved special symbols is not "0" (NO in S6841), the main CPU 6101 sets the gaming state to "game start" (S6842). After the process of S6842, the main CPU 6101 ends the special symbol game standby process and returns the process to the process of S6823 of the special symbol variation start process (FIG. 206).

On the other hand, if the main CPU 6101 determines in S6841 that the number of reserved special symbols is "0" (YES in S6841), the main CPU 6101 determines that the current gaming state is in demonstration (standby state). It is determined whether there is one (S6843). In this determination process, the main CPU 6101 determines whether the demo display command has been sent (whether the demo display command sent flag is on). If the demonstration display command has been sent, the determination result in S6843 is YES, and if the demonstration display command has not been transmitted, the determination result in S6843 is NO.

In S6843, if the main CPU 6101 determines that the current gaming state is in the demonstration mode (YES in S6843), the main CPU 6101 performs processing in S6849, which will be described later.

On the other hand, if the main CPU 6101 determines in S6843 that the current gaming state is not in a demonstration (NO determination in S6843), the main CPU 6101 sets the demo display command sent flag to the on state (S6844) . Note that the value of the demo display command sent flag is determined by the value of the special symbol demo display state flag area (the first special symbol in FIG. It is stored in the symbol demo display state flag area (or the second special symbol demo display state flag area in FIG. 168).

Next, the main CPU 6101 performs interrupt prohibition processing (S6845). Next, the main CPU 6101 performs gaming state designation parameter setting processing (S6846). In this process, the main CPU 6101 performs setting (update) processing of the control number area, gaming state specifying parameter area, and production variation table parameter area in the special symbol work area table, and transfer processing of the gaming state specifying parameter.

Next, the main CPU 6101 performs transmission reservation processing for a demonstration display command (S6847). The demonstration display command reserved in this process is transmitted to the sub-control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172). Next, the main CPU 6101 performs interrupt permission processing (S6848).

After the processing in S6848, or if the determination in S6843 is YES, the main CPU 6101 sets the gaming state to "game standby" (S6849). After the process of S6849, the main CPU 6101 ends the special symbol game standby process and returns the process to the process of S6823 of the special symbol variation start process (FIG. 206).

[Special symbol falling judgment process]
Next, with reference to FIG. 208, the special symbol fall determination process performed in S6825 during the special symbol variation start process (see FIG. 206) will be described. FIG. 208 is a flowchart showing the procedure of special symbol fall determination processing.

First, the main CPU 6101 determines whether or not the game is in a variable probability gaming state (S6851).

In S6851, if the main CPU 6101 determines that it is not in a variable probability gaming state (in the case of a normal gaming state) (if NO in S6851), the main CPU 6101 ends the special symbol fall determination process, and continues the process with a special symbol variation. The process returns to S6826 of the start process (FIG. 206).

On the other hand, in S6851, when the main CPU 6101 determines that the game is in a variable probability gaming state (YES in S6851), the main CPU 6101 performs a fall lottery process (S6852).

Next, the main CPU 6101 determines whether or not the player has won the falling lottery (S6853).

In S6853, if the main CPU 6101 determines that the falling lottery has not been won (NO in S6853), the main CPU 6101 ends the special symbol falling determination process and replaces the process with the special symbol fluctuation start process (Fig. The process returns to step S6826 in step 206).

On the other hand, in S6853, when the main CPU 6101 determines that the falling lottery has been won (YES in S6853), the main CPU 6101 clears (turns off) the special symbol probability change state flag (S6854). Through this process, the gaming state falls (transfers) from the variable probability gaming state to the normal gaming state.

Next, the main CPU 6101 clears (turns off) the special symbol probability change state notification flag (S6855).

Next, the main CPU 6101 determines whether the remaining number of time savings is "0" (number of time savings = 0) (S6856).

In S6856, if the main CPU 6101 determines that the remaining number of time reductions is not "0" (NO in S6856), the main CPU 6101 performs processing in S6860, which will be described later.

On the other hand, in S6856, if the main CPU 6101 determines that the remaining time saving number is "0" (YES in S6856), the main CPU 6101 clears (turns off) the special symbol time saving state flag (S6857) . With this process, the time saving game state ends. In addition, the special symbol time-saving state flag is a flag indicating whether the current gaming state is a time-saving gaming state, and is set to an on state when the current gaming state is a time-saving gaming state. The value of the special symbol time saving state flag is stored in the special symbol time saving state flag area provided in the main RAM 6103.

Next, the main CPU 6101 clears (turns off) the special symbol time saving state notification flag (S6858). In addition, the special symbol time-saving state notification flag is a flag indicating whether or not to notify that the current gaming state is the time-saving gaming state, and is turned on when notifying that the current gaming state is the time-saving gaming state. set to the state. That is, the special symbol time-saving state notification flag is a flag indicating whether or not to light up the time-saving lamp, and if the special symbol time-saving state flag is on, the time-saving lamp is lit, and if it is off, the time-saving lamp is off. do. Therefore, the time saving lamp is turned off by the process of S6858. In addition, the value of the special symbol time-saving state notification flag is stored in the special symbol time-saving state notification flag area provided in the main RAM 6103.

Next, the main CPU 6101 performs a process of setting the first jackpot signal extension flag (S6859). Through this process, the first jackpot signal extension flag is set to the on state, and the output of the first jackpot signal (external signal) is extended. That is, if a fall is confirmed in the fall lottery held before the start of variation of the special symbols, and the time-saving game state also ends at that time, the output of the first jackpot signal extension is extended. In addition, since the first jackpot signal extension flag is reset (turned off) at the end of the variation of the special symbol when the fall is confirmed, the output of the first jackpot signal is extended until the end of the variation display.

After the processing in S6859, or if the determination in S6856 is NO, the main CPU 6101 sets the offset addition value "2" to the data selection offset addition value (S6860). Next, the main CPU 6101 performs special symbol production mode management processing (S6861). In this process, the main CPU 6101 performs a process of selecting a special symbol variation pattern table (effect variation pattern) based on the set data selection offset addition value. The details of the special symbol production mode management process will be explained later with reference to FIG. 209, which will be described later.

After the process of S6861, the main CPU 6101 ends the special symbol fall determination process and returns the process to the process of S6826 of the special symbol variation start process (FIG. 206).

[Special design production mode management processing]
Next, with reference to FIG. 209, the special symbol production mode management process performed in S6861 during the special symbol fall determination process (see FIG. 208) will be described. FIG. 208 is a flowchart showing the procedure of special symbol production mode management processing.

First, the main CPU 6101 performs a process of determining a combination of special symbol variation pattern selection tables (variation pattern table to be described later) (S6871). In this process, the main CPU 6101 determines a combination of special symbol variation pattern selection tables (not shown) from a special symbol variation pattern selection table selection data table (not shown) based on the set data selection offset addition value. .

Next, the main CPU 6101 sets the determined combination of symbol variation pattern selection tables as an effect variation table (S6872). After the process of S6872, the main CPU 6101 ends the special symbol production mode management process and also ends the special symbol fall determination process (FIG. 208).

In the pachinko game machine of this embodiment, a plurality of groups of variation pattern tables are provided to be used when determining the variation pattern of special symbols after the end of the jackpot game. In addition, each group includes a variation pattern table (hereinafter referred to as a "variation pattern table") used to determine the variation pattern of special symbols during a variable probability gaming state, and a variation pattern table used to determine the variation pattern of special symbols during a fall. A fluctuation pattern table used when determining the fluctuation pattern table (hereinafter referred to as the "falling fluctuation pattern table"), and a fluctuation pattern table used when determining the fluctuation pattern of the special symbol after the fall (during normal gaming state). (hereinafter referred to as "normal medium fluctuation pattern table") is provided.

Then, in cases other than falling (normal time), when the fluctuation display of a specific symbol ends, a variable pattern table during probability variation or a variation pattern table during normal variation is selected as a variation pattern table according to the gaming situation, and the selected variation pattern table From this, the next special symbol variation pattern is determined. In addition, in this embodiment, if a fall is determined in the fall lottery performed before the start of the change of special symbols (at the start of the game) in the variable probability game state, at the time of the fall determination, the change pattern at the time of fall is set as a change pattern table. A table is selected, and a variation pattern of the variation display is determined from the selected falling variation pattern table.

In addition, each variation pattern table is composed of a combination of a plurality of special symbol variation pattern selection tables that are set as the production variation table in S6872. Further, each special symbol variation pattern selection table constituting the variation pattern table is associated with the number of variations (variation number period) of the special symbol for which the special symbol variation pattern selection table is used. When the variation pattern table with such a configuration is set, the special symbol variation pattern selection table used changes according to the number of variations (variation number period) of the special symbol.

For example, now, one fluctuation pattern tail is composed of a combination of three special symbol fluctuation pattern selection tables (special symbol fluctuation pattern selection tables A, B, and C), and special symbol fluctuation pattern selection table A is used for the 1st to 100th times. The number of fluctuations (variation number period) up to 100 is associated, the special symbol fluctuation pattern selection table B is associated with the number of fluctuations (variation number period) from the 101st to 300th, and the special symbol fluctuation pattern selection table C is associated with 301. Consider a case where the number of fluctuations after the first time (variation number period) is associated. In this case, when the fluctuation pattern tail is set as the performance fluctuation table, during the period of the number of fluctuations from the 1st to the 100th, the fluctuation pattern of the special symbol is determined using the special symbol fluctuation pattern selection table A, In the period of the number of fluctuations from the 101st to the 300th, the fluctuation pattern of the special symbol is determined using the special symbol fluctuation pattern selection table B, and in the period of the number of fluctuations after the 301st, the fluctuation pattern of the special symbol is It is determined using the symbol variation pattern selection table C.

In this embodiment, the selection and change processing of the variation pattern table (combination (effect group) of special symbol variation pattern selection tables) is performed based on the data selection offset addition value, as described above, and the data selection offset addition value is "0", the normal medium variation pattern table is selected, and when the data selection offset addition value is "1", the probability variation medium variation pattern table is selected, and the data selection offset addition value is "1", the probability variation pattern table is selected. 2'', the falling variation pattern table is selected. In addition, the data selection offset addition value is set to "2" when the falling lottery is won at the start of the game in the variable probability game state, so in this case, the data selection offset value set before the falling lottery is set to "2". The offset addition value "1" is changed to "2", and the fluctuation pattern table is changed to the fall fluctuation pattern table based on the changed data selection offset addition value "2".

When such a correspondence configuration is provided between the data selection offset addition value and the variation pattern table (combination of special symbol variation pattern selection table), in the process of determining the variation pattern table (effect variation table) of the special symbol, the variation to be used is After setting a pattern table group (the above-mentioned special symbol variation pattern selection table selection data table), simply move the address by the offset value (data selection offset addition value) according to the gaming situation within the group. A variation pattern table can be selected depending on the situation. In this case, the process of selecting a variable pattern table can be simplified (the process of acquiring the address of each variable pattern table becomes unnecessary). As a result, in this embodiment, the capacity of the processing program managed by the main control circuit 6100 can be reduced, the processing performed by the main control circuit 6100 can be executed more efficiently, and the processing load on the main control circuit 6100 can be reduced. It can be reduced.

(Variation example of selection method of production variation table)
In addition, the selection method of the variation pattern table (combination of special symbol variation pattern selection tables) according to the gaming situation after the end of the jackpot game (hereinafter referred to as "effect variation table selection method") is limited to the example of this embodiment. Not done. Here, with reference to FIG. 210, another example of the selection method of the performance variation table (variation pattern table) according to the gaming situation will be explained. FIG. 210 is a diagram showing a schematic structure of the special symbol variation pattern selection table selection data table, special symbol variation pattern selection table group, and special symbol variation pattern selection offset table used in the production variation table selection process of this example. be.

The special symbol variation pattern selection table selection data table includes data regarding the storage addresses of multiple types of selectable special symbol variation pattern selection table groups (in the example of FIG. 210, special symbol variation pattern selection table groups 0 to 3). (Relative address from the start address of the special symbol variation pattern selection table selection data table) is defined. Although a detailed explanation will be omitted, the special symbol variation pattern selection table group mainly includes the number of variations and the special symbol variation pattern selection offset table that is referred to when selecting a performance variation table from the special symbol variation pattern selection offset table. The relationship with the reference (start) address within is defined. Further, the special symbol variation pattern selection offset table defines data (offset values: in the example of FIG. 210, production variation table values 0 to 12) regarding storage addresses of a plurality of types of production variation tables.

In this example, first, the special symbol variation pattern selection table group to be used after the end of the jackpot game is selected by referring to the special symbol variation pattern selection table selection data pattern. In addition, in this selection process, the special symbol variation pattern selection table group may be determined according to, for example, the jackpot symbol, the gaming state, the random number value when winning the jackpot, etc. Further, when selecting the special symbol variation pattern selection table group, a new lottery may be performed to select the special symbol variation pattern selection table group. In this case, the special symbol variation pattern selection table group can be randomly determined.

Next, according to the selected special symbol variation pattern selection table group and the current number of variations, data (offset values) regarding the storage addresses of multiple types of effect variation tables specified in the special symbol variation pattern selection offset table are used. , determine the data (reference address, reference offset value) regarding the storage address of the effect variation table that becomes the reference (head) of the effect variation table that is a candidate for use. This determination process is a process for determining which address from the head address of the special symbol variation pattern selection offset table the data stored in is to be used as a reference, according to the number of variations since the end of the jackpot game. For example, when the number of fluctuations is the 20th, the data stored in the 6th address from the start address of the special symbol fluctuation pattern selection offset table is used as the standard, and when the number of fluctuations is the 30th, the data stored in the special symbol fluctuation pattern selection offset table is set as the standard. This determination process determines that the data stored in the ninth address from the top address of the symbol variation pattern selection offset table is to be used as a reference.

Then, a data selection offset addition value (any one of "0" to "2") according to the gaming state is added to the data regarding the storage address of the performance variation table that is the standard determined in the above determination process (standard address). Then, the storage address of the effect variation table to be used is determined.

For example, if the number of fluctuations after the end of the jackpot game is the 20th, the data stored in the 6th address from the top address of the special symbol fluctuation pattern selection offset table is used as the standard by the second selection process. Consider the case where it is decided to

In this case, for example, when the gaming state after the end of the jackpot game is the normal gaming state (after a fall), the data selection offset addition value is "0", so the data regarding the storage address of the standard production variation table ( The offset value obtained by adding the data selection offset addition value "0" to the reference address = 6) is "6", and the data stored at the 6th address from the start address of the special symbol variation pattern selection offset table (relative address value : In the example shown in FIG. 210, the performance variation table stored in the "performance variation table 10 values") is used (selected) as the normal medium variation pattern table.

In addition, in this case, for example, when the gaming state after the end of the jackpot game is the variable probability gaming state, the data selection offset addition value is "1", so the data regarding the storage address of the standard production variation table (standard address = The offset value obtained by adding the data selection offset addition value "1" to 6) is "7", and the data stored in the seventh address from the top address of the special symbol variation pattern selection offset table (relative address value: Figure 210 In the example shown in , the performance variation table stored in the "performance variation table 7 values") is used (selected) as the probability variation variation pattern table.

In addition, in this case, for example, when the game state after the end of the jackpot game is a confirmed fall, the data selection offset addition value is "2", so the data regarding the storage address of the standard production variation table (standard address = The offset value obtained by adding the data selection offset addition value "2" to 6) is "8", and the data stored in the 8th address from the start address of the special symbol variation pattern selection offset table (relative address value: Figure 210 In the example shown in , the performance variation table stored in the "performance variation table binary") is used (selected) as the falling variation pattern table.

As described above, in the above modification of the selection method of the production variation table, multiple types of candidates for use after the end of the jackpot game are selected according to the type of the selected special symbol variation pattern selection table group and the current number of variations. The selection criteria (starting address) of the performance variation table group is determined, and multiple performance variation tables are used after the jackpot game ends according to the selection criteria and the gaming state (data selection offset added value) after the jackpot game ends. It is determined from among the species performance variation table group.

In addition, in the special symbol variation pattern selection offset table, as described above, data (offset values) regarding the storage addresses of a plurality of effect variation tables that are candidates for use depending on the number of variations are arranged consecutively on the address. Therefore, the special symbol variation pattern selection offset table is a table group that specifies which range (address range in the special symbol variation pattern selection offset table) of the production variation table to use depending on the number of variations. It can also be expressed as

[Special symbol game state setting process]
Next, with reference to FIG. 211, the special symbol game state setting process performed in S6830 during the special symbol variation start process (see FIG. 206) will be described. FIG. 211 is a flowchart showing the procedure of special symbol game state setting processing.

First, the main CPU 6101 performs jackpot confirmation processing (S6881). In this process, the main CPU 6101 stores the information stored in the special symbol per flag area (the first special symbol per flag area in FIG. 166 or the second special symbol per flag area in FIG. 168) in the special symbol work area table. The value (special symbol hit flag value) is read out, and based on the special symbol hit flag value, confirmation processing is performed to determine whether the lottery result of the special symbol corresponds to a jackpot.

Next, the main CPU 6101 determines whether or not it is a jackpot (S6882).

In S6882, if the main CPU 6101 determines that it is not a jackpot (NO determination in S6882), the main CPU 6101 ends the special symbol game state setting process and repeats the process to S6831 of the special symbol variation start process (FIG. 206). Return to processing. On the other hand, when the main CPU 6101 determines that it is a jackpot (YES determination in S6882), the main CPU 6101 determines whether or not it is a variable probability gaming state (S6883).

In S6883, if the main CPU 6101 determines that it is not in the variable probability gaming state (if NO in S6883), the main CPU 6101 ends the special symbol gaming state setting process and executes the special symbol variation starting process (FIG. 206). The process returns to step S6831.

On the other hand, in S6883, when the main CPU 6101 determines that it is in a variable probability gaming state (YES in S6883), the main CPU 6101 clears (turns off) the special symbol variable probability state flag (S6884). Next, the main CPU 6101 clears (turns off) the special symbol probability change state notification flag (S6885).

Next, the main CPU 6101 determines whether the remaining number of time savings is not "0" (number of time savings≠0) (S6886).

In S6886, if the main CPU 6101 determines that the remaining time saving number is not "0" (YES in S6886), the main CPU 6101 ends the special symbol game state setting process and starts the special symbol variation start process. The process returns to step S6831 of the process (FIG. 206).

On the other hand, in S6886, if the main CPU 6101 determines that the remaining time saving number is "0" (NO in S6886), the main CPU 6101 clears (turns off) the special symbol time saving state flag (S6887) . Next, the main CPU 6101 clears (turns off) the special symbol time saving state notification flag (S6888). This process turns off the time saving lamp.

Next, the main CPU 6101 sets (turns on) the first jackpot signal extension flag (S6889). Through this processing, the output port of the first jackpot signal (external signal) is set to the on state, and the output processing of the first jackpot signal is extended. After the process of S6889, the main CPU 6101 ends the special symbol game state setting process and returns the process to the process of S6831 of the special symbol variation start process (FIG. 206).

As described above, in this embodiment, the process (S6884 to S6889) performed when a jackpot is achieved during probability change in the special symbol game state setting process is the process (S6854) performed when a fall is confirmed in the special symbol fall determination process (see FIG. 208). ~S6859) is the same process. Therefore, in both processes, the time-saving lamp is turned off at the end of the time-saving gaming state (number of time-saving games = 0), but it is difficult to recognize whether this is due to a confirmed fall or a jackpot. It can be done. In addition, in this case, since the output of the first jackpot signal is extended in both processes, it is possible to determine whether the time-saving lamp goes out due to a confirmed fall or a jackpot, even through a data display etc. cannot be recognized. Therefore, in this embodiment, it is possible to improve the interest of the game when the time saving lamp is turned off.

[Special symbol variation end processing]
Next, with reference to FIG. 212, the special symbol variation end process performed in S6806 in the special symbol management process (see FIG. 205) will be described. FIG. 212 is a flowchart showing the procedure of special symbol variation end processing.

First, the main CPU 6101 determines whether the control state number of the special symbol is "1" (S6891).

In S6891, if the main CPU 6101 determines that the control state number of the special symbol is not "1" (NO determination in S6891), the main CPU 6101 terminates the special symbol variation end process and transfers the process to special symbol management. The process returns to step S6807 of the process (FIG. 205).

On the other hand, in S6891, if the main CPU 6101 determines that the control state number of the special symbol is "1" (YES in S6891), the main CPU 6101 sets the special symbol confirmation waiting time (S6892) . In this process, the main CPU 6101 sets the special symbol fixed waiting time in the upper 2 byte timer in the special symbol waiting time management timer area (4 bytes) in the special symbol work area table.

Next, the main CPU 6101 sets the control state number of the special symbol to "2" (S6893). Due to the update process of the control state number of this special symbol, the special symbol game determination process (S6807) is performed after the special symbol variation end process is completed.

Next, the main CPU 6101 performs transmission reservation processing of a special symbol production stop command for the special symbol (S6894). Note that the special symbol production stop command for the special symbol reserved in this process is sent to the sub control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172). After the process of S6894, the main CPU 6101 ends the special symbol variation end process and returns the process to the process of S6807 of the special symbol management process (FIG. 205).

[Special symbol game judgment processing]
Next, with reference to FIGS. 213 and 214, the special symbol game determination process performed in S6807 in the special symbol management process (see FIG. 205) will be described. 213 and 214 are flowcharts showing the procedure of special symbol game determination processing.

First, the main CPU 6101 determines whether the control state number of the special symbol is "2" (S6901).

In S6901, if the main CPU 6101 determines that the control state number of the special symbol is not "2" (NO determination in S6901), the main CPU 6101 ends the special symbol game determination process and transfers the process to special symbol management. The process returns to step S6808 of the process (FIG. 205).

On the other hand, in S6901, when the main CPU 6101 determines that the control state number of the special symbol is "2" (YES in S6901), the main CPU 6101 performs interrupt prohibition processing (S6902).

Next, the main CPU 6101 performs jackpot confirmation processing (S6903). In this process, the main CPU 6101 stores the information stored in the special symbol per flag area (the first special symbol per flag area in FIG. 166 or the second special symbol per flag area in FIG. 168) in the special symbol work area table. The value (special symbol hit flag value) is read out, and based on the special symbol hit flag value, confirmation processing is performed to determine whether the lottery result of the special symbol corresponds to a jackpot.

Next, the main CPU 6101 determines whether or not it is a jackpot time (S6904).

In S6904, when the main CPU 6101 determines that it is a jackpot (YES determination in S6904), the main CPU 6101 performs processing in S6908, which will be described later.

On the other hand, if the main CPU 6101 determines in S6904 that it is not a jackpot (NO determination in S6904), the main CPU 6101 performs gaming state management processing (S6905). In this process, the main CPU 6101 mainly updates various flags and various counters related to the management of the gaming state. The details of the gaming state management process will be explained later with reference to FIG. 215, which will be described later.

Next, the main CPU 6101 performs special symbol game end processing (S6906). The details of the special symbol game ending process will be explained later with reference to FIG. 216, which will be described later.

Next, the main CPU 6101 performs interrupt permission processing (S6907). After the process of S6907, the main CPU 6101 ends the special symbol game determination process and returns the process to the process of S6808 of the special symbol management process (FIG. 205).

Here, returning to the process of S6904 again, if the determination is YES in S6904, the main CPU 6101 clears (turns off) the first jackpot signal extension flag (S6908). Through this process, the output of the first jackpot signal is stopped. Next, the main CPU 6101 sets the start of the variable display at the time of jackpot (S6909). In this process, the main CPU 6101 performs a process of setting a special symbol hit signal (jackpot signal) outputted via an external terminal board.

Next, the main CPU 6101 performs a process of setting round display LED data according to the designated special symbol (S6910). Next, the main CPU 6101 performs processing to set the upper limit of the number of openings of the big winning hole according to the designated special symbol (S6911).

Next, the main CPU 6101 performs a process of setting a large winning opening operation selection offset value according to the designated special symbol (S6912). In addition, the big winning opening operation selection offset value is a relative address from the top address of the selection table when determining the opening/closing operation pattern of the big winning opening from the selection table. Next, the main CPU 6101 performs a process of setting a jackpot signal (external signal) according to the designated special symbol (S6913).

Next, the main CPU 6101 sets the start display time per special symbol (S6914). In this process, the main CPU 6101 sets the start display time per special symbol in the upper 2 byte timer in the special symbol waiting time management timer area (4 bytes) in the special symbol work area table.

Next, the main CPU 6101 sets the control state number of the special symbol to "3" (S6915). By the updating process of the control state number of this special symbol, after the special symbol game determination process ends, the big winning opening preparation process (S6808) is performed.

Next, the main CPU 6101 performs special symbol game state designation parameter setting processing (S6916). In this process, the main CPU 6101 performs setting (update) processing of the control number area, gaming state specifying parameter area, and production variation table parameter area in the special symbol work area table, and transfer processing of the gaming state specifying parameter.

Next, the main CPU 6101 performs a transmission reservation process for a start display command per special symbol (S6917). Note that the special symbol per start display command reserved in this process is transmitted to the sub control circuit 6200 in the production control command transmission process (S6022) during the next system timer interrupt process (FIG. 172).

Next, the main CPU 6101 performs interrupt permission processing (S6918). After the process of S6918, the main CPU 6101 ends the special symbol game determination process and returns the process to the process of S6808 of the special symbol management process (FIG. 205).

[Game state management processing]
Next, with reference to FIG. 215, the game state management process performed in S6905 in the special symbol game determination process (see FIGS. 213 and 214) will be described. FIG. 215 is a flowchart showing the procedure of gaming state management processing.

First, the main CPU 6101 subtracts 1 from the value of the time saving state change counter (S6921). Note that the time saving state change number counter is a counter for counting the remaining time saving number of times, and the count value is stored in the time saving state change number counter area in the main RAM 6103.

Next, the main CPU 6101 determines whether the remaining number of time savings is not "0" (number of time savings≠0) (S6922). In S6922, if the main CPU 6101 determines that the remaining number of time reductions is not "0" (YES in S6922), the main CPU 6101 performs processing in S6926, which will be described later.

On the other hand, in S6922, if the main CPU 6101 determines that the remaining time saving number is "0" (NO determination in S6922), the main CPU 6101 determines whether the value of the special symbol probability change state flag is not "0" or not. (S6923). In S6923, if the main CPU 6101 determines that the value of the special symbol probability change state flag is not "0" (YES in S6923), the main CPU 6101 performs the process of S6926, which will be described later.

On the other hand, in S6923, if the main CPU 6101 determines that the value of the special symbol probability change state flag is "0" (NO determination in S6923), the main CPU 6101 clears (turns off) the special symbol time saving state flag. (S6924). Next, the main CPU 6101 clears (turns off) the special symbol time saving state notification flag (S6925). This process turns off the time saving lamp.

After the process of S6925, or if the determination is YES in S6922 or S6923, the main CPU 6101 subtracts 1 from the value of the performance variation counter (S6926). The effect variation number counter is a counter for counting the remaining number of variations in which the currently set special symbol variation pattern selection table is used, and the counted value is stored in the effect variation number counter in the main RAM 6103. Stored. In addition, as in this embodiment, the variation pattern table for determining the variation pattern of the special symbol is composed of a combination of special symbol variation pattern selection tables, and each special symbol variation pattern selection table has a corresponding special symbol variation pattern selection table. If the number of variations (variation number period) of the special symbol to be used is associated, it is set in the performance variation counter every time the special symbol variation pattern selection table to be used is switched according to the number of variations. The remaining fluctuation count (initial value) is also reset.

After the process of S6926, the main CPU 6101 ends the game state management process and returns the process to the process of S6906 of the special symbol game determination process (FIGS. 213 and 214).

[Special symbol game end processing]
Next, with reference to FIG. 216, the special symbol game end process performed in S6906 during the special symbol game determination process (see FIGS. 213 and 214) will be described. FIG. 216 is a flowchart showing the procedure of special symbol game end processing.

First, the main CPU 6101 clears (turns off) the first jackpot signal extension flag (S6931). As a result, the output of the first jackpot signal is stopped. Next, the main CPU 6101 sets the control state number of the special symbol to "0" (S6932).

Next, the main CPU 6101 inputs the value stored in the special symbol probability variable state flag area in the main RAM 6103 (“0” in the normal gaming state and “1” in the variable probability gaming state) to the data selection offset of the input register. Set as an additional value (S6933).

Next, the main CPU 6101 performs the special symbol production mode management process described with reference to FIG. 209 (S6934). In this process, if the data selection offset addition value set in S6933 is "0", the normal medium variation pattern table is selected as the variation pattern table for determining the variation pattern of the special symbol, and the data selection offset addition value set in S6933 is selected. When the data selection offset added value is "1", the variable pattern table during probability change is selected as the variable pattern table for determining the variable pattern of the special symbol.

Next, the main CPU 6101 performs special symbol game state designation parameter setting processing (S6935). In this process, the main CPU 6101 performs setting (update) processing of the gaming state number area, gaming state specifying parameter area, and performance variation table parameter area in the special symbol work area table, and transfer processing of the gaming state specifying parameter.

Next, the main CPU 6101 performs a transmission reservation process for a special symbol game end command (S6936). The special symbol game end command reserved in this process is sent to the sub-control side in the performance control command sending process (S6022) during the next system timer interrupt process (FIG. 172). After the process of S6936, the main CPU 6101 ends the special symbol game end process and returns the process to the process of S6907 of the special symbol game determination process (FIGS. 213 and 214).

[Special symbol per end processing]
Next, with reference to FIG. 217, the special symbol per end process performed in S6811 in the special symbol management process (see FIG. 205) will be described. FIG. 217 is a flowchart showing the procedure of special symbol per end processing.

First, the main CPU 6101 determines whether the control state number of the special symbol is "6" (S6941).

In S6941, if the main CPU 6101 determines that the control state number of the special symbol is not "6" (NO determination in S6941), the main CPU 6101 terminates the special symbol per end processing and starts the special symbol management processing ( FIG. 205) also ends.

On the other hand, in S6941, when the main CPU 6101 determines that the control state number of the special symbol is "6" (YES in S6941), the main CPU 6101 performs interrupt prohibition processing (S6942).

Next, the main CPU 6101 performs a process of setting end common data per special symbol (S6943). Next, the main CPU 6101 performs a special symbol per end setting data selection process (S6944).

Next, the main CPU 6101 performs special symbol game end setting processing (S6945). Next, the main CPU 6101 performs the special symbol game end process described in FIG. 216 (S6946). In addition, by this process, the control state number of the special symbol is updated to "0".

Next, the main CPU 6101 performs interrupt permission processing (S6947). After the processing in S6947, the main CPU 6101 ends the special symbol per end processing and also ends the special symbol management processing (FIG. 205).

<Application example>
In the second and third embodiments described above, the operations and functions controlled by the main control circuit 6100 were mainly explained, but these operations and functions are also applicable to the pachinko gaming machine of the first embodiment. It is possible. That is, the various functions (performance functions) controlled by the sub-control circuit 200 described in the first embodiment can also be applied to the pachinko gaming machines of the second and third embodiments, and in this case. Similarly, various effects based on the various functions described in the first embodiment can also be obtained.

Further, in the description of the various embodiments above, the configurations of various modified examples have been described, but in the present invention, the configurations of these various embodiments and various modified examples are used in appropriate combinations unless a particular inconsistency occurs. be able to. Further, in the various embodiments and the various modifications described above, a pachinko game machine has been described as an example of the game machine, but the present invention is not limited thereto. The various techniques of the present invention described above can be applied to other gaming machines as appropriate, for example, to various gaming machines such as pinball gaming machines, gaming machines, enclosed gaming machines, slot machines, and pachislot gaming machines. It can also be applied.

<Other expandability of the gaming machine according to the above embodiment>
Next, various extensibility of the gaming machines according to the various embodiments and the various modified examples described above will be explained.

(1) Extensibility 1
The gaming machine of the above embodiment may be configured such that, for example, six levels of setting values from "1" to "6" can be set by, for example, a person involved in the hall. When the set value is changed, for example, the jackpot probability (internal winning probability) in the internal lottery is changed.

The present invention can be applied to all types of gaming machines of the above embodiments in which players play games using gaming media and receive benefits based on the results of the games. In other words, the gaming machine of the above embodiment is not limited to a mode in which a game is played by ejecting or inserting a game medium by the physical movement of a player, and the game medium is paid out based on the result of the game. The main control circuit itself may electromagnetically manage the game media held by the player and enable games played by circulating the enclosed gaming machine or games played without medals. Furthermore, the device that electromagnetically manages the game media held by the player may be a game media management device that is attached to (connected to) the main control circuit and manages the game media.

When managed by a gaming media management device connected to the main control circuit, the gaming media management device is a device that has ROM and RWM (or RAM) and is installed in the gaming machine, and external gaming media (not shown) It is connected to the handling device and the two-way communication function via a predetermined interface, and performs the lending operation of gaming media (i.e., the operation of providing the necessary gaming media when the player inserts the gaming media). ) or the payout operation of game media in the event of winning a winning role related to the payout of game media (the role is established) (i.e., making the player acquire the necessary game media to pay out the game media) (operation), or an operation of electromagnetically recording game media used for games. In addition, the game media management device not only manages the actual number of game media, but also displays the number of game media held on the front of the gaming machine based on the management result of the number of game media. A number display device (not shown) may be provided to manage the number of game media displayed on the owned game media number display device. In other words, the game media management device may be capable of recording and displaying the total number of game media that can be used by a player in a game using an electromagnetic method.

In addition, in this case, the game media management device has the ability to allow the player to freely transmit a signal indicating the number of recorded game media to the external game media handling device, and In addition to being operated directly by a person, the number of recorded game media cannot be reduced, and an external connection terminal board (not shown) is provided between the player and an external game media handling device. In some cases, it is desirable that the player has the ability to transmit a signal indicating the number of recorded game media except through the external connection terminal board. When transmitting and receiving signals to and from the game machine via a dedicated unit or board for transmitting and receiving signals, it is also possible to receive gaming information and the like via a dedicated unit or board for transmitting and receiving signals.

In addition to the above, the gaming machine is equipped with a lending operation means, a return (payment) operation means, and an external connection terminal board that can be operated by the player, and the gaming media handling device has an input slot for valuables such as banknotes, and a recording medium. (e.g. IC card) insertion slot, non-contact communication antenna for depositing electronic money etc. from a mobile terminal, various operation means such as lending operation means, return operation means, external connection terminal board on the side of the game media handling device may also be provided (both not shown).

The flow of the game at that time is, for example, when the player deposits valuable value into the gaming media handling device using one of the methods, and subtracts a predetermined number of valuable values based on the operation of one of the lending operation means described above. Then, the amount of game media corresponding to the value subtracted from the game media handling device to the game media management device is increased. The player then plays the game and repeats the above operations if more game media are required. After that, as a result of the game, a predetermined number of game media are acquired, and when the game is finished, the number of game media is transmitted from the game media management device to the game media handling device by operating one of the return operation means, and the game The medium handling device ejects the recording medium on which the number of game media is recorded. When the game media management device transmits the number of game media, it clears the number of game media stored in itself. The player takes the ejected recording medium to a prize counter or the like to exchange it for prizes, or moves the game machine to play a game based on the game medium recorded on another machine.

In the above example, all game media are sent to the game media handling device, but the game machine or game media handling device only transmits the number of game media desired by the player, and the game media owned by the player is transmitted. It is also possible to divide and process. Furthermore, instead of just ejecting the recording medium, cash or cash equivalent may be ejected, or it may be stored in a mobile terminal or the like. Further, the game media handling device may be configured to be able to insert a member recording medium of a gaming parlor, and to store the membership recording medium in the member recording medium so that it can be played again at a later date.

Further, in the gaming machine or the gaming media handling device, by operating a predetermined operation means (not shown), a locking operation for locking the data communication of gaming media or valuable value can be performed on the gaming media handling device or the gaming media management device. Good too. In this case, information that only the player can know, such as a one-time password, may be set, or the player may be recorded using an imaging means provided in the game medium handling device.

In addition, although the above describes the case where the game media management device is applied to a pachinko game machine, the game media management device can also be applied to a pachislot machine, a slot machine that uses game balls, and an enclosed game machine. A player's gaming media can also be managed.

In this way, by providing the above-mentioned game media management device, the number of internal points inside the game machine can be reduced compared to the case where game media are physically used in games, and the cost and manufacturing cost of the game machine can be reduced. Not only can players avoid direct contact with gaming media, the gaming environment can be improved, noise can be reduced, and the power consumption of gaming machines can also be reduced by reducing the number of parts. It also happens. In addition, it is possible to prevent fraudulent acts through the game media and the game media input and output ports. That is, it is possible to provide a gaming machine that can improve various environments surrounding the gaming machine.

In addition, data regarding the increase and decrease in gaming media due to consumption, lending, and payout of gaming media is transmitted to enclosed gaming machines configured to allow gaming without the gaming media being ejected to the outside. When the present invention is applied to a gaming system having a gaming media management device connected to enable transmission and reception of optical signals via a cable, the gaming system may be configured as follows.

Below, an outline of the enclosed gaming machine will be explained. In the enclosed game machine, the firing device is located above the game area and fires game balls as game media from above into the game area. When the player operates the handle, the ball feed solenoid is driven by the payout control circuit, and the ball feed pestle pushes out the waiting game ball toward the launch pad. This moves the game ball to the launch pad. Further, a subtraction sensor is provided on the path from the standby position to the launch pad, and detects the game ball moving to the launch pad. When a game ball is detected by the subtraction sensor, the number of balls held is subtracted by 1. Since the game ball is thus configured to be shot as a game medium from above into the game area, the enclosed game machine can avoid so-called return balls (foul balls). The game balls ejected from the game area after rolling in the game area are polished by a ball polishing device. The game balls polished by the ball polishing device are transported upward by the lifting device and guided to the firing device. The game balls are not discharged to the outside of the enclosed game machine, but are configured so that a certain number (for example, 50) of game balls circulate through a series of paths in the game machine.

In an enclosed type game machine, the game balls are not discharged to the outside of the game machine, so an upper tray or a lower tray for temporarily holding the game balls is not provided. In an enclosed game machine, the game balls are not discharged to the outside, so the game balls are not in the hands of the player, and the number of game balls does not actually increase or decrease as the player plays the game. In an enclosed game machine, a player starts playing after acquiring balls lent from a game media management device. Here, obtaining a ball means that the player obtains game media in terms of data management. Then, by firing the game balls from the firing device, the balls held are consumed, and the number of balls held decreases. In addition, by passing the game balls through each winning hole provided in the gaming area, the number of balls that are paid out is increased according to the conditions set according to the winning hole, and the number of balls is increased. Furthermore, the number of balls held increases by lending from the game media management device. Note that "consumption, lending, and payout of game media" indicates that the balls held are consumed, loaned, and paid out. Further, "increase/decrease in game media" indicates an increase/decrease in the number of balls held due to consumption, lending, and payout. Furthermore, "data regarding increases and decreases in game media due to consumption, lending, and payout of game media" is data regarding the decrease in the number of balls held due to game balls being fired and the increase in the number of balls held due to lending and payout.

The enclosed gaming machine may have a payout control circuit and an operation means (for example, a touch panel liquid crystal display device, which may be provided separately or integrally with the gaming machine). However, the game media management device may have an operation means (for example, a touch panel type liquid crystal display device, which may be provided separately or integrally with the game machine). The payout control circuit is connected to various sensors that detect the passage of game balls through each winning hole, etc. The payout control circuit manages the number of balls held. For example, when a game ball passes through each winning hole, the number of game balls paid out due to this is added to the number of balls held. Furthermore, when a game ball is fired, the number of balls held is subtracted. The payout control circuit transmits data regarding the number of balls held by the player to the game media management device. In addition, the above-mentioned liquid crystal display device (or touch panel, etc.) is mainly located at the bottom of the gaming machine, although its installation position is not particularly limited, and is used to convert the gaming value managed by the gaming media management device to balls held. We accept requests for (rental of balls) and for counting (returning) balls. Then, these requests are transmitted to the payout control circuit via the game media management device, and the payout control circuit is instructed to transmit data regarding the current number of balls held to the game media management device. Here, "gaming value" refers to money/banknotes, prepaid media, tokens, electronic money, tickets, etc., which can be converted into balls by the gaming media management device. In the above embodiment, the game media management device is a so-called CR unit, and is configured to be able to accept banknotes, prepaid media, and the like. Further, the counted balls can be used for exchanging prizes, etc. at a game hall where the game system is installed.

Furthermore, the enclosed gaming machine has a backup power source. As a result, even if the power is turned off at night, the data immediately before the power is turned off can be retained. Further, by using this backup power source, for example, the door opening sensor may continue to detect the opening of the door frame. This can also prevent fraudulent acts at night. In this case, information such as the number of times the door frame has been opened may be stored. Furthermore, when the power is turned on, information such as the number of times the door frame has been opened may be output to a liquid crystal display device or the like of the gaming machine.

The gaming media management device has a gaming machine connection board. The game media management device is configured to transmit and receive data (transmission signals) to and from the game machine via the game machine connection board. The transmitted and received data includes the unique ID of the CPU provided in the main control circuit, the unique ID of the CPU provided in the payout control circuit, the gaming machine manufacturer code stored in the gaming machine, the security chip manufacturer code, and the gaming machine manufacturer code stored in the gaming machine. This is information such as the model code of the machine. Then, when the transmission source transmits a transmission signal with one of the gaming machine and the gaming media management device as the transmission source and the other as the transmission destination, the transmission destination that received the transmission signal receives the same signal as the transmission signal. A confirmation signal is transmitted to the transmission source, and the transmission source compares the transmission signal and the confirmation signal to determine whether or not they are the same.

In this way, by comparing the confirmation signal sent from the destination with the transmission signal at the transmission source and determining whether they are the same, the signal transmitted from the transmission source can be prevented from being tampered with. You can confirm that the message is being sent to the sender. Thereby, fraudulent acts such as tampering with transmission/reception signals between the gaming machine and the gaming media management device can be suppressed.

Further, in the gaming system, the transmission source has a modulation section that modulates a signal, and the transmission source transmits the signal modulated by the modulation section as the transmission signal, and the transmission destination transmits the signal modulated by the modulation section. It is also possible to include a demodulation section that performs demodulation.

As a result, even if the transmission and reception signals between the gaming machine and the gaming media management device were read, it would be difficult to decipher the signals, and the transmission and reception signals between the gaming machine and the gaming media management device would be difficult to decipher. Fraudulent acts such as falsification can be suppressed.

In addition, in the gaming system, when the transmission destination receives the transmission signal from the transmission source, the transmission destination sends an approval signal, which is a signal indicating that the transmission signal has been received, separately from the confirmation signal. It may also be sent to the sender.

By comparing the transmitted signal and the confirmation signal, it is possible to not only confirm that a legitimate signal has been transmitted and received, but also to confirm that a legitimate signal has been transmitted and received based on the authorization signal. Therefore, it is possible to further strengthen the suppression of fraudulent acts.

(2) Extensibility 2
In the gaming machine of the present invention, opening the door is a condition for changing the settings on the software. Settings can only be changed when the setting key is turned on and the RWM (RAM) clear switch is turned on when the power is turned on to further monitor (detect) the opening of the door. When no set value is set, "E" is displayed in all four digits of the performance display monitor. Note that at this time, a predetermined sound is also generated, but in addition to the predetermined sound, a voice saying "RWM abnormal error." may be generated. When changing settings, a specific sound is generated (a voice saying "Settings are being changed" may also be generated), and all lamps are turned on. On the back of the gaming machine, the set value changes each time the RWM clear switch is pressed, and returns to the normal state when the setting key is returned (unplugged). When you open the door and turn on the power while turning the key, you can check the settings on the back and the words ``Settings are being changed.'' will be displayed on the screen.

Furthermore, a maintenance mode may be installed. In the maintenance history, the time when the power was turned on, the time when settings were checked, the time when an RWM (RAM) abnormality occurred, errors related to settings, etc. are recorded. In this case, for example, it may be possible to record up to about 200 maintenance histories. In the setting history, you can check the history of setting changes and setting confirmations, and setting values. Note that this history is configured so that it cannot be viewed without the setting key.

Further, the display of the setting change may be performed only by the control on the sub side, but it may also be displayed with all the special figure related displays turned on under the control on the main side. In addition, when displaying the setting change by displaying the special figure related display by all lighting, the pattern of all lighting is not provided in the display pattern of the special symbol. Further, the setting change history can be recorded, for example, up to about 100 items at most, and the maintenance mode can only be activated while checking the settings. Furthermore, the history cannot be deleted at the hall (gaming hall).

In addition, since the power supply board is provided with a backup function, when switching panels, an RWM error occurs and the performance display monitor is also cleared. Note that there is no delay at the final confirmation of setting the setting value. During the delay, the settings will be changed.

(3) Expandability 3
In a pachinko game machine, there is a first sensor that detects the opening of the front door, and a second sensor that detects movement (opening operation, etc.) of the main body (board holding frame) from the outer frame (machine frame, etc.). A sensor is provided.

The settings may not be changed when the first sensor detects the opening, and the settings may be changed when the second sensor detects the opening. In this case, the switch that is pressed to change the settings is provided on the board, etc. on the back side of the gaming machine, and the operator at the gaming center moves the main unit to change the settings at the front of the gaming machine (the outer frame of the gaming machine). Settings can be changed while being guaranteed to work from the front). Note that the present invention is not limited to this, and a configuration may be adopted in which the setting can be changed when the opening is detected by both the first sensor and the second sensor, or the setting can be changed when the opening is detected by the first sensor. The configuration may be such that the settings can be changed when the

<Additional notes>
[30th and 31st gaming machines]
Conventionally, pachinko gaming machines are known that are equipped with a plurality of symbol display devices (display areas) and are provided with a function that allows the plurality of symbol display devices to simultaneously display identification information in a variable manner (for example, Japanese Patent Laid-Open No. 2015-150303 (see official bulletin).

Incidentally, in recent years, there has been a demand for pachinko gaming machines equipped with a function that can display identification information in a variable manner on a plurality of symbol display devices at the same time to increase the interest of the game with such a function.

The present invention has been made in order to solve the above-mentioned 30th problem, and the 30th object of the present invention is to provide a gaming machine having a function that allows a plurality of symbol display devices to simultaneously display identification information in a variable manner. It is an object of the present invention to provide a technology that can increase the interest in playing games with such functions.

In order to achieve the above 30th object, the present invention provides the following 30th gaming machine.

A first determination for determining whether to transition to a special gaming state advantageous to the player (for example, a jackpot gaming state) based on the establishment of a first starting condition (for example, winning of the first starting opening 6044). means (for example, main CPU 6101);
a first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on a determination result by the first determination means;
A second determining means (for example, the main CPU 6101 )and,
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second determination means; Equipped with
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
The timing at which the one identification information display means ends the fluctuating display of the one identification information overlaps with the timing at which the other identification information display means starts fluctuating display of the other identification information, and In a specific case where one determination result corresponding to the identification information display means causes the transition to the special gaming state, the other identification information is based on the other determination result corresponding to the other identification information display means. A gaming machine characterized by not starting a variable display of.

Further, in the 30th gaming machine of the present invention, in the specific case, a predetermined control flag (for example, a special symbol suspension flag) is turned on to prevent the start of the variable display of the other identification information. , when the special game state executed based on the one determination result ends, the predetermined control flag is turned off and a variable display of the other identification information is started based on the other determination result. You can do it like this.

Furthermore, in the 30th gaming machine of the present invention, when the one identification information is being displayed in a variable manner, and the manner in which the one identification information is displayed in a variable manner is a mode in which the transition is made to the special gaming state. In this case, even if the start condition for the other identification information is met, the control may be such that a determination result for shifting the other identification information to the special gaming state is not determined.

In order to achieve the above 30th object, the present invention provides the following 31st gaming machine.

A first determination for determining whether to transition to a special gaming state advantageous to the player (for example, a jackpot gaming state) based on the establishment of a first starting condition (for example, winning of the first starting opening 6044). means (for example, main CPU 6101);
a first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on a determination result by the first determination means;
A second determining means (for example, the main CPU 6101 )and,
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second determination means; Equipped with
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
Starting the variable display of the other identification information by the other identification information display means at the timing when the one identification information display means ends the variable display of the one identification information, and a period from the said timing to a predetermined time period before. In a specific case where the timing of one of the judgments corresponding to the one identification information display means causes the transition to the special gaming state, the other judgment result corresponding to the other identification information display means A gaming machine characterized by not starting a variable display of the other identification information based on the determination result.

Further, in the thirty-first gaming machine of the present invention, in the specific case, when the special gaming state executed based on the one determination result ends, the other one based on the other determination result is It is also possible to start displaying the identification information in a variable manner.

Furthermore, in the thirty-first gaming machine of the present invention, when the one identification information is being displayed in a variable manner, and the manner in which the one identification information is displayed in a variable manner is a mode in which the transition is made to the special gaming state. In this case, even if the start condition for the other identification information is met, the control may be such that a determination result for shifting the other identification information to the special gaming state is not determined.

According to the 30th and 31st gaming machines of the present invention having the above-mentioned configurations, in a gaming machine equipped with a function of being able to display identification information in a variable manner simultaneously on a plurality of symbol display devices, it is possible to increase the interest of the game with respect to such a function. be able to.

[32nd to 45th gaming machines]
Conventionally, pachinko gaming machines are known that are equipped with a plurality of symbol display devices (display areas) and are provided with a function that allows the plurality of symbol display devices to simultaneously display identification information in a variable manner (for example, Japanese Patent Laid-Open No. 2015-150303 (see official bulletin).

By the way, the gaming machine described above usually has a main control board on which a circuit (main control circuit) for controlling main gaming operations such as determination of identification information is mounted, and a circuit (main control circuit) for controlling performance operations such as displaying images. and a sub-control board on which a sub-control circuit (sub-control circuit) is mounted. The gaming operation is controlled by a CPU (Central Processing Unit) installed in the main control circuit. At this time, under the control of the CPU, programs and various table data stored in the ROM (Read Only Memory) of the main control circuit are expanded to the RAM (Random Access Memory) of the main control circuit, and processing related to various gaming operations is executed. be done. In recent years, in such gaming machines, there has been a demand for the development of technology that can more efficiently execute the processing performed by the main control circuit and reduce the processing load on the main control circuit.

The present invention has been made to solve the above thirty-first problem, and the thirty-first object of the present invention is to more efficiently execute the processing performed in the main control circuit and reduce the processing load on the main control circuit. The purpose of the present invention is to provide a gaming machine that can

In order to achieve the above thirty-first object, the present invention provides the following thirty-second gaming machine.

Arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling game operations;
comprising a storage means (for example, main RAM 6103) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
The storage means is provided with two work areas,
Information that is processed using each work area is attached with specific information (for example, an identifier) that is associated with the work area used.
When processing information using one of the two work areas, the arithmetic processing means selects the work area to be used based on the specific information added to the information to be processed. A gaming machine characterized by selecting.

Further, in the thirty-second gaming machine of the present invention, the specific information is upper address data that constitutes the address of the corresponding work area;
In the work area selection process by the arithmetic processing means, the arithmetic processing means may specify an address of the work area to be used based on the specific information.

In order to achieve the above thirty-first object, the present invention provides the following thirty-third gaming machine.

A first identification information display means (for example, a first special symbol) that variably displays first identification information (for example, a first special symbol) triggered by the establishment of a first start condition (for example, a winning of the first starting hole 6044). 1 special symbol display device 6061),
A second identification information display means (for example, a second special symbol) that variably displays second identification information (for example, a second special symbol) is triggered by the establishment of a second start condition (for example, a winning of the second starting hole 6045). 2 special symbol display device 6062),
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
comprising a storage means (for example, a main RAM 6103) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
The storage means is provided with a first work area and a second work area,
The processing related to the variable display of the first identification information by the arithmetic processing means is performed using the first work area,
The processing related to the variable display of the second identification information by the arithmetic processing means is performed using the second work area,
First specific information (for example, an identifier) associated with the first work area is added to the information to be processed in the process related to the variable display of the first identification information,
Second specific information associated with the second work area is added to the information to be processed in the process related to the variable display of the second identification information,
The arithmetic processing means is
When performing a process related to a variable display of the first identification information, selecting the first work area based on the first specific information added to the information to be processed;
When performing the process related to the variable display of the second identification information, the second work area is selected based on the second specific information added to the information to be processed. A gaming machine.

Further, in the thirty-third gaming machine of the present invention, the first specific information is upper address data that constitutes the address of the first work area, and the second specific information is This is the upper address data that constitutes the address of the work area No. 2,
In the work area selection process by the arithmetic processing means, the arithmetic processing means may designate the address of the work area to be used based on specific information.

In order to achieve the above thirty-first object, the present invention provides the following thirty-fourth gaming machine.

A first identification information display means (for example, a first special symbol) that variably displays first identification information (for example, a first special symbol) triggered by the establishment of a first start condition (for example, a winning of the first starting hole 6044). 1 special symbol display device 6061),
A second identification information display means (for example, a second special symbol) that variably displays second identification information (for example, a second special symbol) is triggered by the establishment of a second start condition (for example, a winning of the second starting hole 6045). 2 special symbol display device 6062),
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
a first data table (for example, a first special symbol work area table) storing information used when executing processing related to the variable display of the first identification information by the arithmetic processing means;
a second data table (for example, a second special symbol work area table) in which information used when executing processing related to the variable display of the second identification information by the arithmetic processing means;
In the first data table, the second identification of the same type as the predetermined information is stored in a storage area at an address separated by a predetermined offset value from the address of the storage area of predetermined information regarding the first identification information. Information related to the information is stored, and the address of the second data table is stored in the last storage area,
In the second data table, the first information of the same type as the specific information is stored in a storage area at an address separated by the predetermined offset value from the address of the storage area of specific information related to the second identification information. Information related to identification information is stored, and an address of the first data table is stored in the last storage area,
In the process related to the variable display of the first identification information, when reading information related to the second identification information of the same type as the predetermined information stored in the first data table, the calculation process The means sets the address of the storage area of the predetermined information as a reference address, corrects the address by the predetermined offset value with respect to the reference address, and selects the same type of information as the predetermined information based on the corrected address. reading information regarding the second identification information;
In the process related to the variable display of the second identification information, when reading information related to the first identification information of the same type as the specific information stored in the second data table, the calculation process The means sets the address of the storage area of the specific information as a reference address, corrects the address by the predetermined offset value with respect to the reference address, and selects the same type of information as the specific information based on the corrected address. A gaming machine characterized by reading out information related to first identification information.

Further, in the thirty-fourth gaming machine of the present invention, while one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information is displayed. The identification information display means may be able to start displaying the other identification information in a variable manner.

In order to achieve the above thirty-first object, the present invention provides the following thirty-fifth gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
Interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
Display means (e.g., performance display monitor 6070) for displaying predetermined information (e.g., base value) regarding the history of gaming values given to players;
The interrupt processing execution means includes:
Random number updating means (for example, S6019 during system timer interrupt processing) for updating random number values used in game control by the game control means;
Display control means for controlling display processing of the predetermined information by the display means (for example, S6024 during system timer interrupt processing);
a setting control means (for example, S6016 during system timer interrupt processing) for controlling a setting value change process or confirmation process indicating the advantageous degree of the game;
The setting value changing process or confirmation process by the setting control means is executed when the game is not permitted, and in this case, the random number updating process by the random number updating means and the display control A gaming machine characterized in that display processing of the predetermined information by the means is not executed.

Furthermore, in the thirty-fifth gaming machine of the present invention, the display means may also be capable of displaying the set value.

In order to achieve the above thirty-first object, the present invention provides the following thirty-sixth-first gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
The interrupt processing execution means has a setting control means (for example, S6016 during system timer interrupt processing) that controls a change processing or confirmation processing of a setting value indicating the advantageous degree of the game,
The setting value changing process or confirmation process by the setting control means is executed when the game is not permitted, and in this case, the process executed by the interrupt processing execution means when the game is permitted is executed. A gaming machine that is characterized by the fact that it does not play.

Furthermore, in order to achieve the above thirty-first object, the present invention provides the following thirty-sixth-second gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
The interrupt processing execution means includes:
startup information acquisition means for acquiring information regarding the startup state (for example, S6014 during system timer interrupt processing);
a setting control means (for example, S6016 during system timer interrupt processing) for controlling a setting value change process or confirmation process indicating the advantageous degree of the game;
The setting value changing process or confirmation process by the setting control means is executed when the game is not permitted, and in this case, the process executed by the interrupt processing execution means when the game is permitted is performed. No,
A gaming machine characterized in that a determination as to whether a game is permitted or not is made based on information regarding the activation state acquired by the activation information acquisition means.

In order to achieve the above thirty-first object, the present invention provides the following thirty-seventh gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
Interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
Display means (e.g. performance display monitor 6070) for displaying predetermined information (e.g. base value) regarding the history of gaming values given to players;
The interrupt processing execution means includes:
Random number updating means (for example, S6019 during system timer interrupt processing) for updating random number values used in game control by the game control means;
Display control means for controlling display processing of the predetermined information by the display means (for example, S6024 during system timer interrupt processing);
A setting control means (for example, S6016 during system timer interrupt processing) that controls a process of changing or confirming a setting value indicating the degree of advantage of the game;
a timer update means (for example, S6018 during system timer interrupt processing) that performs update processing of a timer that manages the predetermined period;
The setting value changing process or confirmation process by the setting control means is executed when the game is not permitted, and in this case, the random number updating process by the random number updating means and the process by the display control means A gaming machine characterized in that display processing of the predetermined information and updating processing of the timer by the timer updating means are not executed.

Further, the 37th gaming machine of the present invention further includes a storage means (for example, main RAM 6103) in which information necessary for game control by the game control means is stored,
The storage means includes a first work area (for example, a gaming RAM area) in which information necessary for executing processes related to the progress of the game is stored, and information necessary for executing processes not related to the proceeding of the game. has a second work area (for example, an extra-area RAM area) in which is stored;
Display processing of the predetermined information by the display control means may be performed using the second work area.

In order to achieve the above thirty-first object, the present invention provides the following thirty-eighth-first gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
Production control means (for example, sub-control circuit 6200) that controls production operations;
and an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means,
The interrupt processing execution means includes:
A setting control means (for example, S6016 during system timer interrupt processing) that controls a process of changing or confirming a setting value indicating the degree of advantage of the game;
a data transmission means (for example, S6022 during system timer interrupt processing) for transmitting data from the game control means to the production control means according to the game situation;
The game control means includes a setting operation data generation means (for example, setting operation preprocessing) that generates setting operation data indicating that the setting value changing process or confirmation process has been performed,
The setting operation data generated by the setting operation data generation means is transmitted from the game control means to the performance control means by the data transmission means in the first interrupt processing performed after the generation processing of the setting operation data. A gaming machine characterized by:

Furthermore, in order to achieve the above thirty-first object, the present invention provides the following thirty-eighth-second gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
Production control means (for example, sub-control circuit 6200) that controls production operations;
and an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means,
The interrupt processing execution means includes:
A setting control means (for example, S6016 during system timer interrupt processing) that controls a process of changing or confirming a setting value indicating the degree of advantage of the game;
a data transmission means (for example, S6022 during system timer interrupt processing) for transmitting data from the game control means to the production control means according to the game situation;
The game control means includes a setting operation data generation means (for example, setting operation preprocessing) that generates setting operation data indicating that the setting value changing process or confirmation process has been performed,
The setting operation data generated by the setting operation data generation means is transmitted from the game control means to the performance control means by the data transmission means in the first interrupt processing performed after the generation processing of the setting operation data. ,
A game machine characterized in that the reservation process for transmitting the setting operation data is performed during the control process by the game control means, but not during the interrupt process by the interrupt process execution means.

In order to achieve the thirty-first object, the present invention provides the following thirty-ninth gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game;
Production control means (for example, sub-control circuit 6200) that controls production operations;
Storage means (for example, main RAM 6103) in which information necessary for execution of control processing by the game control means is stored;
and an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means,
The interrupt processing execution means includes:
A setting control means (for example, S6016 during system timer interrupt processing) that controls a process of changing or confirming a setting value indicating the degree of advantage of the game;
a data transmission means (for example, S6022 during system timer interrupt processing) for transmitting data from the game control means to the production control means according to the game situation;
The game control means includes a setting operation data generation means (for example, setting operation pre-processing) that generates setting operation data indicating that the setting value changing process or confirmation process has been performed,
The setting operation data generated by the setting operation data generation means is transmitted from the game control means to the performance control means by the data transmission means in the first interrupt processing performed after the generation processing of the setting operation data. ,
In the interrupt processing in which the setting value is changed by the setting control means, the data transmission means transmits data that is the same as specific data (for example, an initialization command) that would be transmitted when the storage means was cleared. is transmitted from the game control means to the performance control means,
In the interrupt processing in which the setting value confirmation process is performed by the setting control means, the data transmission means transmits the same data as predetermined data (for example, a power failure recovery command) to be transmitted when the power is restored. A gaming machine characterized by transmitting information from a gaming control means to the performance control means.

In order to achieve the above thirty-first object, the present invention provides the following fortieth gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
Interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
Storage means (for example, main RAM 6103) in which information necessary for execution of control processing by the game control means is stored,
In the control process by the game control means, a prohibition period (for example, S6221 to S6230 during the main control main process) for the execution of the interrupt process by the interrupt process execution unit is provided during the progress of the process,
During the prohibition period, the game control means performs processing in response to the occurrence of a power outage, processing for updating initial random numbers used in game control, and predetermined information regarding the history of gaming values given to players. (e.g. base value),
The storage means includes a first work area (for example, a gaming RAM area) in which information necessary for executing processes related to the progress of the game is stored, and information necessary for executing processes not related to the proceeding of the game. has a second work area (for example, an extra-area RAM area) in which is stored;
A gaming machine characterized in that the process of updating the predetermined information regarding the history of gaming values given to the player is executed using the second work area.

Further, in the fortieth gaming machine of the present invention, the updating process of the predetermined information regarding the history of gaming values given to the player may be executed only when it is possible to play.

In order to achieve the above thirty-first object, the present invention provides the following forty-first gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
and an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period (for example, 2 msec) during the control processing by the game control means,
In the control processing by the game control means, a period during which execution of the interrupt processing by the interrupt processing execution means is prohibited (for example, S6221 to S6230 during main control main processing: 6 msec) is provided during the progress of the processing,
During the prohibition period, the game control means performs processing in response to the occurrence of a power outage, processing for updating initial random numbers used in game control processing, and predetermined processing regarding the history of gaming values given to players. Update information (e.g. base value),
A gaming machine characterized in that the prohibited period is a predetermined number of times greater than or equal to twice the predetermined period.

Further, in the forty-first gaming machine of the present invention, the processing of the prohibition period by the game control means may be performed before the execution of control processing related to the progress of the game by the game control means.

In order to achieve the above thirty-first object, the present invention provides a forty-second gaming machine as described below.

A first determination for determining whether to transition to a special gaming state advantageous to the player (for example, a jackpot gaming state) based on the establishment of a first starting condition (for example, winning of the first starting opening 6044). means (for example, main CPU 6101);
a first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on a determination result by the first determination means;
a second determination means (for example, the main CPU 6101) that determines whether or not to transition to the special gaming state in response to the establishment of a second start condition (for example, winning of the second starting port 6045);
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second determination means; Equipped with
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
When the variable display time of the other identification information has elapsed, it is possible to perform an end process for the variable display of the other identification information,
When the fluctuating display of the one identification information ends, a predetermined control flag (for example, a special symbol pause flag) for determining the control mode of the fluctuating display of the one identification information is not set to an on state. In this case, it is decided to shift the control process of the fluctuating display of the one identification information to the process of determining the result of the stop mode of the fluctuating display of the one identification information (for example, during special symbol fluctuation end processing). S6514),
When the fluctuating display of the one identification information ends, the predetermined control flag is not set to the on state, and the result of the stop mode of the fluctuating display of the one identification information is the special gaming state. In the case where the change display of the other identification information is to be migrated, the termination process for the fluctuation display of the other identification information is not performed, and the control processing of the fluctuation display of the other identification information is changed to the stop mode of the fluctuation display of the other identification information. It is possible to decide to proceed to the process of determining the result (for example, S6531 during the special symbol variation end process)
A gaming machine characterized by:

Furthermore, in order to achieve the thirty-first object, the present invention provides a forty-second gaming machine as described below.

A first determination for determining whether to transition to a special gaming state advantageous to the player (for example, a jackpot gaming state) based on the establishment of a first starting condition (for example, winning of the first starting opening 6044). means (for example, main CPU 6101);
a first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on a determination result by the first determination means;
a second determination means (for example, the main CPU 6101) that determines whether or not to transition to the special gaming state in response to the establishment of a second start condition (for example, winning of the second starting port 6045);
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second determination means; Equipped with
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
When the variable display time of the other identification information has elapsed, it is possible to perform an end process for the variable display of the other identification information,
A predetermined control flag (for example, a special symbol suspension flag) is provided for determining a control mode of the fluctuating display of the identification information,
A control parameter (for example, a special symbol control state number) is provided for controlling the transition of the control process of the variable display of the identification information,
When the predetermined control flag of the one identification information is not set to an on state when the fluctuating display of the one identification information ends, controlling the control process of the fluctuating display of the one identification information; The parameter is updated to a predetermined value (for example, "2") for transitioning to the next variable display control process after the variable display end process (for example, S6514 during the special symbol change end process), and in this case, When the result of the stop mode of the fluctuating display of the one identification information is to shift to the special gaming state, the control parameter of the control process of the fluctuating display of the other identification information is also updated to the predetermined value (e.g. , S6531 during special symbol variation end processing)
A gaming machine characterized by:

In order to achieve the above-mentioned 31st object, the present invention provides the following 43rd-1st gaming machine.

A first determination for determining whether to transition to a special gaming state advantageous to the player (for example, a jackpot gaming state) based on the establishment of a first starting condition (for example, winning of the first starting opening 6044). means (for example, main CPU 6101);
a first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on a determination result by the first determination means;
a second determination means (for example, the main CPU 6101) that determines whether or not to transition to the special gaming state in response to the establishment of a second start condition (for example, winning of the second starting port 6045);
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second determination means; Equipped with
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
When the variable display time of the other identification information has elapsed, it is possible to perform an end process for the variable display of the other identification information,
When the fluctuating display of the one identification information ends, a predetermined control flag (for example, a special symbol pause flag) for determining the control mode of the fluctuating display of the one identification information is not set to an on state. In this case, it is decided to shift the control process of the fluctuating display of the one identification information to the process of determining the result of the stop mode of the fluctuating display of the one identification information (for example, during the special symbol fluctuation end process). S6514),
When the fluctuating display of the one identification information ends, the predetermined control flag is not set to an on state, and the result of the stop mode of the fluctuating display of the one identification information causes the transition to the special gaming state. and when the other identification information is being displayed in a fluctuating manner, the end processing for the fluctuating display of the other identification information is not performed, and the control processing for the fluctuating display of the other identification information is performed. It is decided to proceed to the process of determining the stop mode of the variation display of the other identification information (for example, S6531 during the special symbol variation end process)
A gaming machine characterized by:

Furthermore, in order to achieve the thirty-first object, the present invention provides a forty-third-second gaming machine as described below.

A first determination for determining whether to transition to a special gaming state advantageous to the player (for example, a jackpot gaming state) based on the establishment of a first starting condition (for example, winning of the first starting opening 6044). means (for example, main CPU 6101);
a first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on a determination result by the first determination means;
a second determination means (for example, the main CPU 6101) that determines whether or not to transition to the special gaming state in response to the establishment of a second start condition (for example, winning of the second starting port 6045);
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second determination means; Equipped with
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
When the variable display time of the other identification information has elapsed, it is possible to perform an end process for the variable display of the other identification information,
A predetermined control flag (for example, a special symbol suspension flag) is provided for determining a control mode of the fluctuating display of the identification information,
A control parameter (for example, a special symbol control state number) is provided for controlling the transition of the control process of the variable display of the identification information,
When the predetermined control flag of the one identification information is not set to an on state when the fluctuating display of the one identification information ends, controlling the control process of the fluctuating display of the one identification information; The parameter is updated to a predetermined value for transitioning to the next variable display control process after the variable display end process (for example, S6514 during the special symbol change end process), and in this case, the change in one of the identification information When the result of the display stop mode is to shift to the special gaming state, and when the other identification information is being displayed in a variable manner, the control parameter for the control process for the variable display of the other identification information is also set to the predetermined value. updated to the value (for example, S6531 during special symbol fluctuation end processing)
A gaming machine characterized by:

In order to achieve the above thirty-first object, the present invention provides a forty-fourth-first gaming machine as described below.

Identification information display means (e.g., first special symbol display device 6061) that variably displays identification information (e.g., first special symbol) in response to establishment of a predetermined starting condition (e.g., winning of the first starting hole 6044). and,
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
a time counting means (for example, a special symbol waiting time management timer area) for managing a specific period in the arithmetic processing by the arithmetic processing means;
The time counting means includes a first time counting means (for example, an upper 2 byte timer) and a second time counting means (for example, a lower 2 byte timer),
When the specific period is a time that can be counted by one of the first time counting device and the second time counting device, the specific period is managed by the one time counting device. (For example, S6554 during special symbol game determination processing, etc.)
If the specific period cannot be counted by one of the first time counting device and the second time counting device, first, a part of the specific period can be counted by one of the first time counting device and the second time counting device. After the management by one time counting means is completed, the remaining period of the specific period is managed by the other time counting means (for example, special symbol related timer update processing).
A gaming machine characterized by:

Further, in the 44-1 gaming machine of the present invention, the first time counting means and the second time counting means may each be configured with a 2-byte timer.

Furthermore, in order to achieve the thirty-first object, the present invention provides a forty-fourth-second gaming machine as described below.

Identification information display means (e.g., first special symbol display device 6061) that variably displays identification information (e.g., first special symbol) in response to establishment of a predetermined starting condition (e.g., winning of the first starting hole 6044). and,
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
a time counting means (for example, a special symbol waiting time management timer area) for managing a specific period in the arithmetic processing by the arithmetic processing means;
The time counting means includes a first time counting means (for example, an upper 2 byte timer) and a second time counting means (for example, a lower 2 byte timer),
When the specific period is a time that can be counted by one of the first time counting device and the second time counting device, the specific period is managed by the one time counting device. (For example, S6554 during special symbol game determination processing, etc.)
If the specific period cannot be counted by one of the first time counting device and the second time counting device, first, a part of the specific period can be counted by one of the first time counting device and the second time counting device. After the management by one time counting means is completed, the remaining period of the specific period is managed by the other time counting means (for example, special symbol related timer update processing);
The time that can be counted by the one time counting means and the time that can be counted by the other time counting means are the same, but the period of time that can be counted by the one time counting means is a part of the specific period managed by the one time counting means. A gaming machine characterized in that the remaining period of the specific period managed by the other time counting means is a period different from each other.

In order to achieve the above thirty-first object, the present invention provides the following gaming machine No. 45-1.

Identification information display means (e.g., first special symbol display device 6061) that variably displays identification information (e.g., first special symbol) in response to establishment of a predetermined starting condition (e.g., winning of the first starting hole 6044). and,
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
a time counting means (for example, a special symbol waiting time management timer area) for managing a specific period in the arithmetic processing by the arithmetic processing means;
The time counting means includes a first time counting means (for example, an upper 2 byte timer) and a second time counting means (for example, a lower 2 byte timer),
When the specific period is a variable display period of the identification information, first, one of the first time counting means and the second time counting means is used to display a part of the variable display period. After the management by one of the time counting means is completed, the remaining period of the variable display period is managed by the other time counting means (for example, special symbol related timer update processing).
A gaming machine characterized by:

Further, in the 45-1 gaming machine of the present invention, a part of the variable display period is the first half of the variable display period, and the remaining period of the variable display period is the first half of the variable display period. The period may be in the latter half.

Furthermore, in order to achieve the d-31st object, the present invention provides the following 45-2 gaming machine.

Identification information display means (e.g., first special symbol display device 6061) that variably displays identification information (e.g., first special symbol) in response to establishment of a predetermined starting condition (e.g., winning of the first starting hole 6044). and,
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
a time counting means (for example, a special symbol waiting time management timer area) for managing a specific period in the arithmetic processing by the arithmetic processing means;
The time counting means includes a first time counting means (for example, an upper 2 byte timer) and a second time counting means (for example, a lower 2 byte timer),
When the specific period is a variable display period of the identification information, first, one of the first time counting means and the second time counting means is used to display a part of the variable display period. and after the management by the one time counting means is completed, the remaining period of the variable display period is managed by the other time counting means (for example, special symbol related timer update processing),
A part of the variable display period managed by the one time counting means and a remaining period of the variable display period managed by the other time counting means are mutually different periods, and a part of the variable display period is managed by the other time counting means. A gaming machine characterized in that the period of may be 0.

According to the thirty-second to forty-fifth gaming machines of the present invention having the above-mentioned configurations, the processing performed by the main control circuit can be executed more efficiently, and the processing load on the main control circuit can be reduced.

[46th to 56th gaming machines]
Conventionally, pachinko gaming machines are known that are equipped with a plurality of symbol display devices (display areas) and are provided with a function that allows the plurality of symbol display devices to simultaneously display identification information in a variable manner (for example, Japanese Patent Laid-Open No. 2015-150303 (see official bulletin).

By the way, the gaming machine described above usually has a main control board on which a circuit (main control circuit) for controlling main gaming operations such as determination of identification information is mounted, and a circuit (main control circuit) for controlling performance operations such as displaying images. and a sub-control board on which a sub-control circuit (sub-control circuit) is mounted. The gaming operation is controlled by a CPU (Central Processing Unit) installed in the main control circuit. At this time, under the control of the CPU, programs and various table data stored in the ROM (Read Only Memory) of the main control circuit are expanded to the RAM (Random Access Memory) of the main control circuit, and processing related to various gaming operations is executed. be done. In recent years, in such gaming machines, there has been a demand for reducing the capacity of processing programs managed by the main control circuit.

The present invention has been made to solve the above thirty-second problem, and the thirty-second object of the present invention is to provide a gaming machine that can reduce the capacity of processing programs managed by the main control circuit. That's true.

In order to achieve the above thirty-second object, the present invention provides the following forty-sixth gaming machine.

A first identification information display means (for example, a first special symbol) that variably displays first identification information (for example, a first special symbol) triggered by the establishment of a first start condition (for example, a winning of the first starting hole 6044). 1 special symbol display device 6061),
A second identification information display means (for example, a second special symbol) that variably displays second identification information (for example, a second special symbol) is triggered by the establishment of a second start condition (for example, a winning of the second starting hole 6045). 2 special symbol display device 6062),
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
a first index table (for example, a first special symbol-related definition data table) storing reference information for calling information used when executing processing related to the variable display of the first identification information by the arithmetic processing means; )and,
a second index table (for example, a second special symbol-related definition data table) storing reference information for calling information used when executing processing related to the variable display of the second identification information by the arithmetic processing means; )and,
A gaming machine equipped with.

Further, in the forty-sixth gaming machine of the present invention, the address of the second index table is stored in the last storage area in the first index table, and the last storage area in the second index table The address of the first index table may be stored in the storage area.

In order to achieve the above 32nd object, the present invention provides a 47th-1 gaming machine as described below.

A first identification information display means (for example, a first special symbol) that variably displays first identification information (for example, a first special symbol) triggered by the establishment of a first start condition (for example, a winning of the first starting hole 6044). 1 special symbol display device 6061),
A second identification information display means (for example, a second special symbol) that variably displays second identification information (for example, a second special symbol) is triggered by the establishment of a second start condition (for example, a winning of the second starting hole 6045). 2 special symbol display device 6062),
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
Information used when executing a process related to a variable display of the first identification information by the arithmetic processing means, and information used when executing a process related to a variable display of the second identification information by the arithmetic processing means. An index table that stores reference information for calling information,
A gaming machine equipped with.

Further, in the 47-1 gaming machine of the present invention, during the variable display of one of the identification information by one of the first identification information display means and the second identification information display means, The other identification information display means may be configured to start displaying the other identification information in a variable manner.

Moreover, in order to achieve the above-mentioned 32nd object, the present invention provides the following 47th-2nd gaming machine.

A first identification information display means (for example, a first special symbol) that variably displays first identification information (for example, a first special symbol) triggered by the establishment of a first start condition (for example, a winning of the first starting hole 6044). 1 special symbol display device 6061),
A second identification information display means (for example, a second special symbol) that variably displays second identification information (for example, a second special symbol) is triggered by the establishment of a second start condition (for example, a winning of the second starting hole 6045). 2 special symbol display device 6062),
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
Information used when executing a process related to a variable display of the first identification information by the arithmetic processing means, and information used when executing a process related to a variable display of the second identification information by the arithmetic processing means. Equipped with an index table storing reference information for recalling information,
In order to call, in the index table, information used when executing a process related to a variable display of the first identification information and information used when executing a process related to a variable display of the second identification information. The address of each storage area of the reference information is defined by a relative value (for example, an offset value) from the top address of the index table.

In order to achieve the above thirty-second object, the present invention provides the following forty-eighth gaming machine.

A first identification information display means (for example, a first special symbol) that variably displays first identification information (for example, a first special symbol) triggered by the establishment of a first start condition (for example, a winning of the first starting hole 6044). 1 special symbol display device 6061),
A second identification information display means (for example, a second special symbol) that variably displays second identification information (for example, a second special symbol) is triggered by the establishment of a second start condition (for example, a winning of the second starting hole 6045). 2 special symbol display device 6062),
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
a first data table (for example, a first special symbol work area table) storing information used when executing processing related to the variable display of the first identification information by the arithmetic processing means;
a second data table (for example, a second special symbol work area table) in which information used when executing processing related to the variable display of the second identification information by the arithmetic processing means;
In the first data table, the second identification of the same type as the predetermined information is stored in a storage area at an address separated by a predetermined offset value from the address of the storage area of predetermined information regarding the first identification information. Information about information is stored;
In the second data table, the first information of the same type as the specific information is stored in a storage area at an address separated by the predetermined offset value from the address of the storage area of specific information related to the second identification information. Information regarding identification information is stored,
In the process related to the variable display of the first identification information, when reading information related to the second identification information of the same type as the predetermined information stored in the first data table, the calculation process The means sets the address of the storage area of the predetermined information as a reference address, corrects the address by the predetermined offset value with respect to the reference address, and selects the same type of information as the predetermined information based on the corrected address. reading information regarding the second identification information;
In the process related to the variable display of the second identification information, when reading information related to the first identification information of the same type as the specific information stored in the second data table, the calculation process The means sets the address of the storage area of the specific information as a reference address, corrects the address by the predetermined offset value with respect to the reference address, and selects the same type of information as the specific information based on the corrected address. A gaming machine characterized by reading out information related to first identification information.

Further, in the forty-eighth gaming machine of the present invention, the predetermined offset value may be added to the reference address in the address correction process by the arithmetic processing means.

In order to achieve the above thirty-second object, the present invention provides the following forty-ninth gaming machine.

Triggered by the establishment of a predetermined starting condition (for example, winning of the second starting opening 6045), either a special game state (for example, a jackpot game state) or a specific game state (for example, a small win game state) that is advantageous to the player is activated. A gaming state transition determining means (for example, main CPU 6101) that determines whether to transition to a certain state or not;
Identification information display means (for example, second special symbol display device 6062) that variably displays identification information (for example, second special symbol) based on the determination result by the gaming state transition determination means;
a first determining means for determining whether or not the determination result by the gaming state transition determining means is to transition to the special gaming state;
a second determining means for determining whether or not the determination result by the gaming state transition determining means is to transition to the specific gaming state;
Common processing (for example, special symbol hit determination processing) is used in the determination processing by the first determination means and the determination processing by the second determination means,
A plurality of types of setting values are provided with mutually different probabilities that the gaming state transition determining means determines to transition to the special gaming state,
The game state transition determining means changes the special game state and the specific game using data stored in a predetermined storage area designated based on a parameter (address offset value) determined according to the setting value. A gaming machine characterized by determining whether or not to transition to one of the states.

In order to achieve the above-mentioned 32nd object, the present invention provides the following 50th gaming machine.

Identification information display means (e.g., first special symbol display device 6061) that variably displays identification information (e.g., first special symbol) in response to establishment of a predetermined starting condition (e.g., winning of the first starting hole 6044). and,
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
storage means (for example, main RAM 6103) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
a storage means (for example, an IY register) capable of storing specific information when the arithmetic processing is executed by the arithmetic processing means;
When the arithmetic processing means performs arithmetic processing for controlling the operation of changing display of the identification information, the arithmetic processing means stores an area (for example, a special symbol work) in the storage means in which information used for the arithmetic processing is stored. A gaming machine characterized in that address information of an area table) is stored in the storage means, and information necessary for the arithmetic processing is read from the storage means using the address information stored in the storage means.

Further, in the fiftieth gaming machine of the present invention, the identification information display means:
A first identification information display means (for example, a first special symbol) that variably displays first identification information (for example, a first special symbol) triggered by the establishment of a first start condition (for example, a winning of the first starting hole 6044). 1 special symbol display device 6061),
A second identification information display means (for example, a second special symbol) that variably displays second identification information (for example, a second special symbol) is triggered by the establishment of a second start condition (for example, a winning of the second starting hole 6045). 2 special symbol display device 6062),
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
The arithmetic processing means is
When performing arithmetic processing to control the operation of changing display of the first identification information, address information of a first area in the storage means in which information used for the arithmetic processing is stored is stored. reading information necessary for the arithmetic processing from the storage means, stored in the storage means, and using the address information of the first area stored in the storage means;
When performing arithmetic processing to control the operation of fluctuating display of the second identification information, address information of a second area in the storage means in which information used for the arithmetic processing is stored is stored. The information may be stored in the storage means and used for address information of the second area stored in the storage means to read information necessary for the arithmetic processing from the storage means.

In order to achieve the above thirty-second object, the present invention provides the following fifty-first gaming machine.

Identification information display means (e.g., first special symbol display device 6061) that variably displays identification information (e.g., first special symbol) in response to establishment of a predetermined starting condition (e.g., winning of the first starting hole 6044). and,
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
storage means (for example, main RAM 6103) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
a register (for example, an IY register) capable of storing specific information when the arithmetic processing is executed by the arithmetic processing means;
When the arithmetic processing means performs arithmetic processing for controlling the operation of changing the display of the identification information, the arithmetic processing means stores an area (for example, an area for special design work) in the storage means in which information used for the arithmetic processing is stored. A gaming machine characterized in that address information of an area table) is stored in the register, and information necessary for the arithmetic processing is read from the storage means using the address information stored in the register.

Furthermore, in order to achieve the above thirty-second object, the present invention provides a fifty-first-second gaming machine as described below.

Identification information display means (e.g., first special symbol display device 6061) that variably displays identification information (e.g., first special symbol) in response to establishment of a predetermined starting condition (e.g., winning of the first starting hole 6044). and,
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
storage means (for example, main RAM 6103) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
a first register (for example, an IY register) capable of storing specific information when the arithmetic processing is executed by the arithmetic processing means;
a second register (for example, an IX register) capable of storing predetermined information when the arithmetic processing is executed by the arithmetic processing means;
The arithmetic processing means is
When performing arithmetic processing to control the operation of changing display of the identification information,
Address information of a first area (for example, a special symbol work area table) in the storage means in which information used for the arithmetic processing is stored is stored in the first register; reading information necessary for the arithmetic processing from the storage means using the stored address information;
Address information of a second area (for example, a special symbol related definition data table) in the storage means in which reference information for calling information used when executing the arithmetic processing is stored in the second register. and reading out the reference information necessary for the arithmetic processing from the storage means using the address information stored in the second register.

In order to achieve the above thirty-second object, the present invention provides the following fifty-second gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game;
Storage means (for example, main RAM 6103) in which information necessary for execution of control processing by the game control means is stored;
Interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
a first initial setting means (for example, a first normal game pre-processing) that performs a first initial setting process when the storage means is cleared;
a second initial setting means (for example, a second normal game pre-processing) that performs a second initial setting process when the power is restored;
The interrupt processing execution means has a setting control means (for example, S6016 during system timer interrupt processing) that controls a change processing or confirmation processing of a setting value indicating the advantageous degree of the game,
When the setting control means performs the setting value change processing, the first initial setting means can execute the first initial setting processing, and the setting control means performs the setting value confirmation processing. A gaming machine characterized in that, at times, the second initial setting process can be executed by the second initial setting means.

In the fifty-second gaming machine of the present invention, the interrupt processing execution means further includes a setting operation means (for example, a setting key 6080) that triggers the execution of the setting value change processing or confirmation processing by the setting control means. ) has a setting operation determination means (for example, S6015 during system timer interrupt processing) that determines the operation status of the
When the setting control means performs a process of changing the setting value and the setting operation determining means determines that the setting operation means is in an off state, the first initial setting process is executed by the first initial setting means. and when the setting control means performs the setting value confirmation process and the setting operation determining means determines that the setting operation means is in the OFF state, the second initial setting process is performed by the second initial setting means. may be executed.

In order to achieve the above-mentioned 32nd object, the present invention provides the following 53rd-1st gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game;
Storage means (for example, main RAM 6103) in which information necessary for execution of control processing by the game control means is stored;
Interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
Initial setting means (for example, first normal game pre-processing or second normal game pre-processing) that performs initial setting processing when the power is restored or when the storage means is cleared,
The interrupt processing execution means has a setting control means (for example, S6016 during system timer interrupt processing) that controls a change processing or confirmation processing of a setting value indicating the advantageous degree of the game,
A gaming machine characterized in that when the setting control means performs confirmation processing or changing processing of the setting value, the initial setting processing can be executed by the initial setting means.

Moreover, in order to achieve the above-mentioned 32nd object, the present invention provides the following 53rd-2nd gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game;
Storage means (for example, main RAM 6103) in which information necessary for execution of control processing by the game control means is stored;
Interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
Initial setting means (for example, first normal game pre-processing or second normal game pre-processing) that performs initial setting processing when the power is restored or when the storage means is cleared,
The interrupt processing execution means has a setting control means (for example, S6016 during system timer interrupt processing) that controls a change processing or confirmation processing of a setting value indicating the advantageous degree of the game,
When the setting control means performs a confirmation process or a change process of the set value, the initial setting process is executable by the initial setting means,
The contents of the initial setting process executed by the initial setting means when the setting value confirmation process is performed by the setting control means are as follows: A gaming machine characterized in that the content of the initial setting process is different from the content of the initial setting process executed by the initial setting means.

In order to achieve the above thirty-second object, the present invention provides the following fifty-fourth gaming machine.

A first determining means (for example, the main CPU6101) and
a first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on a determination result by the first determination means;
A second determining means (for example, the main CPU6101) and
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second determination means; Equipped with
The first gaming state and the second gaming state include a special gaming state (for example, a jackpot gaming state),
At least one of the first gaming state and the second gaming state further includes a specific gaming state (for example, a small winning gaming state) different from the special gaming state,
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
When the fluctuating display of one of the identification information ends, in a specific case where the manner in which the fluctuating display of one of the identification information is stopped is a mode of transitioning to the special gaming state or the specific gaming state, the other identification information A predetermined control flag (for example, a special symbol suspension flag) for determining the control mode of the fluctuation display of is set to the on state,
In the case where the mode of stopping the fluctuating display of one of the identification information is a mode of transitioning to the special gaming state,
When the other identification information is not being displayed in a variable manner, the variable display of the other identification information is controlled not to start;
When the other identification information is being displayed in a fluctuating manner, the manner in which the fluctuating display of the other identification information is stopped is controlled such that it does not cause the player to shift to the special gaming state or the specific gaming state. Game machine.

Further, in the 54th gaming machine of the present invention, arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
a first index table (for example, a first special symbol-related definition data table) storing reference information for calling information used when executing processing related to the variable display of the first identification information by the arithmetic processing means; )and,
a second index table (for example, a second special symbol-related definition data table) storing reference information for calling information used when executing processing related to the variable display of the second identification information by the arithmetic processing means; ) and may further be provided.

In order to achieve the above thirty-second object, the present invention provides the following fifty-fifth gaming machine.

A first determination for determining whether to transition to a special gaming state advantageous to the player (for example, a jackpot gaming state) based on the establishment of a first starting condition (for example, winning of the first starting opening 6044). means (for example, main CPU 6101);
a first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on a determination result by the first determination means;
A second determination means (for example, the main CPU 6101 )and,
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second determination means; Equipped with
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
A predetermined control flag (for example, a special symbol suspension flag) is provided for determining a control mode of the fluctuating display of the first or second identification information,
When the predetermined control flag for the first identification information is set to the on state in a state where the variable display of the first or second identification information can be started, the variable display of the first identification information A game machine characterized in that the state of the variable display of the first identification information is set to a standby state without starting the game.

Further, in the fifty-fifth gaming machine of the present invention, further, during the variable display of one of the first identification information and the second identification information, a start condition is satisfied for one of the identification information. In this case, a judgment result storage means (for example, a special symbol reservation number area) is provided for storing the judgment result by one judgment means corresponding to the one identification information at the time of establishment, within a predetermined upper limit number,
When the predetermined control flag for the one identification information is set to an on state in a state where the fluctuation display of the one identification information can be started, the judgment stored in the judgment result storage means The process of determining the number of results (for example, S6494 during the special symbol standby process) may not be performed.

In order to achieve the above thirty-second object, the present invention provides the following fifty-sixth gaming machine.

A first determining means (for example, the main CPU6101) and
a first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on a determination result by the first determination means;
A second determining means (for example, the main CPU6101) and
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second determination means; Equipped with
The first gaming state and the second gaming state include a special gaming state (for example, a jackpot gaming state),
At least one of the first gaming state and the second gaming state includes a specific gaming state (for example, a small winning gaming state) different from the special gaming state,
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
When the fluctuating display of the one identification information ends, a predetermined control flag (for example, a special symbol pause flag) for determining a control mode of the fluctuating display of the one identification information is set to an on state. In this case, a process of determining whether or not the manner in which the fluctuating display of one of the pieces of identification information is stopped until at least the predetermined control flag is set to an off state is a manner in which the change is made to the special gaming state or the specific gaming state. is not performed (for example, S6513 during special symbol variation end processing)
A gaming machine characterized by:

Furthermore, in order to achieve the above thirty-second object, the present invention provides a fifty-sixth-second gaming machine as described below.

A first determining means (for example, the main CPU6101) and
a first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on a determination result by the first determination means;
A second determining means (for example, the main CPU6101) and
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second determination means; Equipped with
The first gaming state and the second gaming state include a special gaming state (for example, a jackpot gaming state),
At least one of the first gaming state and the second gaming state includes a specific gaming state (for example, a small winning gaming state) different from the special gaming state,
While one of the first identification information display means and the second identification information display means is displaying one of the identification information in a fluctuating manner, the other identification information display means may display the other identification information in a fluctuating manner. can be started and
When the fluctuating display of the one identification information ends, a predetermined control flag (for example, a special symbol pause flag) for determining a control mode of the fluctuating display of the one identification information is set to an on state. In this case, a process of determining whether or not the manner in which the fluctuating display of one of the pieces of identification information is stopped until at least the predetermined control flag is set to an off state is a manner in which the change is made to the special gaming state or the specific gaming state. is not performed (for example, S6513 during special symbol fluctuation end processing),
When the fluctuating display of the one identification information ends, the predetermined control flag is set to an on state, and the mode of stopping the fluctuating display of the one identification information is a mode of transitioning to the special gaming state, A gaming machine characterized in that, when the other identification information is being displayed in a variable manner, the manner in which the other identification information is displayed in a variable manner is such that it does not shift to the special gaming state or the specific gaming state.

According to the forty-sixth to fifty-sixth gaming machines of the present invention having the above configurations, it is possible to reduce the capacity of the processing program managed by the main control circuit.

[57th to 59th gaming machines]
Conventionally, pachinko gaming machines are known that are equipped with a plurality of symbol display devices (display areas) and are provided with a function that allows the plurality of symbol display devices to simultaneously display identification information in a variable manner (for example, Japanese Patent Laid-Open No. 2015-150303 (see official bulletin).

By the way, the gaming machine described above usually has a main control board on which a circuit (main control circuit) for controlling main gaming operations such as determination of identification information is mounted, and a circuit (main control circuit) for controlling performance operations such as displaying images. and a sub-control board on which a sub-control circuit (sub-control circuit) is mounted. The gaming operation is controlled by a CPU (Central Processing Unit) installed in the main control circuit. At this time, under the control of the CPU, programs and various table data stored in the ROM (Read Only Memory) of the main control circuit are expanded to the RAM (Random Access Memory) of the main control circuit, and processing related to various gaming operations is executed. be done. In recent years, such gaming machines have been required to reduce the amount of data such as tables managed by the main control circuit.

The present invention has been made to solve the above thirty-third problem, and the thirty-third object of the present invention is to provide a gaming machine that can reduce the amount of data managed by the main control circuit. It is.

In order to achieve the above thirty-third object, the present invention provides the following fifty-seventh gaming machine.

A first game in which it is determined whether or not to shift to a special game state advantageous to the player (for example, a jackpot game state) based on the establishment of a first starting condition (for example, winning of the first starting opening 6044). A state transition determining means (for example, main CPU 6101),
A first identification information display means (for example, a first special symbol display device 6061) that variably displays first identification information (for example, a first special symbol) based on the determination result by the first gaming state transition determination means. )and,
Is the establishment of the second starting condition (e.g., winning of the second starting opening 6045) triggered by the transition to either the special gaming state or the specific gaming state (e.g., small winning gaming state) advantageous to the player? A second game state transition determining means (for example, main CPU 6101) that determines whether
a second identification information display means (for example, a second special symbol display device 6062) that variably displays second identification information (for example, a second special symbol) based on the determination result by the second gaming state transition determination means; )and,
Whether or not the determination result by the first gaming state transition determining means is to transition to the special gaming state, or whether the determination result by the second gaming state transition determining means is to cause the transition to the special gaming state and the specific game. a determination means (for example, special symbol hit determination processing) for determining whether or not the state is to be shifted to one of the states;
When executing the determination process by the determination means, information regarding the type of identification information to be determined is used as an argument;
When the argument is information regarding the first identification information, in the determination process, only a determination is made as to whether or not the determination result is to cause a transition to the special gaming state;
When the argument is information regarding the second identification information, in the determination process, it is determined whether the determination result is to cause the transition to either the special gaming state or the specific gaming state. carried out,
A plurality of types of setting values are provided, each of which has a different probability that the first and second gaming state transition determining means will determine the transition to the special gaming state,
The first game state transition determining means transitions to the special game state using data stored in a predetermined storage area designated based on a parameter (address offset value) determined according to the setting value. Decide whether to migrate or not,
The second gaming state transition determining means determines the special gaming state and the specific gaming state using data stored in a specific storage area designated based on parameters determined according to the set values. A gaming machine characterized by determining whether or not to shift to either one.

Further, in the 57th gaming machine of the present invention, while one of the identification information display means of the first identification information display means and the second identification information display means is displaying a variation of the identification information, the other identification information is displayed. The identification information display means may be able to start displaying the other identification information in a variable manner.

In order to achieve the thirty-third object, the present invention provides the following fifty-eighth gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
Interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
A setting operation means (for example, a setting key 6080) that is operated when executing a process of changing or confirming a setting value indicating the degree of advantage of the game,
The interrupt processing execution means has a setting control means (for example, S6016 during system timer interrupt processing) that controls the setting value change processing or confirmation processing,
The determination of the start of execution of the control process by the setting control means is made based on the detection of a predetermined operation on the setting operation means (for example, an ON edge) indicating the start of the execution of the control process, and the determination of whether the execution of the control process by the setting control means is completed The determination is made based on the detection of a specific operation (for example, an OFF edge) indicating the end of the execution on the setting operation means,
The determination of whether or not the predetermined operation is detected and whether or not the specific operation is detected is determined based on operation information (for example, activation control flag) indicating the operation status of the setting operation means in the previous interrupt process and the current interrupt process. A gaming machine characterized in that the determination is made by comparing operation information indicating the operation status of the setting operation means in .

In order to achieve the above thirty-third object, the present invention provides the following gaming machine No. 59-1.

A game control means (for example, main control main processing) that controls the operation of the game,
Storage means (for example, main RAM 6103) in which information necessary for execution of control processing by the game control means is stored;
Interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
a first operation means (for example, a setting key 6080) that is operated when executing a process for changing or confirming a setting value indicating the degree of advantage of the game;
a second operation means (for example, a RAM clear switch 6121) that is operated when clearing the storage means,
The interrupt processing execution means has a setting control means (for example, S6016 during system timer interrupt processing) that controls the setting value change processing or confirmation processing,
Whether or not the control process is executed by the setting control means is determined by a combination of first operation information indicating the operation status of the first operation means and second operation information indicating the operation status of the second operation means (for example, activation). control flag).

Furthermore, in order to achieve the above thirty-third object, the present invention provides the following gaming machine No. 59-2.

A game control means (for example, main control main processing) that controls the operation of the game;
Storage means (for example, main RAM 6103) in which information necessary for execution of control processing by the game control means is stored;
Interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means;
a first operation means (for example, a setting key 6080) that is operated when executing a process for changing or confirming a setting value indicating the degree of advantage of the game;
a second operation means (for example, a RAM clear switch 6121) that is operated when clearing the storage means,
The interrupt processing execution means has a setting control means (for example, S6016 during system timer interrupt processing) that controls the setting value change processing or confirmation processing,
Whether or not the control process is executed by the setting control means is determined by a combination of first operation information indicating the operation status of the first operation means and second operation information indicating the operation status of the second operation means (for example, activation). control flag)
The combination of the first operation information and the second operation information when the setting value change process is performed by the setting control means is the same as the combination of the first operation information and the second operation information when the setting value confirmation process is performed by the setting control means. A gaming machine characterized in that the combination of the first operation information and the second operation information is different.

According to the 57th to 59th gaming machines of the present invention having the above configurations, it is possible to reduce the amount of data managed by the main control circuit.

[60th and 61st gaming machines]
Conventionally, pachinko gaming machines are known that are equipped with a plurality of symbol display devices (display areas) and are provided with a function that allows the plurality of symbol display devices to simultaneously display identification information in a variable manner (for example, Japanese Patent Laid-Open No. 2015-150303 (see official bulletin).

By the way, in the gaming machine described above, when the door/frame of the gaming machine is opened, the magnetic field becomes unstable (disturbed), which may have an adverse effect (malfunction, etc.) on the magnetic sensor provided in the gaming machine.

The present invention has been made in order to solve the above-mentioned thirty-fourth problem, and the thirty-fourth object of the present invention is that even if magnetic disturbance occurs when the door/frame of the game machine is opened, It is an object of the present invention to provide a game machine that can suppress the negative influence on a magnetic sensor.

In order to achieve the thirty-fourth object, the present invention provides the following sixtieth gaming machine.

A game machine main body (for example, main body 6002),
a door member (for example, a base door 6003 and/or a glass door 6004) attached to the gaming machine main body so as to be openable and closable;
A game board on which game media rolls,
magnetic sensor;
Comprising arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling game operations,
A gaming machine characterized in that when the door member is open, the arithmetic processing means clears the detection by the magnetic sensor.

Further, in the 60th gaming machine of the present invention, the initialization signal of the magnetic sensor is sent to a predetermined output port during a predetermined standby process (for example, wait process) performed by the arithmetic processing means after the power is restored. It may also be output.

Furthermore, the 60th gaming machine of the present invention includes a setting control means exposed on the back side of the gaming machine main body, which controls changing processing or confirmation processing of a setting value indicating the degree of advantage of a game,
When the door member is open, the settings may be changed by the setting control means.

In order to achieve the above thirty-fourth object, the present invention provides the following sixty-first gaming machine.

A game machine main body (for example, main body 6002),
a door member (for example, a base door 6003 and/or a glass door 6004) attached to the gaming machine main body so as to be openable and closable;
A game board on which game media rolls,
magnetic sensor;
Comprising arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling game operations,
A gaming machine characterized in that, after power is restored, an initialization signal of the magnetic sensor is output to a predetermined output port during a predetermined standby process (for example, wait process) performed by the arithmetic processing means.

Furthermore, in order to achieve the thirty-fourth object, the present invention provides the following sixty-first-second gaming machine.

A game machine main body (for example, main body 6002),
a door member (for example, a base door 6003 and/or a glass door 6004) attached to the gaming machine main body so as to be openable and closable;
A game board on which game media rolls,
magnetic sensor;
Arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling game operations;
A performance control means (for example, a sub-control circuit 6200) that controls the operation of the performance according to the progress of the game,
The arithmetic processing means clears the detection by the magnetic sensor at a predetermined timing (for example, when the first loop number is 10 times) within the activation waiting time of the production control means after the power is restored. A gaming machine with special features.

Furthermore, in order to achieve the thirty-fourth object, the present invention provides the following sixty-first-third gaming machine.

A game machine main body (for example, main body 6002),
a door member (for example, a base door 6003 and/or a glass door 6004) attached to the gaming machine main body so as to be openable and closable;
A game board on which game media rolls,
magnetic sensor;
Arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling game operations;
A performance control means (for example, a sub-control circuit 6200) that controls the operation of the performance according to the progress of the game,
The arithmetic processing means is updated during the start-up wait time of the production control means after the power is restored, when a predetermined parameter for counting the start-up wait time reaches a predetermined value (for example, in the first loop). A gaming machine characterized in that the detection by the magnetic sensor is cleared when the number of times is 10, for example.

According to the 60th and 61st gaming machines of the present invention having the above configurations, even if magnetic disturbance occurs when the door/frame of the gaming machine is opened, the adverse effect on the magnetic sensor provided in the gaming machine is suppressed. be able to.

[62nd and 63rd gaming machines]
Conventionally, pachinko gaming machines are known that are equipped with a plurality of symbol display devices (display areas) and are provided with a function that allows the plurality of symbol display devices to simultaneously display identification information in a variable manner (for example, Japanese Patent Laid-Open No. 2015-150303 (see official bulletin).

By the way, in the gaming machine described above, when the door/frame of the gaming machine is opened, the magnetic field becomes unstable (disturbed) or vibrations are generated, and various sensors installed in the gaming machine (for example, magnetic sensor, vibration sensors, etc.) may have an adverse effect (malfunction, etc.).

The present invention has been made in order to solve the above thirty-fifth problem, and the thirty-fifth object of the present invention is that even if magnetic disturbance or vibration occurs when opening the door/frame of the gaming machine, the gaming machine An object of the present invention is to provide a game machine that can suppress adverse effects on various sensors (for example, magnetic sensors, vibration sensors, etc.) provided in the game machine.

In order to achieve the above thirty-fifth object, the present invention provides the following sixty-second gaming machine.

A game machine main body (for example, main body 6002),
a door member (for example, a base door 6003 and/or a glass door 6004) attached to the gaming machine main body so as to be openable and closable;
A game board on which game media rolls,
An anomaly detection sensor that detects an anomaly;
Comprising arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling game operations,
The gaming machine characterized in that when the door member is open, the arithmetic processing means lowers the abnormality detection level of the abnormality detection sensor.

Further, in the 62-1 gaming machine of the present invention, when the door member is open, the arithmetic processing means sets the abnormality detection level of the abnormality detection sensor to a non-detection level. Good too.

Furthermore, in order to achieve the above thirty-fifth object, the present invention provides a sixty-second gaming machine as described below.

A game machine main body (for example, main body 6002),
a door member (for example, a base door 6003 and/or a glass door 6004) attached to the gaming machine main body so as to be openable and closable;
A game board on which game media rolls,
An anomaly detection sensor that detects an anomaly;
Arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling game operations;
and an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the calculation processing by the calculation control means,
When the door member is open, a process for lowering or maintaining the abnormality detection level of the abnormality detection sensor is performed each time the interrupt process execution means executes the interrupt process. .

In order to achieve the above thirty-fifth object, the present invention provides the following sixty-third-first gaming machine.

A game machine main body (for example, main body 6002),
a door member (for example, a base door 6003 and/or a glass door 6004) attached to the gaming machine main body so as to be openable and closable;
A game board on which game media rolls,
An anomaly detection sensor that detects an anomaly;
Comprising arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling game operations,
When the door member is open, the arithmetic processing means excludes abnormality detection by the abnormality detection sensor from the abnormality detection target.

Further, in the gaming machine No. 63-1 of the present invention, information defining an abnormality detection target (for example, information on input port 2) is provided,
When the door member is open, the arithmetic processing means may clear data included in the information that makes the abnormality detection sensor an abnormality detection target (for example, a magnetic sensor bit). .

Furthermore, in order to achieve the thirty-fifth object, the present invention provides the following sixty-third-second gaming machine.

A game machine main body (for example, main body 6002),
a door member (for example, a base door 6003 and/or a glass door 6004) attached to the gaming machine main body so as to be openable and closable;
A game board on which game media rolls,
An anomaly detection sensor that detects an anomaly;
Arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling game operations;
and an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the calculation processing by the calculation control means,
When the door member is open, in the interrupt processing by the interrupt processing execution means, before performing the processing to determine whether or not an abnormality is detected, processing to remove the abnormality detected by the abnormality detection sensor from the abnormality detection target. A gaming machine characterized by:

According to the sixty-second and sixty-third gaming machines of the present invention having the above configuration, even if magnetic disturbance or vibration occurs when the door/frame of the gaming machine is opened, various sensors provided in the gaming machine (for example, magnetic (vibration sensors, vibration sensors, etc.) can be suppressed.

[64th and 65th gaming machines]
Conventionally, pachinko gaming machines are known that are equipped with a plurality of symbol display devices (display areas) and are provided with a function that allows the plurality of symbol display devices to simultaneously display identification information in a variable manner (for example, Japanese Patent Laid-Open No. 2015-150303 (see official bulletin).

By the way, recent pachinko gaming machines are provided with a plurality of setting values ("1" to "6") that differ in the degree of advantage of the game (for example, probability of winning the jackpot, etc.), and these setting values can be changed or confirmed. A setting key is provided to enable this. For such gaming machines, there is a need for technology that can more reliably grasp the operation status (on/off) of the setting keys at startup and accurately identify the startup state of the gaming machine. .

The present invention has been made to solve the thirty-sixth problem described above, and the thirty-sixth object of the present invention is to more reliably grasp the operation status of the setting keys at the time of startup, and to check the startup state of the gaming machine. To provide a gaming machine that can be accurately identified.

In order to achieve the above thirty-sixth object, the present invention provides the following sixty-fourth gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
A performance control means (for example, a sub-control circuit 6200) that controls the operation of the performance according to the progress of the game;
A setting operation means (for example, a setting key 6080) that is operated when executing a process of changing or confirming a setting value indicating the degree of advantage of the game,
When the power is restored, the game control means saves operation information indicating the operation status of the setting operation means before performing a startup wait process on the production control means side (for example, S6205 during main control main processing). (For example, S6204 during main control main processing).

Further, the 64-1 gaming machine of the present invention further includes a storage means (for example, main RAM 6103) in which information necessary for execution of control processing by the game control means is stored,
The game control means may perform a process of checking the sum value of the storage means after the startup waiting process on the side of the performance control means.

Furthermore, in order to achieve the thirty-sixth object, the present invention provides a sixty-fourth-second gaming machine as follows.

A game control means (for example, main control main processing) that controls the operation of the game;
A performance control means (for example, a sub-control circuit 6200) that controls the operation of the performance according to the progress of the game;
A setting operation means (for example, a setting key 6080) that is operated when executing a process of changing or confirming a setting value indicating the degree of advantage of the game,
The game control means is
When the power is restored, before performing a startup wait process (for example, S6205 during main control main processing) on the side of the production control means, processing to save operation information indicating the operation status of the setting operation means (for example, main control main processing) is performed. Perform S6204) during processing,
After the activation waiting process on the side of the production control means, the activation state determination process is performed based on the operation information indicating the operation status of the setting operation means (for example, S6218 during the main control main process).
A gaming machine characterized by:

In order to achieve the above thirty-sixth object, the present invention provides the following sixty-fifth-first gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game,
A performance control means (for example, a sub-control circuit 6200) that controls the operation of the performance according to the progress of the game;
Storage means (for example, main RAM 6103) in which information necessary for execution of control processing by the game control means is stored;
a first operation means (for example, a setting key 6080) that is operated when executing a process for changing or confirming a setting value indicating the degree of advantage of the game;
a second operation means (for example, a RAM clear switch 6121) that is operated when clearing the storage means,
When the power is restored, the game control means generates first operation information indicating the operation status of the first operation means, before performing a startup wait process on the production control means side (for example, S6205 during the main control main process). The gaming machine is characterized in that a process (for example, S6204 during main control main processing) is performed to save second operation information indicating the operation status of the second operation means.

Furthermore, in order to achieve the thirty-sixth object, the present invention provides the following sixty-fifth-second gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game;
A performance control means (for example, a sub-control circuit 6200) that controls the operation of the performance according to the progress of the game;
Storage means (for example, main RAM 6103) in which information necessary for execution of control processing by the game control means is stored;
a first operation means (for example, a setting key 6080) that is operated when executing a process for changing or confirming a setting value indicating the degree of advantage of the game;
a second operation means (for example, a RAM clear switch 6121) that is operated when clearing the storage means,
The game control means is
When the power is restored, before performing the activation waiting process on the side of the production control means (for example, S6205 during main control main processing), first operation information indicating the operation status of the first operation means and the second operation Performing a process (for example, S6204 during main control main processing) to save second operation information indicating the operation status of the means,
After the startup wait processing on the side of the production control means, a startup state determination process is performed based on the first operation information and the second operation information (for example, S6218 during main control main processing).
A gaming machine characterized by:

According to the sixty-fourth and sixty-fifth gaming machines of the present invention having the above configurations, it is possible to more reliably grasp the operation status of the setting key at the time of startup, and to accurately identify the startup state of the gaming machine.

[66th and 67th gaming machines]
Conventionally, a pachinko gaming machine that shifts to a probability variable gaming state (hereinafter referred to as a "probability variable gaming state") after a jackpot gaming state ends is known (for example, see Japanese Patent Application Laid-Open No. 2014-103996). In the variable probability gaming state, identification information of a predetermined combination is derived and displayed with a higher probability than in normal times. In addition, the pachinko gaming machine disclosed in Japanese Patent Application Laid-open No. 2014-103996 is provided with a function to perform a lottery (fall lottery) to determine whether a fall in the game state is won or not during a variable game state. If the player wins, the variable probability gaming state ends and the game enters a gaming state in which identification information of a predetermined combination is derived and displayed with a normal probability.

By the way, the gaming machine described above usually has a main control board on which a circuit (main control circuit) for controlling main gaming operations such as determination of identification information is mounted, and a circuit (main control circuit) for controlling performance operations such as displaying images. and a sub-control board on which a sub-control circuit (sub-control circuit) is mounted. The gaming operation is controlled by a CPU (Central Processing Unit) installed in the main control circuit. At this time, under the control of the CPU, programs and various table data stored in the ROM (Read Only Memory) of the main control circuit are expanded to the RAM (Random Access Memory) of the main control circuit, and processing related to various gaming operations is executed. be done. In recent years, in such gaming machines, there has been a demand for reducing the capacity of processing programs managed by the main control circuit.

The present invention has been made to solve the thirty-seventh problem, and the thirty-seventh object of the present invention is to provide a gaming machine that can reduce the capacity of processing programs managed by the main control circuit. It is to be.

In order to achieve the above thirty-seventh object, the present invention provides the following sixty-sixth gaming machine.

Determining means (for example, determining whether or not to shift to a special gaming state advantageous to the player (for example, jackpot gaming state) upon fulfillment of a predetermined starting condition (for example, winning of the first starting opening 6044) main CPU6101) and
Identification information display means (for example, first special symbol display device 6061) that variably displays identification information (for example, first special symbol) based on the determination result by the determination means;
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
In a high probability gaming state (for example, a variable probability gaming state) in which the probability of transition to the special gaming state is determined by the determining means to be higher than the normal gaming state which is disadvantageous to the player, before the start of the variable display of the identification information. , a fall determining means (for example, a special symbol fall determination process) for determining whether or not to shift the gaming state to the normal gaming state;
a first data table (for example, a normal medium variation pattern table) used when determining a variation display pattern of the identification information in a first case where the gaming state is the normal gaming state;
a second data table (for example, a probability variation fluctuation pattern table) used when determining a variation display pattern of the identification information in a second case where the gaming state is the high probability gaming state;
A third data table (for example, when a fall (variable pattern table);
The arithmetic processing means is
Setting a parameter value (for example, a data selection offset addition value) indicating one of the first, second, and third cases according to the current gaming situation;
In the third case, the third data table is selected as the data table for determining the variation display pattern of the identification information based on the value of the parameter corresponding to the third case. A gaming machine with special features.

Furthermore, in order to achieve the thirty-seventh object, the present invention provides the following sixty-sixth-second gaming machine.

Determining means (for example, determining whether or not to shift to a special gaming state advantageous to the player (for example, jackpot gaming state) upon fulfillment of a predetermined starting condition (for example, winning of the first starting opening 6044) main CPU6101) and
Identification information display means (for example, first special symbol display device 6061) that variably displays identification information (for example, first special symbol) based on the determination result by the determination means;
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
In a high probability gaming state (for example, a variable probability gaming state) in which the probability of transition to the special gaming state is determined by the determining means to be higher than the normal gaming state which is disadvantageous to the player, before the start of the variable display of the identification information. , a fall determining means (for example, a special symbol fall determination process) for determining whether or not to shift the gaming state to the normal gaming state;
a first selection table (e.g., a special symbol variation pattern selection offset table) in which data (e.g., production variation table values) regarding a plurality of selectable types of variation display patterns of the identification information are defined;
A plurality of types of second selection tables (for example, special symbol variation pattern selection table group),
a third selection table (for example, a special symbol variation pattern selection table selection data table) in which data regarding the plurality of types of second selection tables are defined;
The arithmetic processing means is
Set the value of a parameter indicating the gaming situation (for example, data selection offset addition value) to a value corresponding to the current gaming situation,
Data regarding a predetermined second selection table is selected from the third selection table based on predetermined information (for example, jackpot symbols, gaming status, etc.), and data regarding the selected second selection table is selected. obtaining a reference address in the first selection table defined in the predetermined second selection table based on the data;
If the value of the parameter is a specific value (for example, "2") corresponding to when the fall determining means decides to shift the gaming state to the normal gaming state, the first selection A gaming machine characterized in that a variation display pattern of the identification information corresponding to data specified in an address obtained by adding an offset value corresponding to the specific value to the reference address in a table is selected.

In order to achieve the above thirty-seventh object, the present invention provides the following sixty-seventh gaming machine.

Determining means (for example, the main CPU6101) and
Identification information display means (for example, first special symbol display device 6061) that variably displays identification information (for example, first special symbol) based on the determination result by the determination means;
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
In a high probability gaming state (for example, a variable probability gaming state) in which the probability of transition to the special gaming state is determined by the determining means to be higher than the normal gaming state which is disadvantageous to the player, before the start of the variable display of the identification information. , a fall determining means (for example, a special symbol fall determination process) for determining whether or not to shift the gaming state to the normal gaming state;
A first data table (for example, a first data table (for example, a normal medium variation pattern table) and
In a second case where the gaming state after the end of the variable display of the identification information is the high-probability gaming state, a second data table (for example, a second data table (for example, fluctuation pattern table) and
A third data table (for example, when a fall (variable pattern table);
The arithmetic processing means is
Setting a parameter value (for example, a data selection offset addition value) indicating one of the first, second, and third cases according to the current gaming situation;
In the first case, the first data table is selected as a data table for determining a variation display pattern of the identification information based on the value of the parameter corresponding to the first case;
In the second case, the second data table is selected as a data table for determining a variation display pattern of the identification information based on the value of the parameter corresponding to the second case;
In the third case, the third data table is selected as the data table for determining the variation display pattern of the identification information based on the value of the parameter corresponding to the third case. A gaming machine with special features.

Further, in the gaming machine No. 67-1 of the present invention, the value of the parameter corresponding to the second case and the value of the parameter corresponding to the third case correspond to the first case. The reference value may be an offset value using the value of the parameter as the reference value.

Furthermore, in order to achieve the thirty-seventh object, the present invention provides a sixty-seventh-second gaming machine as described below.

Determining means (for example, determining whether or not to shift to a special gaming state advantageous to the player (for example, jackpot gaming state) upon fulfillment of a predetermined starting condition (for example, winning of the first starting opening 6044) main CPU6101) and
Identification information display means (for example, first special symbol display device 6061) that variably displays identification information (for example, first special symbol) based on the determination result by the determination means;
arithmetic processing means (for example, main CPU 6101) that performs arithmetic processing for controlling the operation of changing the display of the identification information;
In a high probability gaming state (for example, a variable probability gaming state) in which the probability of transition to the special gaming state is determined by the determining means to be higher than the normal gaming state which is disadvantageous to the player, before the start of the variable display of the identification information. , a fall determining means (for example, a special symbol fall determination process) for determining whether or not to shift the gaming state to the normal gaming state;
a first selection table (e.g., a special symbol variation pattern selection offset table) in which data (e.g., production variation table values) regarding a plurality of selectable types of variation display patterns of the identification information are defined;
A plurality of types of second selection tables (for example, special symbol variation pattern selection table group),
a third selection table (for example, a special symbol variation pattern selection table selection data table) in which data regarding the plurality of types of second selection tables are defined;
The arithmetic processing means is
Set the value of a parameter indicating the gaming situation (for example, data selection offset addition value) to a value corresponding to the current gaming situation,
Data regarding a predetermined second selection table is selected from the third selection table based on predetermined information (for example, jackpot symbols, gaming status, etc.), and data regarding the selected second selection table is selected. obtaining a reference address in the first selection table defined in the predetermined second selection table based on the data;
When the value of the parameter is a first specific value (for example, "0") corresponding to the gaming state after the end of the variable display of the identification information is the normal gaming state, the first select a variation display pattern of the identification information corresponding to the data specified in the reference address in the selection table of;
If the value of the parameter is a second specific value (for example, "1") that corresponds to the gaming state after the end of the variable display of the identification information is the high-probability gaming state, the second specific value (for example, "1") selecting a variation display pattern of the identification information corresponding to data specified in an address obtained by adding an offset value corresponding to the second specific value to the reference address in the selection table No. 1;
When the value of the parameter is a third specific value (for example, "2") corresponding to when the fall determining means determines to shift the gaming state to the normal gaming state, The gaming machine is characterized in that a variation display pattern of the identification information corresponding to data specified in an address obtained by adding an offset value corresponding to the third specific value to the reference address is selected in the selection table No. 1. .

According to the sixty-sixth and sixty-seventh gaming machines of the present invention having the above configuration, it is possible to reduce the capacity of the processing program managed by the main control circuit.

[68th and 69th gaming machines]
Conventionally, a pachinko gaming machine that shifts to a probability variable gaming state (hereinafter referred to as a "probability variable gaming state") after a jackpot gaming state ends is known (for example, see Japanese Patent Application Laid-Open No. 2014-103996). In the variable probability gaming state, identification information of a predetermined combination is derived and displayed with a higher probability than in normal times. In addition, the pachinko gaming machine disclosed in Japanese Patent Application Laid-open No. 2014-103996 is provided with a function to perform a lottery (fall lottery) to determine whether a fall in the game state is won or not during a variable game state. If the player wins, the variable probability gaming state ends and the game enters a gaming state in which identification information of a predetermined combination is derived and displayed with a normal probability.

By the way, the gaming machine described above usually has a main control board on which a circuit (main control circuit) for controlling main gaming operations such as determination of identification information is mounted, and a circuit (main control circuit) for controlling performance operations such as displaying images. and a sub-control board on which a sub-control circuit (sub-control circuit) is mounted. The gaming operation is controlled by a CPU (Central Processing Unit) installed in the main control circuit. At this time, under the control of the CPU, programs and various table data stored in the ROM (Read Only Memory) of the main control circuit are expanded to the RAM (Random Access Memory) of the main control circuit, and processing related to various gaming operations is executed. be done. In recent years, in such gaming machines, there has been a demand for the development of technology that can more efficiently execute the processing performed by the main control circuit and reduce the processing load on the main control circuit.

The present invention has been made to solve the above-mentioned thirty-eighth problem, and the thirty-eighth object of the present invention is to more efficiently execute the processing performed in the main control circuit and reduce the processing load on the main control circuit. The purpose of the present invention is to provide a gaming machine that can

In order to achieve the above thirty-eighth object, the present invention provides the following sixty-eighth-first gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game;
and an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means,
The interrupt processing execution means has an abnormality monitoring means (for example, general-purpose abnormality detection determination processing) capable of monitoring a plurality of types of abnormality items,
The gaming machine characterized in that the abnormality monitoring means determines that there is no abnormality with respect to an abnormal item that is not a monitoring target, regardless of whether or not there is an abnormality in the abnormal item.

Further, in the 68-1 gaming machine of the present invention, monitoring specific information is provided that specifies whether or not each of the plurality of abnormal items is to be monitored,
The abnormality monitoring means may determine whether or not there is an abnormality in the abnormal item based on information indicating whether the abnormal item has an abnormality and the monitoring specific information.

Furthermore, in order to achieve the thirty-eighth object, the present invention provides the following sixty-eighth-second gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game;
and an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means,
The interrupt processing execution means has an abnormality monitoring means (for example, general-purpose abnormality detection and determination processing) capable of monitoring a plurality of types of abnormality items,
The abnormality monitoring means determines that there is no abnormality in an abnormality item that is not a monitoring target, regardless of whether or not there is an abnormality in the abnormality item;
A gaming machine characterized in that the monitoring process by the abnormality monitoring means is not executed when the game is not permitted.

In order to achieve the above thirty-eighth object, the present invention provides the following sixty-ninth gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game;
and an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means,
The interrupt processing execution means has an abnormality monitoring means (for example, general-purpose abnormality detection and determination processing) capable of monitoring a plurality of types of abnormality items,
Monitoring specific information is provided that specifies whether or not each of the plurality of abnormal items is to be monitored,
The abnormality monitoring means includes:
Based on the information indicating the presence or absence of an abnormality in the abnormal item and the monitoring specific information, a determination is made as to the presence or absence of an abnormality for the abnormal item, and the determination is repeated for all abnormal items,
A gaming machine characterized in that, in determining an abnormal item that is not a monitoring target, the determination result of the presence or absence of an abnormality is determined to be no abnormality, regardless of whether or not there is an abnormality in the abnormal item.

Further, in the gaming machine according to the 69-1 aspect of the present invention, the abnormality monitoring means includes information indicating whether or not an abnormality exists in the abnormality item, and whether the abnormality item specified by the monitoring specific information is to be monitored. A logical AND operation may be performed with information indicating whether or not the abnormality item is abnormal, and based on the result of the logical AND operation, it may be determined whether or not there is an abnormality in the abnormal item.

Furthermore, in order to achieve the thirty-eighth object, the present invention provides the following sixty-nine-second gaming machine.

A game control means (for example, main control main processing) that controls the operation of the game;
and an interrupt processing execution means (for example, system timer interrupt processing) capable of executing interrupt processing at a predetermined period during the control processing by the game control means,
The interrupt processing execution means has an abnormality monitoring means (for example, general-purpose abnormality detection determination processing) capable of monitoring a plurality of types of abnormality items,
Monitoring specific information is provided that specifies whether or not each of the plurality of abnormal items is to be monitored,
The abnormality monitoring means includes:
Based on the information indicating the presence or absence of an abnormality in the abnormal item and the monitoring specific information, the presence or absence of an abnormality is determined for the abnormal item, and the determination is repeated for all abnormal items,
When making judgments on abnormal items that are not subject to monitoring, regardless of whether or not there is an abnormality in the abnormal item, the judgment result of the presence or absence of an abnormality is treated as no abnormality.
A gaming machine characterized in that the monitoring process by the abnormality monitoring means is not executed when the game is not permitted.

According to the sixty-eighth and sixty-ninth gaming machines of the present invention having the above-mentioned configurations, the processing performed by the main control circuit can be executed more efficiently, and the processing load on the main control circuit can be reduced.

[70th and 71st gaming machines]
Conventionally, a pachinko gaming machine that shifts to a probability variable gaming state (hereinafter referred to as a "probability variable gaming state") after a jackpot gaming state ends is known (for example, see Japanese Patent Application Laid-Open No. 2014-103996). In the variable probability gaming state, identification information of a predetermined combination is derived and displayed with a higher probability than in normal times. In addition, the pachinko gaming machine disclosed in Japanese Patent Application Laid-open No. 2014-103996 is provided with a function to perform a lottery (fall lottery) to determine whether a fall in the game state is won or not during a variable game state. If the player wins, the variable probability gaming state ends and the game enters a gaming state in which identification information of a predetermined combination is derived and displayed with a normal probability.

By the way, conventionally, in gaming machines equipped with the above-mentioned falling lottery function, it has been required to suppress a decrease in interest in the game even when a falling lottery is won.

The present invention has been made to solve the above-mentioned problem No. 39, and the thirty-ninth object of the present invention is to reduce the interest in playing the game when winning a lottery by falling, in a gaming machine equipped with a falling lottery function. The objective is to provide technology that can suppress this.

In order to achieve the thirty-ninth object, the present invention provides the following seventieth gaming machine.

Determining means (for example, determining whether or not to shift to a special gaming state advantageous to the player (for example, jackpot gaming state) upon fulfillment of a predetermined starting condition (for example, winning of the first starting opening 6044) main CPU6101) and
Identification information display means (for example, first special symbol display device 6061) that variably displays identification information (for example, first special symbol) based on the determination result by the determination means;
In a high probability gaming state (for example, a variable probability gaming state) in which the probability of transition to the special gaming state is determined by the determining means to be higher than the normal gaming state which is disadvantageous to the player, before the start of the variable display of the identification information. , a fall determining means (for example, a special symbol fall determination process) for determining whether or not to shift the gaming state to the normal gaming state;
an external signal output means that continues to output a predetermined external signal (for example, a first jackpot signal) during a high winning gaming state (for example, a time-saving gaming state) in which the probability that the predetermined starting condition is satisfied is high;
When the fall determining means decides to shift the gaming state to the normal gaming state and the high winning gaming state ends, the external signal outputting means A game machine characterized in that the output of the predetermined external signal is extended.

Further, in the 70th gaming machine of the present invention, an extension flag (for example, a first jackpot signal extension flag) indicating whether or not to extend the output of the predetermined external signal is provided,
When the fall determining means decides to shift the gaming state to the normal gaming state and the high winning gaming state ends, the extension flag is turned on before the start of the variable display of the identification information. , the extension flag may be turned off at the end of the variable display of the identification information.

In order to achieve the thirty-ninth object, the present invention provides the following seventy-first gaming machine.

Determining means (for example, determining whether or not to shift to a special gaming state advantageous to the player (for example, jackpot gaming state) upon fulfillment of a predetermined starting condition (for example, winning of the first starting opening 6044) main CPU6101) and
Identification information display means (for example, first special symbol display device 6061) that variably displays identification information (for example, first special symbol) based on the determination result by the determination means;
In a high probability gaming state (for example, a variable probability gaming state) in which the probability of transition to the special gaming state is determined by the determining means to be higher than the normal gaming state which is disadvantageous to the player, before the start of the variable display of the identification information. , a fall determining means (for example, a special symbol fall determination process) for determining whether or not to shift the gaming state to the normal gaming state;
an external device that continues to output a predetermined external signal (e.g., a first jackpot signal) during a high winning game state (for example, a time-saving game state) in which the probability that the predetermined starting condition is satisfied is high, and during the special game state; A signal output means;
If the fall determining means decides to shift the gaming state to the normal gaming state, and the high winning gaming state ends, and the high winning gaming state is in progress, the determining means determines that the special gaming state When the transition to the state is determined and the high winning game state ends, the output of the predetermined external signal by the external signal output means is extended until the fluctuating display of the identification information ends. A gaming machine characterized by:

Further, the 71st gaming machine of the present invention further includes a notification lamp (for example, a time-saving lamp) that is turned on during the high winning game state and turned off when the high winning winning game state ends. You can.

According to the seventieth and seventy-first gaming machines of the present invention having the above configurations, it is possible to suppress a decrease in interest in the game when a player wins a lottery by falling.

16,6013...Display device (liquid crystal display), 24,6011...Speaker, 35...Power switch, 100,6100...Main control circuit, 101,6101...Main CPU, 102,6102...Main ROM, 103,6103...Main RAM, 201... Sub CPU, 328, 6080... Setting key, 330, 6121... RAM clear switch (backup clear switch), 338... Power supply circuit, 662... Main button, 664... Select button, 1000... Accessories group, 1002 ... Accessory object detection sensor group, 2010 ... Relay board, 2100 ... Host control circuit, 6001 ... Pachinko game machine, 6002 ... Main body, 6003 ... Base door, 6004 ... Glass door, 6012 ... Game board, 6015 ... Launch device, 6016 ... Payout device, 6018... Lamp (LED) group, 6020... Accessory, 6043... Ball passage detector, 6044... First starting port, 6045... Second starting port, 6046... Ordinary electric accessory, 6051, 6052... General prize winning Mouth, 6053...First big prize opening, 6054...Second big prize opening, 6055...Out opening, 6056...Game nail, 6061...First special symbol display device, 6062...Second special symbol display device, 6063...Normal symbol Display device, 6064...First special symbol retention display device, 6065…Second special symbol retention display device, 6066…Normal symbol retention display device, 6070…Performance display monitor, 6071 Error notification monitor, 6081…Setting switch, 6140…External Terminal board, 6200...sub control circuit, 6300...dispensing/firing control circuit

Claims (1)

Identification information display means that variably displays identification information upon satisfaction of a predetermined start condition;
a first arithmetic processing means that performs arithmetic processing for controlling the operation of changing the display of the identification information;
storage means for storing information necessary for execution of the arithmetic processing by the first arithmetic processing means;
storage means capable of storing specific information when the first arithmetic processing means executes the arithmetic processing;
When the first arithmetic processing means performs arithmetic processing for controlling the operation of changing display of the identification information, the first arithmetic processing means stores a part of the area in the storage means in which information used for the arithmetic processing is stored. address information stored in the storage means, and based on the address information stored in the storage means, read information necessary for the arithmetic processing from the storage means,
The information used for the arithmetic processing stored in a part of the storage means includes a count value of a timer that manages a fluctuating display time of the identification information,
Further comprising, unlike the first arithmetic processing means, a second arithmetic processing means capable of performing arithmetic processing according to the result of the arithmetic processing of the first arithmetic processing means,
The second arithmetic processing means
It is possible to generate input information based on the input state of the operating means and to manage the generated input information,
After the input information is generated, as long as the input state of the operating means continues for a predetermined period of time, the input information can be generated;
Specific control can be executed on the condition that the input information has been generated,
The generation of the input information and the bank flip of the frame buffer are performed within a specific process that can be repeatedly executed at a predetermined period,
A gaming machine characterized in that the generation of the input information can be executed within one time of the specific processing before a bank flip of the frame buffer is completed.

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