JP6664266B2 - Gaming machine - Google Patents

Description

  The present invention relates to a gaming machine.

  Conventionally, a gaming machine called a pachinko gaming machine is known, and this pachinko gaming machine generally includes a gaming area in which a game ball fired on a gaming board can roll, and a starting area provided in the gaming area. , A symbol display device, and variable display control means for controlling the symbol display device. In such a gaming machine, the variable display control means controls the symbol display device when a predetermined condition such as that the game ball has passed through the starting area (the winning opening of the game ball) is established, and the symbol display device The identification information (for example, a special symbol to be described later) is variably displayed on the display area. When the identification information finally derived and displayed on the display area of the symbol display device is in a predetermined combination (specific display mode), the gaming state is a big hit gaming state advantageous to the player (a so-called “big hit”). )).

  Conventionally, there has been known a gaming machine having a function of performing an effect using a lamp in accordance with the above-mentioned gaming operation (for example, see Patent Document 1). In Patent Literature 1, a gaming machine using LEDs as lamps is proposed. Patent Literature 1 discloses a technique of storing various lighting patterns in which a plurality of LEDs are classified in a predetermined section to determine a lighting mode, and controlling the lighting of the plurality of LEDs according to a lighting pattern selected from the stored lighting patterns. Proposed.

JP 2004-166904 A

  As described above, conventionally, in a gaming machine having a function of performing an effect using a lamp, a technique of performing a lamp control according to a lighting pattern selected from a plurality of types of lighting patterns has been proposed. However, this lamp control technology is a technology for simply selecting a lighting pattern of a lamp according to the content of the effect. Therefore, when a plurality of effects are combined, there is a concern that the lighting control of the lamp becomes difficult with this lamp control technique, and that the control of the lighting pattern becomes complicated.

  In recent years, in the above-mentioned gaming machines, since the types of effects are increasing, it is expected that the number of combined effects will increase. Therefore, as a countermeasure for this tendency, it is conceivable to prepare a lighting pattern of a lamp for a composite effect. However, since the pattern of the composite effect dramatically increases in accordance with the number of the effects, it is difficult to prepare lighting patterns corresponding to all the patterns of the composite effect from the viewpoint of the productivity and the storage capacity of the gaming machine. is there.

  The present invention has been made to solve the above problems, and an object of the present invention is to enable accurate and simple control of an effect even when a plurality of effects are combined. Is to provide a simple gaming machine.

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

When the predetermined starting condition is satisfied, identification information (for example, a special symbol, a normal symbol, a decorative symbol, a reel symbol of a pachislot gaming machine, various decorative symbols displayed on various displays of the pachislot gaming machine, described later). A gaming machine that fluctuates,
Effect control means for controlling the effect (for example, a host control circuit 210 or a voice / LED control circuit 220 described later),
A light emitting unit (for example, a lamp (LED) group 18 described later) that performs a predetermined effect operation based on the driving data;
With
The effect control means,
Driving data (for example, LED data set for each channel) for generating the driving data can be set, and a plurality of systems (for example, the execution priorities of the set driving generation data are set respectively) , Channels described below)
Selection means for selecting, as the drive data, the drive generation data set to a predetermined system from among the plurality of systems according to the execution priority set to the system (for example, a lamp control process described later) And having
When the first drive generation data is set in the first system and the second drive generation data is set in the second system having a higher execution priority than the first system,
When the second drive generation data is data in a first non-lighting mode (for example, turn-off data to be described later), the selection unit selects the second drive generation data as the drive data, and When the second drive generation data is data of a second non-lighting mode different from the data of the first non-lighting mode (for example, transparent definition data described later), the selection unit outputs the first drive generation data. Is selected as the driving data,
When starting the variation display of the identification information, in accordance with the content of the effect, in at least one of the systems, at least immediately before starting the production operation of the light emitting means corresponding to the variation display of the identification information, A gaming machine wherein data of a second non-lighting mode is set.

  According to the gaming machine of the present invention having the above configuration, even when a plurality of types of effects are combined, the effects can be accurately and easily controlled.

It is a figure showing the functional flow of the pachinko gaming machine concerning one embodiment of the present invention. 1 is an external perspective view of a pachinko gaming machine according to one embodiment of the present invention. 1 is an exploded perspective view of a pachinko gaming machine according to one embodiment of the present invention. It is a front view showing the composition of the game board of the pachinko gaming machine concerning one embodiment of the present invention. It is a block diagram showing a circuit configuration of a pachinko gaming machine according to one embodiment of the present invention. It is a block diagram showing an internal configuration of a sub control circuit of the pachinko gaming machine according to one embodiment of the present invention. FIG. 3 is a block diagram showing an internal configuration of a voice / LED control circuit of the pachinko gaming machine according to one embodiment of the present invention. It is a schematic connection block diagram between the built-in relay board and the speaker of the pachinko gaming machine according to one embodiment of the present invention. It is a figure showing the internal composition of the voltage conversion circuit part of the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing the number of diodes provided in the voltage conversion circuit part of the pachinko gaming machine according to one embodiment of the present invention, and the element temperature of the linear regulator. It is a block diagram showing the internal configuration of the display control circuit of the pachinko gaming machine according to one embodiment of the present invention. 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 one embodiment of the present invention. FIG. 2 is a schematic connection configuration diagram between a sub board and a CGROM board (NAND type) of the pachinko gaming machine according to one embodiment of the present invention. 6 is a truth table for explaining an operation of an AND circuit provided on a sub-board of the pachinko gaming machine according to one embodiment of the present invention. 6 is a truth table for explaining an operation of the bidirectional balance transceiver provided on the sub board of the pachinko gaming machine according to one embodiment of the present invention. It is a figure showing an example of a big hit random number judgment table (at the time of the 1st starting opening prize) in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of a big hit random number judgment table (at the time of the 2nd starting opening prize) in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of a symbol judgment table (at the time of the 1st starting mouth winning) in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of the symbol judgment table (at the time of the 2nd starting mouth winning) in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of the big hit type decision table (the 1) in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of the big hit type decision table (the 2) in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of the big hit type decision table (the 3) in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of the big hit type decision table (the 4) in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of a prize effect information determination table in a pachinko gaming machine according to one embodiment of the present invention. It is a figure showing an example of the fluctuating effect pattern determination table in the pachinko gaming machine according to one embodiment of the present invention. It is a figure showing an example of the fluctuation effect table in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of a reservation effect table in a pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of the look ahead production table in the pachinko gaming machine concerning one embodiment of the present invention. FIG. 2 is a schematic configuration diagram of command data in the pachinko gaming machine according to one embodiment of the present invention. It is a figure showing the composition of the demonstration display command in the pachinko gaming machine concerning one embodiment of the present invention, and the contents of the information contained in the demonstration display command. It is a figure which shows the structure of the special symbol production start command and the content of the information included in the special symbol production start command in the pachinko gaming machine according to one embodiment of the present invention. It is a figure showing the composition of the 1st power-off restoration command in pachinko gaming machine concerning one embodiment of the present invention, and the contents of the information contained in the 1st power-off restoration command. It is a figure showing the composition of the 2nd power failure return command in pachinko gaming machine concerning one embodiment of the present invention, and the contents of the information contained in the 2nd power failure return command. It is a figure showing the composition of the suspension addition command in the pachinko gaming machine concerning one embodiment of the present invention, and the contents of the information contained in the suspension addition command. It is a figure for explaining the outline of the command control processing between the main and sub executed by the host control circuit (sub-control circuit) in the pachinko gaming machine according to one embodiment of the present invention. FIG. 2 is a schematic configuration diagram of a ring buffer provided inside a host control circuit in the pachinko gaming machine according to one embodiment of the present invention. It is a figure for explaining an outline of generation operation of various requests in a pachinko gaming machine concerning one embodiment of the present invention. It is a figure for explaining an outline of animation request construction processing in a pachinko gaming machine concerning one embodiment of the present invention. It is a figure for explaining an outline of animation request construction processing in a pachinko gaming machine concerning one embodiment of the present invention. It is a figure for explaining the outline of the drawing processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure for explaining an outline of a sound reproduction operation in a pachinko gaming machine according to one embodiment of the present invention. FIG. 3 is a schematic configuration diagram of access data used in a sound reproducing operation in the pachinko gaming machine according to one embodiment of the present invention. It is a figure for explaining an outline of a lamp (LED) lighting operation in a pachinko gaming machine according to one embodiment of the present invention. FIG. 2 is a schematic connection configuration diagram between a voice / LED control circuit, an LED driver, and an LED in a pachinko gaming machine according to an embodiment of the present invention. It is a SPI connection configuration diagram between a voice / LED control circuit and an LED driver in a pachinko gaming machine according to one embodiment of the present invention. FIG. 2 is a schematic configuration diagram of serial data transmitted from an audio / LED control circuit to an LED driver in the pachinko gaming machine according to one embodiment of the present invention. It is a schematic structure figure of the LED driver in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure for explaining the data input operation of the LED driver in the pachinko gaming machine according to one embodiment of the present invention. It is a figure for explaining the address setting operation of the LED driver in the pachinko gaming machine according to one embodiment of the present invention. FIG. 3 is a diagram showing a correspondence relationship between each SPI channel (physical system), a device address of an LED driver connected thereto, and an output terminal in the pachinko gaming machine according to one embodiment of the present invention. It is a figure showing the format (data type) of LED data in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing the example of output control of LED data in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing generation example 1 of LED animation in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing the example 2 of generation of LED animation in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing generation example 3 of LED animation in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing generation example 3 of LED animation in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing the example of composition of the reproduction channel and the expansion channel in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing the example of composition of the reproduction channel and the expansion channel in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing various examples of the switching reproduction pattern of LED animation in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing the switching reproduction mode (flow on the time axis) of the LED animation in the LED animation switching reproduction pattern 2 of the pachinko gaming machine according to one embodiment of the present invention. It is a figure showing the switching reproduction mode (flow on the time axis) of the LED animation in the switching reproduction pattern 4 of the LED animation of the pachinko gaming machine according to one embodiment of the present invention. FIG. 8 is a diagram showing an LED animation switching playback pattern (flow on the time axis) in an LED animation switching playback pattern 6 of the pachinko gaming machine according to one embodiment of the present invention. FIG. 8 is a diagram showing an LED animation switching playback mode (flow on a time axis) in an LED animation switching playback pattern 7 of the pachinko gaming machine according to one embodiment of the present invention. It is a figure showing a switching reproduction mode (flow on a time axis) at the time of continuous reproduction of the LED animation in the pachinko gaming machine according to one embodiment of the present invention. It is a figure showing the example of reproduction of LED animation at the time of “ODONLY” designation not having been designated in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure showing an example of reproduction of LED animation at the time of “ODONLY” designation in the pachinko gaming machine according to one embodiment of the present invention. It is a figure for explaining the outline of the accessory driving operation in the pachinko gaming machine according to one embodiment of the present invention. It is an I2C connection block diagram between the host control circuit and the motor driver in the pachinko gaming machine according to one embodiment of the present invention. It is a flowchart which shows an example of the main control main process performed by the main CPU in the pachinko gaming machine according to one embodiment of the present invention. It is a flow chart which shows an example of the special symbol control processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of special design memory check processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flowchart which shows an example of the special symbol display time management processing in the pachinko gaming machine according to one embodiment of the present invention. It is a flow chart which shows an example of big hit end interval processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flowchart which shows an example of a normal symbol control process in the pachinko gaming machine according to one embodiment of the present invention. It is a flowchart which shows an example of the process at the time of power-on performed by the main CPU in the pachinko gaming machine according to one embodiment of the present invention. It is a flowchart which shows an example of the system timer interruption process performed by the main CPU in the pachinko gaming machine according to one embodiment of the present invention. It is a flow chart which shows an example of switch input detection processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of starting opening winning detection processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the sub control main processing performed by the host control circuit (sub control circuit) in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure for explaining the outline of initialization processing performed by the host control circuit (sub-control circuit) in the pachinko gaming machine according to one embodiment of the present invention. It is a flow chart which shows an example of initialization processing performed by a host control circuit in a pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of backup return initialization processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the accessory control initialization processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of LED registration processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a figure for explaining the outline of the processing at the time of operation input performed by the host control circuit (sub-control circuit) in the pachinko gaming machine according to one embodiment of the present invention. It is a flow chart which shows an example of operation input timer interruption processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of operation input information acquisition processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the command reception processing (reception interruption) in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of reception data storage processing in a pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the command analysis processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the command parameter check processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of animation request construction processing in a pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the drawing control processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the animation command creation processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of animation data reading processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of all the command list creation processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flowchart which shows an example of the drawing process in the pachinko gaming machine concerning one Embodiment of this invention. It is a flowchart which shows an example of the drawing process in the pachinko gaming machine concerning one Embodiment of this invention. It is a flowchart which shows an example of the drawing process in the pachinko gaming machine concerning one Embodiment of this invention. It is a flowchart which shows an example of the audio | voice control process in the pachinko gaming machine concerning one Embodiment of this invention. It is a flow chart which shows an example of the ramp control processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flowchart which shows an example of the accessory control process in the pachinko gaming machine concerning one Embodiment of this invention. It is a flow chart which shows an example of a character processing at the time of a change start command reception in a pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the accessory processing at the time of the demonstration command reception in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of error processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the character processing at the time of a change stop command reception in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the accessory processing at the time of a big hit command reception in the pachinko gaming machine concerning one embodiment of the present invention. It is a flow chart which shows an example of the initial position restoration operation processing in the pachinko gaming machine concerning one embodiment of the present invention. It is a flowchart which shows an example of the serial data output process to the LED driver via SPI performed by the audio / LED control circuit in the pachinko gaming machine according to one embodiment of the present invention. It is a flowchart which shows an example of the serial data output process to the motor driver via the I2C interface performed by the host control circuit in the pachinko gaming machine according to one embodiment of the present invention. 13 is a flowchart illustrating an example of a voice control process according to a first modification. 13 is a flowchart illustrating an example of a lamp control process according to a second modification. 13 is a flowchart illustrating an example of a lamp control process according to a third modification. 15 is a flowchart illustrating an example of a data setting process of each port in Modification Example 3. FIG. 14 is a SPI connection configuration diagram between a voice / LED control circuit and an LED driver in a fourth modification. FIG. 15 is a diagram for describing an input / output operation of serial data between a voice / LED control circuit and an LED driver in a fourth modification. FIG. 15 is a diagram for describing an input / output operation of serial data between a voice / LED control circuit and an LED driver in a fourth modification. 15 is a flowchart illustrating an example of serial data input / output processing executed between an audio / LED control circuit and an LED driver in Modification Example 4. FIG. 15 is a diagram illustrating an example of LED data output control in Modification Example 5. It is a schematic block diagram of the excitation state detection part of the accessory in the modification 6. 15 is a flowchart illustrating an example of an accessory control process according to Modification 6. FIG. 18 is a schematic connection configuration diagram between a sub-board and a CGROM board (NOR type) of a pachinko gaming machine in Modification Example 8. FIG. 19 is a diagram illustrating a first example of generating an LED animation in a pachinko gaming machine according to a ninth modification. FIG. 19 is a diagram illustrating a second example of generating an LED animation in a pachinko gaming machine according to a ninth modification. FIG. 21 is a view illustrating an example of generating an LED animation (an example of using light-off data) in a pachinko gaming machine of Modification Example 9. FIG. 19 is a diagram illustrating a third example of generating an LED animation in a pachinko gaming machine according to a ninth modification. FIG. 19 is a diagram illustrating a fourth example of generating an LED animation in a pachinko gaming machine according to a ninth modification. 15 is a flowchart illustrating an example of an animation request construction process in a pachinko gaming machine of Modification Example 9. 15 is a flowchart illustrating an example of a ramp request generation process in a pachinko gaming machine of Modification Example 9.

  Hereinafter, the configuration and various operations of a pachinko gaming machine (game machine) according to an embodiment of the present invention will be described with reference to the drawings.

<Function flow>
First, with reference to FIG. 1, the function of the pachinko gaming machine according to the present embodiment will be described. FIG. 1 is a diagram showing a functional flow of the pachinko gaming machine according to the present embodiment.

  As shown in FIG. 1, the pachinko game is a game in which a game ball is fired by a user's operation, and a payout control process of the game ball is performed when the game ball wins various kinds. The pachinko game includes a special symbol game using a special symbol and a normal symbol game using a normal symbol. When a "big hit" in a special symbol game or a "hit" in a normal symbol game, the possibility that a game ball wins is relatively increased, and the payout control process of the game ball is easily performed. Become.

  In addition, in various winnings, a special symbol starting prize which is one condition for performing variable display of a special symbol in a special symbol game, and one condition for performing variable display of a normal symbol in a normal symbol game. It also includes certain regular symbol starting prizes.

  Note that the term “variable display” as used herein is a concept that is displayed so as to be changeable, for example, a “variable display” that is actually changed and displayed, and a “stop display” that is actually stopped and displayed. And so on. In the "variable display", for example, "derivation display" in which a special symbol (identification information) is displayed as a result of the 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”. Further, in the present specification, "identification information" refers to "symbols" used in pachinko games, such as special symbols, ordinary symbols, decorative symbols, identification symbols, and identification symbols or decorations used in pachislot or slot games. When the player plays a game, such as a symbol, the meaning may include a symbol used when displaying or suggesting a result of the game, and various symbols in the embodiments and various modifications described below are also included. May be included.

  Hereinafter, the outline of the processing flow of the special symbol game and the ordinary symbol game will be described.

(1) Special symbol game When a special symbol starting prize is won in the special symbol game, random numbers (big hit determination random number and symbol determination random number) are extracted from the jackpot determination counter and the symbol determination counter, respectively. Then, the extracted random numbers are stored (see the flow of the special symbol start winning process in the special symbol game shown in FIG. 1).

  As shown in FIG. 1, in the special symbol control process during the special symbol game, first, it is determined whether or not a condition for starting variable display of the special symbol is satisfied. In this determination processing, it is determined whether or not the condition for starting the variable display of the special symbol is satisfied, with reference to whether or not the random value is stored by the special symbol starting prize, as one condition that the random value is stored. judge.

  Next, when the variable display of the special symbol is started, the big hit determination random number value extracted from the big hit determination counter is referred to, and a big hit determination as to whether or not the big hit is made is performed. Thereafter, a stop symbol determination process is performed. In this process, the special symbol to be stopped and displayed is determined by referring to the symbol determination random number value extracted from the symbol determination counter and the result of the above-described big hit determination.

  Next, a variation pattern determination process is performed. In this process, a random number value is extracted from the fluctuation pattern determination counter, and the random number value, the result of the above-described big hit determination, and the above-described special symbol to be stopped and displayed are referred to, and the variation pattern of the special symbol is determined.

  Next, an effect pattern determination process is performed. In this process, a random number value is extracted from the effect pattern determination counter, and the random number value, the result of the above-described big hit determination, the above-described special symbol to be stopped and displayed, and the above-described special symbol variation pattern are referred to. An effect pattern to be executed according to the variable display of the special symbol is determined.

  Next, as a result of the determined big hit determination, the special symbol to be stopped and displayed, the variation pattern of the special symbol, and the effect pattern accompanying the variable display of the special symbol are referred to, and the variable display control process for controlling the variable display of the special symbol is performed. An effect control process for performing a predetermined effect is performed.

  Then, when the variable display control process and the effect display control process are completed, it is determined whether or not a “big hit” is achieved. In this determination process, if it is determined that a "big hit" has occurred, a big hit game control process for performing a big hit game is executed. In the big hit game, the possibility of the various winnings described above increases. On the other hand, if it is determined that the “big hit” has not been achieved, the big hit game control process is not executed.

  When it is determined that the “big hit” has not been achieved, or when the big hit game control process has been completed, a game state shift control process for shifting the game state is performed. In this game state transition control processing, management of a normal game state different from the big hit game state is performed. As the game state in the normal state, for example, in the above-described big hit determination, a game state in which the probability of being determined as “big hit” increases (hereinafter, referred to as “probable change game state”) or a special symbol start winning is easily obtained. A game state (hereinafter, referred to as a "time reduction game state") is exemplified. Thereafter, a process of determining whether to start the variable display of the special symbol is performed again, and thereafter, the various processes of the above-described special symbol control process are repeated.

  In the pachinko gaming machine of the present embodiment, when a game ball wins and starts during a special symbol fluctuating display, various data acquired at the time of the start winning (a random number for determining a big hit, a random number for determining a symbol, and the like). ) Is suspended. That is, if the game ball wins during the special symbol change display, the special symbol corresponding to the start winning change is suspended (variable display), and after the special symbol change display currently being executed is completed. The variable display of the reserved special symbols is started. Hereinafter, the variable display of the reserved special symbol is also referred to as “reserved ball”.

  Further, in the pachinko gaming machine of the present embodiment, as described later, two types of special symbol starting prizes (first and second starting opening prizes) are provided, and up to four special symbol starting prizes are provided for each special symbol starting prize. You can get a hold ball. That is, in the present embodiment, up to eight reserved balls can be obtained.

  Further, although not shown in FIG. 1, the pachinko gaming machine of the present embodiment determines a hit of a reserved ball (whether or not a “big hit” has been won) based on the above-mentioned information of the reserved ball, and further determines the result of the determination. It also has a function of performing a predetermined effect based on the effect, that is, a look-ahead effect function.

(2) Normal Symbol Game When a normal symbol starting prize is received in the ordinary symbol game, a random value is extracted from the hit determination counter and the random value is stored (the normal symbol in the ordinary symbol game shown in FIG. 1). Refer to the flow of the symbol start winning process).

  As shown in FIG. 1, in the normal symbol control process during the normal symbol game, first, it is determined whether or not a condition for starting variable display of the normal symbol is satisfied. In this determination process, it is referred to whether or not the random number value is stored by the normal symbol start winning, and assuming that the random number value is stored as one condition, the condition for starting the variable display of the normal symbol is satisfied. judge.

  Next, when the variable display of the ordinary symbol is started, the random number value extracted from the hit determination counter is referred to, and a hit determination as to whether or not the hit is made is performed. Thereafter, a variation pattern determination process is performed. In this processing, the result of the hit determination is referred to to determine the variation pattern of the ordinary symbol.

  Next, with reference to the determined result of the hit determination and the variation pattern of the ordinary symbol, a variable display control process for controlling the variable display of the ordinary symbol 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 “hit” is achieved. In this determination process, if it is determined to be "hit", a hit game control process for performing a hit game is executed. In the hit game control processing, the possibility of the various winnings described above, in particular, the possibility of the special symbol starting winning of the game ball in the special symbol game increases. On the other hand, if it is determined that it does not become "hit", the hit game control process is not executed. Thereafter, a process of determining whether to start variable display of the normal symbol is performed again, and thereafter, the various processes of the normal symbol control process described above are repeated.

  As described above, in the pachinko game, the payout control of the game ball is performed according to conditions such as whether or not a “big hit” is obtained in the special symbol game, a transition state of the gaming state, and whether or not a “hit” is generated in the normal symbol game. The easiness of processing changes.

  In the present embodiment, as a method for extracting various random numbers, a soft random number method for generating random numbers by executing a program is used. However, the present invention is not limited to this. For example, when the pachinko gaming machine includes a random number generator in which random numbers are updated at predetermined intervals, a random number value is counted from a counter (so-called ring counter) in the random number generator. May be adopted as the above-described method for extracting various random numbers. When the hard random number method is used, it is possible to prevent the same random number value from being extracted in the predetermined cycle by determining the initial value of the random number value at a timing different from the predetermined cycle.

<Structure of pachinko machine>
Next, the structure of the pachinko gaming machine according to the present embodiment will be described with reference to FIGS. FIG. 2 is a perspective view showing the appearance of the pachinko gaming machine. FIG. 3 is an exploded perspective view of the pachinko gaming machine.

  As shown in FIGS. 2 and 3, the pachinko gaming machine 1 includes a main body 2, a base door 3 attached to the main body 2 so as to be able to open and close, and a glass door attached to the base door 3 so as to be able to open and close. 4 is provided.

[Body]
The main body 2 is formed of a frame-shaped member having a rectangular opening 2a (see FIG. 3). The main body 2 is formed of a material such as wood, for example.

[Base door]
The base door 3 is formed of a plate-like member having a rectangular outer shape substantially equal to the outer shape of the main body 2. The base door 3 is disposed in front of the main body 2 (the front side of the pachinko gaming machine 1), and the base door 3 is rotated about one side edge of the main body 2 as an axis to thereby rotate the main body 2. The opening 2a is opened and closed. As shown in FIG. 3, the base door 3 is provided with a square opening 3a. The opening 3a is formed from a substantially central portion of the base door 3 to a region above the base door 3, and has a size occupying most of the region.

  The base door 3 also includes a speaker 11 (sound generating means), a game board 12, a display device 13 (producing means, display means), a plate unit 14, a firing device 15, a payout device 16, The unit 17 is attached.

  The speaker 11 is disposed above the base door 3 (near the upper end). The game board 12 is arranged in front of the base door 3 (the front side of the pachinko gaming machine 1), and is arranged so as to cover the opening 3a of the base door 3.

  The game board 12 is formed of a plate-shaped resin member having optical transparency. In addition, as a resin having light transmittance, for example, an acrylic resin, a polycarbonate resin, a methacrylic resin, or the like can be used.

  Further, on the front surface of the game board 12 (the front surface of the pachinko gaming machine 1), a game area 12a in which the game ball fired from the firing device 15 rolls is formed. The game area 12a is an area surrounded by a guide rail 41 (specifically, an outer rail 41a shown in FIG. 4 described later), and its outer peripheral shape is substantially circular. Further, a plurality of gaming nails (see FIG. 4 described later) are driven into the gaming area 12a. The configuration of the game board 12 (game area 12a) will be described later in detail with reference to FIG.

  The display device 13 is attached to the back side of the gaming board 12 (the side opposite to the front side of the pachinko gaming machine 1). The display device 13 has a display area 13a for displaying an image. The size of the display area 13a is set so as to occupy all or a part of the surface of the game board 12. In the display area 13a of the display device 13, various images such as an effect identification symbol, an effect image, and a decorative image (decorative symbol) are displayed. The player can visually recognize various images displayed on the display area 13a of the display device 13 via the game board 12.

  In the present embodiment, a liquid crystal display device is used as the display device 13. However, the present invention is not limited to this, 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 13.

  A spacer 19 is provided on the back side of the game board 12 (the side opposite to the front side of the pachinko gaming machine 1). The spacer 19 is provided between the back of the gaming board 12 (the front surface of the pachinko gaming machine 1) and the front of the display device 13 (the front surface of the pachinko gaming machine 1). The space which becomes the flow path of the game ball rolling in the area 12a is formed. The spacer 19 is formed of a material having optical transparency. Note that the present invention is not limited to this, and the spacer 19 may, for example, be partially formed of a material having light transmittance or may be formed of a material having no light transmittance. .

  The dish unit 14 is arranged below the game board 12. The plate unit 14 has an upper plate 21 and a lower plate 22 arranged below the plate 21. As shown in FIG. 2, the upper plate 21 and the lower plate 22 are formed with payout ports 21a and 22a for renting out game balls and paying out game balls (prize balls), respectively. When the predetermined payout condition is satisfied, the game balls are discharged from the payout ports 21a and 22a and stored in the upper plate 21 and the lower plate 22, respectively. The game balls stored in the upper plate 21 are fired by the firing device 15 to the game area 12a.

  Further, the dish unit 14 is provided with an effect button 23. The effect button 23 is mounted on the upper plate 21. A dial operation unit (jog dial) 24 is attached to the periphery of the effect button 23 so as to be rotatable with respect to the effect button 23. The pachinko gaming machine 1 according to the present embodiment has a predetermined effect function performed using the effect button 23 and / or the dial operation unit 24. When a predetermined effect is performed, the display area 13a of the display device 13 includes: An image prompting the operation of the effect button 23 and / or the dial operation unit 24 is displayed.

  The launching device 15 is disposed in the lower right area (near the lower right corner) on the front surface of the base door 3. The firing device 15 includes a firing handle 25 that can be operated by a player, and a panel body 26 that engages with a lower right portion of the dish unit 14. The firing handle 25 is arranged on the front side of the panel body 26 and is rotatably supported by the panel body 26.

  Although not shown in FIGS. 2 and 3, a solenoid actuator (drive device) for controlling the firing operation of the game ball is provided on the back side of the panel body 26. Although not shown in FIGS. 2 and 3, a touch sensor is provided on the periphery of the firing handle 25, and a firing volume is provided inside the firing handle 25. The firing volume changes the resistance value according to the amount of rotation of the firing handle 25, and changes the power supplied to the solenoid actuator.

  In the pachinko gaming machine 1 of the present embodiment, when the player's hand contacts the touch sensor of the firing handle 25, the touch sensor outputs a detection signal. Thereby, it is detected that the player grips the firing handle 25, and the shooting ball can be fired by the solenoid actuator. Then, when the player grips the firing handle 25 and turns in the clockwise direction (clockwise as viewed from the player side), the resistance value of the firing volume changes according to the turning angle of the firing handle 25. The power corresponding to the resistance value is supplied to the solenoid actuator. As a result, the game balls stored in the upper plate 21 are sequentially fired, and the fired game balls are guided to the guide rail 41 (see FIG. 4 described later) and released to the game area 12a of the game board 12.

  Although not shown in FIGS. 2 and 3, a firing stop button is provided on the side of the firing handle 25. The firing stop button is a button provided for stopping the firing of the game ball by the solenoid actuator. When the player presses the firing stop button, the firing of the game ball is stopped even in a state where the firing handle 25 is gripped and rotated.

  The payout device 16 and the substrate unit 17 are arranged on the back side of the base door 3. Game balls are supplied to the payout device 16 from a storage unit (not shown). The payout device 16 pays out a predetermined number of game balls from the game balls supplied from the storage unit to the upper plate 21 or the lower plate 22 based on establishment of a payout condition. The board unit 17 has various control boards. The various control boards are provided with a main control circuit 70 and a sub control circuit 200, which will be described later (see FIG. 5, which will be described later).

[Glass door]
The glass door 4 is formed of a plate-like member having a substantially square surface. The glass door 4 is arranged on the front side of the game board 12 and has a size that covers the game board 12. On the front surface of the glass door 4, a speaker cover 29 is provided in an upper region facing the speaker 11.

  In the central portion of the glass door 4, an opening 4a is formed in a region of the game board 12 facing the game region 12a so as to expose at least the game region 12a. An opening 4a of the glass door 4 is provided with a protective glass 28 having a light transmitting property, thereby closing the opening 4a. Therefore, when the glass door 4 is closed with respect to the base door 3, the protective glass 28 is arranged so as to face at least the game area 12a of the game board 12.

[Game board]
Next, the configuration of the game board 12 will be described with reference to FIG. FIG. 4 is a front view showing the configuration of the game board 12.

  As shown in FIG. 4, a guide rail 41, a ball passage detector 43, a first starting port 44, a second starting port 45 (starting area), and a normal electric accessory 46 are provided on the front surface of the game board 12. Are provided. In addition, on the front of the game board 12, a general winning opening 51, 52, a first big winning opening 53 (variable winning device), a second big winning opening 54 (variable winning device), an out opening 55, a plurality of Game nail 56 is provided. Further, on the front surface of the game board 12, a special symbol display device 61 (special symbol display means, identification information display means) and a normal symbol display device are provided above the display area 13a of the display device 13 arranged substantially at the center thereof. 62, a normal symbol holding display device 63, a first special symbol holding display device 64, and a second special symbol holding display device 65 are provided.

  Although not shown in FIG. 4, a 7-segment counter for effect is also provided on the front surface of the game board 12. The effect 7-segment counter is composed of a display counter capable of displaying two-digit numbers and two alphabetic characters. In the present embodiment, a notification LED (Light Emitting Diode) that lights when the result of the special symbol stop display is “big hit”, a round number display LED that displays the number of rounds during the big hit game, and the like are provided. Is also good.

[Various components in the game area]
The guide rail 41 includes an outer rail 41a extending in an arc shape that defines the game area 12a, and an inner rail 41b extending in an arc shape disposed inside (inner peripheral side) of the outer rail 41a. Is done. The game area 12a is formed inside the outer rail 41a. The outer rail 41a and the inner rail 41b are arranged so as to face each other near the left end of the game area 12a when viewed from the player side, whereby the launching device is provided between the outer rail 41a and the inner rail 41b. A guide path 41c that guides the game ball fired by 15 to the upper part of the game area 12a is formed.

  A ball discharge port 41d is formed at the tip of the inner rail 41b located at the upper left portion of the game area 12a by the tip of the inner rail 41b and a part of the outer rail 41a facing the tip. A ball return preventing piece 42 is provided at the tip of the inner rail 41b so as to close the ball discharge port 41d. The ball return preventing piece 42 prevents the game ball discharged from the ball discharge port 41d into the game area 12a from passing through the ball discharge port 41d again and entering the guide path 41c.

  The game ball discharged from the ball discharge port 41d flows down from the upper part to the lower part of the game area 12a. At this time, the game ball collides with various members provided in the game area 12a, such as the plurality of game nails 56, the first starting port 44, and the second starting port 45, and changes the traveling direction of the game area 12a. It flows down from the top to the bottom.

  A display area 13a of the display device 13 is provided substantially at the center of the game area 12a. An obstacle 13b is provided at the upper end of the display area 13a. By providing the obstacle 13b, the game ball does not pass over an area overlapping the display area 13a in the game area 12a.

  The ball passage detector 43 is arranged near the right end of the display area 13a when viewed from the player side. The ball passing detector 43 is provided with a passing ball sensor 43a (see FIG. 5 described later) for detecting a game ball passing through the ball passing detector 43. In addition, when the game ball passes through the ball passage detector 43, a lottery is performed to determine whether or not a “hit” has occurred, and a variation display of the normal symbol is started based on the result of the lottery.

  The first starting port 44 is disposed below the display area 13a, and the second starting port 45 is disposed below the first starting port 44. The first starting port 44 and the second starting port 45 are formed of members capable of receiving game balls. Hereinafter, entering or passing a game ball into the first starting port 44 or the second starting port 45 is referred to as “winning”. Then, when the game balls win the first starting port 44 or the second starting port 45, a first predetermined number (three in the present embodiment) of game balls are paid out. In addition, when a game ball enters the first starting port 44, a lottery is performed to determine whether the hit is a "big hit" or a "small hit", and the special symbol changes based on the result of the lottery. Display starts. Furthermore, when a game ball enters the second starting port 45, a lottery is performed to determine whether or not a "big hit" has occurred, and a variable display of a special symbol is started based on the result of the lottery.

  The first starting port 44 is provided with a first starting port winning ball sensor 44a (see FIG. 5 described later) for detecting a game ball that has won the first starting port 44. The second starting port 45 is provided with a second starting port winning ball sensor 45a (see FIG. 5 described later) for detecting a game ball that has won the second starting port 45. The game balls that have won the first starting port 44 and the second starting port 45 pass through a collecting port (not shown) provided on the game board 12 and are conveyed to a collecting section (not shown) for game balls. .

  The normal electric accessory 46 is provided at the second starting port 45. The ordinary electric accessory 46 includes a pair of blade members rotatably attached to both sides of the second starting port 45 and an ordinary electric accessory solenoid 46a (see FIG. 5 described later) for driving the pair of blade members. Have. The ordinary electric accessory 46 is driven by an ordinary electric accessory solenoid 46a, and is in an open state in which the pair of blade members are expanded to make it easier for a game ball to enter the second starting port 45, and the pair of blade members are closed. One state of the closed state where the game ball cannot be won is generated in the second starting port 45. In the present embodiment, when the ordinary electric accessory 46 is in the closed state, the opening of the pair of blade members is not formed in a form that makes it impossible to win, but in a form that makes it difficult to win a game ball. Is also good.

  The general winning opening 51 is disposed near the lower left of the game area 12a when viewed from the player side. Further, the general winning opening 52 is arranged below the ball passage detector 43, and is arranged near the lower right of the game area 12a when viewed from the player side. The general winning opening 51 and the general winning opening 52 are formed of members capable of receiving game balls. Hereinafter, the entry or passage of a game ball into the general winning opening 51 or the general winning opening 52 is also referred to as “winning”. When a game ball wins in the general winning opening 51 or the general winning opening 52, a second predetermined number (10 in the present embodiment) of game balls are paid out.

  The general winning opening 51 is provided with a general winning ball sensor 51a (see FIG. 5 described later) for detecting a game ball having won the general winning opening 51. The general winning opening 52 is provided with a general winning ball sensor 52a (see FIG. 5 described later) for detecting a game ball that has won the general winning opening 52.

  The first special winning opening 53 and the second special winning opening 54 are arranged below the ball passing detector 43 and between the first starting opening 44 and the general winning opening 52. The first special winning opening 53 and the second special winning opening 54 are arranged vertically along the flow path of the game ball, and the first special winning opening 53 is arranged above the second special winning opening 54. You. Each of the first big winning opening 53 and the second big winning opening 54 is a so-called attacker type opening / closing device, and is capable of opening and closing shutters 53a and 54a and a solenoid actuator for driving the shutter (a first actuator in FIG. The special winning opening solenoid 53b and the second special winning opening solenoid 54b) are provided.

  Each of the first special winning opening 53 and the second special winning opening 54 receives a game ball when the corresponding shutter is open (open state) and plays a game when the shutter is closed (closed state). Do not accept the ball. Hereinafter, the entry or passage of a game ball into or from the first special winning opening 53 or the second special winning opening 54 is also referred to as “winning”. When a game ball wins in the first big winning opening 53, a third predetermined number of balls (ten in this embodiment) are paid out. On the other hand, when a game ball wins in the second special winning opening 54, a fourth predetermined number of balls (five in this embodiment) are paid out.

  Further, the first large winning opening 53 is provided with a count sensor 53c (see FIG. 5 described later) for counting the game balls that have won the first large winning opening 53. Further, the second large winning opening 54 is provided with a count sensor 54c (see FIG. 5 described later) for counting game balls that have won the second large winning opening 54.

  The out port 55 is provided at the lowermost part of the game area 12a. The out port 55 does not win any of the first starting port 44, the second starting port 45, the general winning opening 51, the general winning opening 52, the first big winning opening 53, and the second big winning opening 54. Accept the ball.

  If the arrangement of various components in the game area 12a of the present embodiment is arranged as shown in FIG. 4, when a player hits a game ball into the right area of the game area 12a (when hit right), A game ball is guided to the second starting port 45 by the game nail 56 or the like. In this case, there is almost no possibility of winning the first starting port 44. In the present embodiment, as will be described later, a player who wins the second starting port 45 is more likely to receive a "big hit" lottery which is advantageous to the player than a player who wins the first starting port 44. Therefore, in the below-mentioned "time-saving gaming state" in which it is relatively easy to win a prize in the second starting port 45, by right-handing, the possibility of winning in the first starting port 44 (which is disadvantageous for the player) Game state).

[Special design display]
As shown in FIG. 4, the special symbol display device 61 is disposed substantially at the center of the upper part of the display area 13a of the display device 13.

  The special symbol display device 61 is a display device that variably displays (variable display and stop display) a special symbol in a special symbol game. In the present embodiment, as shown in FIG. 4, the special symbol display device 61 is configured by a device that displays a special symbol with a symbol or a symbol. Note that the present invention is not limited to this, and the special symbol display device 61 may be configured by, for example, a plurality of LEDs. In this case, a display pattern formed by turning on / off a plurality of LEDs is represented as a special symbol.

  The special symbol display device 61 changes the display of the special symbol (identification information) when the game ball has won the first starting port 44 or the second starting port 45 (special symbol starting prize). Then, the special symbol display device 61 performs a special symbol change display for a predetermined time, and then performs a special symbol stop display. In the following, a special symbol that is variably displayed on the special symbol display device 61 when a game ball has won the first starting port 44 is referred to as a first special symbol. In addition, a special symbol that is variably displayed on the special symbol display device 61 when the game ball has won the second starting port 45 is referred to as a second special symbol.

  In the special symbol display device 61, when the first special symbol or the second special symbol stopped and displayed is in a specific mode ("big hit" mode), the gaming state is changed from the normal gaming state to an advantageous state for the player. The state shifts to the jackpot game state. That is, in the special symbol display device 61, the state where the first special symbol or the second special symbol is stopped and displayed in a state of shifting to the big hit game state is "big hit".

  In the big hit game state, the first big winning opening 53 or the second big winning opening 54 is opened. Specifically, in the present embodiment, when a game ball wins in the first starting port 44 and the first special symbol is stopped and displayed in a specific manner on the special symbol display device 61, the first special winning slot is provided. 53 is opened. On the other hand, when the game ball wins in the second starting port 45 and the second special symbol is stopped and displayed in the special symbol display device 61 in a specific mode, the second large winning port 54 is opened.

  The open state of each big winning opening is maintained until a predetermined number of game balls are won or until a certain period (for example, 30 seconds) elapses. Then, when the elapsed time of the open state of each special winning opening satisfies any of these conditions, the large winning opening that has been open is closed.

  Hereinafter, a game in which the first special winning opening 53 or the second special winning opening 54 is in a state (open state) in which game balls can be easily received is referred to as a round game. During the round game, the special winning opening is closed. The round game is counted as the number of rounds such as one round and two rounds. For example, the first round game is referred to as a first round, and the second round game is referred to as a second round.

  In the special symbol display device 61, when the special symbol stopped and displayed is in a mode other than the specific mode (a mode of "losing"), the game state does not shift except when the player has won the falling lottery. That is, the special symbol game is a game in which the special symbol is variably displayed by the special symbol display device 61, and then the special symbol is stopped and displayed, and the game state is shifted or maintained according to the result.

  Also, in the pachinko gaming machine 1 of the present embodiment, when a game ball wins in the first starting port 44 during the change display of the first special symbol or the second special symbol, the first special symbol corresponding to the winning is changed. The display (holding ball) is held. Then, when the first special symbol or the second special symbol which is currently being displayed in a variable manner is stopped and displayed, the variable display of the held first special symbol is started. In the present embodiment, the number of variable displays of the first special symbol to be retained (so-called “reserved number (the number of retained balls)”) is defined as a maximum of four times.

  Further, in the present embodiment, when a game ball wins in the second starting port 45 during the changing display of the first special symbol or the second special symbol, the variable display of the second special symbol corresponding to the winning (reserved ball). Is suspended. Then, when the first special symbol or the second special symbol that is currently being displayed in a variable manner is stopped and displayed, the variable display of the held second special symbol is started. In the present embodiment, the number of variable displays of the second special symbol to be held (the number of holdings) is defined as a maximum of four times (number). Therefore, in this embodiment, the total number of variable display of special symbols held is a maximum of eight in total.

  Further, in the present embodiment, when the reserved ball of the first special symbol and the reserved ball of the second special symbol are mixed, the variable display of one special symbol is preferentially executed over the variable display of the other special symbol. . Note that 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 special symbol may be changed and displayed in the order in which the reserved balls are retained.

[Normal symbol display device]
As shown in FIG. 4, the normal symbol display device 62 is disposed substantially at the center of the upper part of the display area 13 a of the display device 13. And in this embodiment, the normal symbol display device 62 is arranged on the right side of the special symbol display device 61 when viewed from the player side.

  The normal symbol display device 62 is a display device that variably displays (variable display and stop display) the normal symbols in the normal symbol game. In the present embodiment, as shown in FIG. 4, the ordinary symbol display device 62 is configured by two LEDs (ordinary symbol display LEDs) arranged in the vertical direction. In the ordinary symbol display device 62, a display pattern formed by turning on / off each ordinary symbol display LED is represented as an ordinary symbol.

  The ordinary symbol display device 62 alternately turns on and off the two ordinary symbol display LEDs when the game ball passes through the ball passage detector 43, and performs a variable display of the ordinary symbol. Then, the normal symbol display device 62 performs a change display of the normal symbol for a predetermined time, and then performs a stop display of the ordinary symbol.

  In the normal symbol display device 62, when the stopped and displayed normal symbol is in a predetermined mode ("hit" mode), the normal electric accessory 46 is changed from the closed state to the open state for a predetermined period. On the other hand, when the stop-displayed normal symbol is in a mode other than the predetermined mode (a mode of “losing”), the normal electric accessory 46 maintains the closed state. That is, the ordinary symbol game is a game in which the ordinary symbol is fluctuated and displayed by the ordinary symbol display device 62, and thereafter the ordinary symbol is stopped and displayed, and the ordinary electric accessory 46 operates according to the result.

  When the game ball passes the ball passage detector 43 during the variable display of the normal symbol, the variable display of the normal symbol is suspended. Then, when the ordinary symbol currently being displayed in a variable manner is stopped and displayed, the variable display of the suspended ordinary symbol is started. In the present embodiment, the number of variable displays of the ordinary symbols to be retained (that is, the “reserved number”) is defined as a maximum of four times.

[Normal symbol hold display]
As shown in FIG. 4, the normal symbol hold display device 63 is disposed substantially at the center of the upper part of the display area 13 a of the display device 13. In the present embodiment, the ordinary symbol holding display device 63 is disposed below the special symbol display device 61 and the ordinary symbol display device 62.

  The ordinary symbol hold display device 63 is a device for displaying the number of held ordinary symbols in variable display. In the present embodiment, as shown in FIG. 4, the normal symbol hold display device 63 is configured by four LEDs (normal symbol hold display LEDs) arranged in the left-right direction. Then, in the ordinary symbol hold display device 63, the number of ordinary symbols held for variable display is displayed by turning on / off each ordinary symbol hold display LED.

  Specifically, when the number of variable display of the normal symbols is one, the normal symbol hold display LED located at the leftmost side when viewed from the player side (the first normal symbol hold display LED from the left). Lights up, and the other ordinary symbol hold display LEDs go out. In the case where the number of variable display of the normal symbols is two, the first and second normal symbol holding display LEDs from the left are turned on, and the other normal symbol holding display LEDs are turned off. When the number of variable display of ordinary symbols is three, the first to third ordinary symbol holding display LEDs from the left are turned on, and the other ordinary symbol holding display LEDs are turned off. Then, when the number of variable display of the normal symbols is four, all the normal symbol holding display LEDs are turned on.

[1st special symbol hold display device]
As shown in FIG. 4, the first special symbol holding display device 64 is disposed above the display area 13a of the display device 13 on the left side of the special symbol display device 61 when viewed from the player side.

  The first special symbol holding display device 64 is a device that displays information relating to the variable display of the held first special symbol (the holding ball of the first special symbol). In the present embodiment, as shown in FIG. 4, the first special symbol holding display device 64 includes a first special symbol holding number display section 64a and a first special symbol holding information display section 64b. The first special symbol hold information display section 64b is arranged on the left side of the special symbol display device 61, and the first special symbol hold quantity display section 64a is arranged on the left side of the first special symbol hold information display section 64b. .

  The first special symbol reservation number display section 64a has four LEDs (first special symbol reservation display LEDs) arranged in the left-right direction. In addition, the display mode of the first special symbol hold number display section 64a is the same as the display mode of the normal symbol hold display device 63. In other words, when the variable display of the first special symbol is suspended, the first special symbol suspension display LEDs from the first leftmost special symbol suspension display LED to the number of retained positions as viewed from the player side. Lights up.

  Further, the first special symbol holding information display section 64b displays information on the holding ball of the first special symbol. For example, the first special symbol holding information display section 64b displays information (identification information) on the holding ball of the first special symbol to be displayed next in a variable manner with a symbol or the like. The configuration of the first special symbol hold display device 64 is not limited to the example shown in FIG. 4, and may be arbitrarily configured as long as it can display at least the number of variable display holds of the first special symbol. .

[Second special symbol hold display]
As shown in FIG. 4, the second special symbol holding display device 65 is disposed above the display area 13a of the display device 13 on the right side of the normal symbol display device 62 when viewed from the player side.

  The second special symbol holding display device 65 is a device that displays information relating to the variable display of the held second special symbol (holding ball of the second special symbol). In the present embodiment, as shown in FIG. 4, the second special symbol reservation display device 65 includes a second special symbol reservation number display section 65a and a second special symbol reservation information display section 65b. The second special symbol hold information display section 65b is arranged on the right side of the ordinary symbol display device 62, and the second special symbol hold number display section 65a is arranged on the right side of the second special symbol hold information display section 65b. .

  The second special symbol reserved number display section 65a has four LEDs (second special symbol reserved display LEDs) arranged in the left-right direction. The display mode of the second special symbol reserved number display section 65a is the same as the display mode of the normal symbol reserved display device 63. That is, when the variable display of the second special symbol is suspended, the second special symbol suspension display LED from the second leftmost special symbol suspension display LED located at the leftmost position when viewed from the player side to the number of retained second special symbols is displayed. Lights up.

  Further, the second special symbol holding information display section 65b displays information on the holding ball of the second special symbol. For example, the second special symbol holding information display section 65b displays information (identification information) on the holding ball of the second special symbol which is to be displayed next in a fluctuating manner with a symbol or the like. The configuration of the second special symbol hold display device 65 is not limited to the example shown in FIG. 4, and can be arbitrarily configured as long as it can display at least the variable display number of the second special symbols. .

[Display device]
The display device 13 is configured by the liquid crystal display device as described above, and performs various image display effects in the display area 13a.

  Specifically, in the present embodiment, an effect image related to the special symbol displayed on the special symbol display device 61 is displayed in the display area 13a. At this time, for example, when the special symbol is being fluctuated and displayed on the special symbol display device 61, a plurality of effect identification symbols (decorations) including, for example, numbers 1 to 8 and various characters, except for a specific case. (Design) is variably displayed in the display area 13a. When the special symbol is stopped and displayed on the special symbol display device 61, a plurality of decorative symbols (big hit symbols and the like to be described later) corresponding to the special symbol are also stopped and displayed in the display area 13a.

  Then, when the special symbol stopped and displayed on the special symbol display device 61 is in a specific mode (the result of the stop display is "big hit"), the special symbol is displayed to the player to recognize that it is "big hit". The effect image is displayed in the display area 13a. As an effect for causing the player to recognize that it is a “big hit”, for example, first, a plurality of stopped and displayed decorative symbols are arranged in a specific mode (for example, a mode in which the same decorative symbols are arranged in a predetermined direction). ), And then an effect of displaying an image for notifying “big hit” is given.

  In the present embodiment, an effect image related to the display contents of the first special symbol reservation display device 64 and the second special symbol reservation display device 65 is displayed in the display area 13a of the display device 13. For example, in the display area 13a, hold information (for example, the same number of holding symbols as the number of holding symbols) for notifying the holding number of variable display of special symbols is displayed. Further, for example, in the pachinko gaming machine 1 of the present embodiment, a pre-reading effect is performed based on the information of the special designating reserved ball, and a notice at this time is also displayed in the display area 13a.

  In the present embodiment, when the ordinary symbol stopped and displayed on the ordinary symbol display device 62 is in a predetermined mode, an effect image for allowing the player to grasp the information is displayed on the display area 13a of the display device 13. A function may be further provided.

<Circuit structure of pachinko machine>
Next, the configuration of various circuits included in the pachinko gaming machine 1 of the present embodiment will be described with reference to FIG. FIG. 5 is a block diagram showing a circuit configuration of the pachinko gaming machine 1.

  As shown in FIG. 5, the pachinko gaming machine 1 has a main control circuit 70 (main control means, game control means) for mainly controlling a game operation, a payout / firing control circuit 123, and It has a sub-control circuit 200 (sub-control means, effect control means) for controlling the effect operation. Although not shown in FIG. 5, the pachinko gaming machine 1 is provided with a power supply device for supplying a power supply voltage (DC voltage) of +12 V to each unit.

[Main control circuit]
The main control circuit 70 includes a one-chip microcomputer 77, a clock generation circuit 74, and an initial reset circuit 75. In addition, as described above, in the present embodiment, the lottery process of the special symbol is performed at the time of winning the first starting port 44 or the second starting port 45, but this process is controlled by the main control circuit 70. That is, the main control circuit 70 also functions as a means (lottery means) for performing a lottery process for determining whether or not to shift the gaming state to a state advantageous to the player.

  The one-chip microcomputer 77 includes a main CPU (Central Processing Unit) 71, a main ROM (Read Only Memory) 72, a main RAM (Random Access Memory) 73, and a serial communication unit 76. Note that the main CPU 71, the main ROM 72, the main RAM 73, and the serial communication unit 76 may be separately provided.

  Further, in the present embodiment, a configuration in which the main ROM 72 is built in the substrate of the main control circuit 70 will be described, but the present invention is not limited to this. For example, a ROM board on which the main ROM 72 is mounted may be connected to the board of the main control circuit 70. Further, in the present embodiment, various circuits (various means) in the main control circuit 70 may be formed integrally or may be formed separately. Further, the main ROM 72 may not be configured to be installed in the gaming machine, and may be configured to be able to communicate with the gaming machine.

  The clock generation circuit 74 and the initial reset circuit 75 are connected to the one-chip microcomputer 77. The main ROM 72 stores various programs (see FIGS. 69 to 78 described later) for controlling the operation of the pachinko gaming machine 1 by the main CPU 71, various data tables (see FIGS. 16 to 25 described later), and the like. ing.

  The main CPU 71 executes various processes according to a program stored in the main ROM 72. The main RAM 73 functions as a temporary storage area when the main CPU 71 executes various processes, and stores various flags and variable values required for the main CPU 71 for various processes. In the present embodiment, the main RAM 73 is used as a temporary storage area of the main CPU 71. However, the present invention is not limited to this, and any storage medium that can be read and written can be used as the temporary storage area. .

  The clock generation circuit 74 generates a clock pulse at a predetermined cycle (for example, 2 msec) in order to execute a system timer interrupt process described later. The initial reset circuit 75 generates a reset signal when power is turned on. Then, the serial communication unit 76 supplies a command to the sub control circuit 200.

  Further, as shown in FIG. 5, various devices that operate according to the output signal sent from the main control circuit 70 are connected to the main control circuit 70.

  Specifically, the main control circuit 70 is connected to a special symbol display device 61, a normal symbol display device 62, a normal symbol hold display device 63, a first special symbol hold display device 64, and a second special symbol hold display device 65. Is done. Each of these devices performs a predetermined operation based on an output signal sent from the main control circuit 70. For example, when a predetermined output signal is transmitted from the main control circuit 70 to the special symbol display device 61, the special symbol display device 61 controls the operation of variably displaying the special symbol in the special symbol game based on the output signal. Do.

  Further, the main control circuit 70 is connected with a normal electric accessory solenoid 46a, a first winning port solenoid 53b, and a second winning port solenoid 54b. Then, the main control circuit 70 controls the drive of the ordinary electric accessory solenoid 46a to bring the pair of blade members of the ordinary electric accessory 46 into an open state or a closed state. Further, the main control circuit 70 drives and controls the first special winning opening solenoid 53b and the second special winning opening solenoid 54b, respectively, so that the first special winning opening 53 and the second special winning opening 54 are opened or closed. I do.

  Further, as shown in FIG. 5, the main control circuit 70 is connected to various sensors and receives output signals from the various sensors. Specifically, the main control circuit 70 includes count sensors 53c and 54c, general winning ball sensors 51a and 52a, a passing ball sensor 43a, a first starting opening winning ball sensor 44a, a second starting opening winning ball sensor 45a, and a backup. The clear switch 121 and the like are connected.

  The count sensor 53c counts the game balls that have won the first special winning opening 53, and outputs a predetermined output signal indicating the result to the main control circuit 70. The count sensor 54c counts the game balls that have won the second special winning opening 54, and outputs a predetermined output signal indicating the result to the main control circuit 70. The general winning ball sensor 51a outputs a predetermined detection signal to the main control circuit 70 when a game ball wins in the general winning opening 51, and the general winning ball sensor 52a receives a game ball in the general winning opening 52. In this case, a predetermined detection signal is output to the main control circuit 70.

  The passing ball sensor 43a outputs a predetermined detection signal to the main control circuit 70 when the game ball passes the ball passing detector 43. The first starting port winning ball sensor 44a outputs a predetermined detection signal to the main control circuit 70 when a game ball has won the first starting port 44. The second starting port winning ball sensor 45a outputs a predetermined detection signal to the main control circuit 70 when a game ball has won the second starting port 45. The backup clear switch 121 sends a predetermined detection signal to the main control circuit 70 and the payout / launch control circuit 123 when the backup data is cleared in response to an operation of a game store manager or the like at the time of a power failure or the like. Output.

  Further, a payout / firing control circuit 123 is connected to the main control circuit 70. The contents of the payout / firing control circuit 123 and various peripheral devices connected thereto will be described later in detail.

[Payout / Launch Control Circuit and Peripheral Devices]
The payout / firing control circuit 123 is connected to the prize ball case unit 170, the payout state notification display device 178, the lower plate full switch 179, the firing device 15, the external terminal plate 140, and the card unit 150. Further, the external terminal board 140 is connected to the data display 141, and the card unit 150 is connected to the lending operation unit 151.

  The payout / firing control circuit 123 inputs and outputs signals and the like to these peripheral devices based on various commands and the like transmitted from the main control circuit 70, and controls the operation of each peripheral device. For example, the payout / firing control circuit 123 receives a prize ball control command transmitted from the main control circuit 70 and a later-described lending ball control signal transmitted from the card unit 150, and sends a predetermined sphere control signal to the prize ball case unit 170. Send a signal. Thereby, the prize ball case unit 170 pays out game balls.

  The winning ball case unit 170 is a device for paying out game balls, and includes a first 15-ball security switch 172a, a second 15-ball security switch 172b, a first counting switch 181a, a second counting switch 181b, and a payout. It has a motor 174. These components included in the prize ball case unit 170 are connected to the payout / firing control circuit 123, respectively.

  Although not shown here, two ball supply passages are provided inside the prize ball case unit 170. Then, the first 15-ball security switch 172a detects the game ball supplied to one of the ball supply passages, and outputs a predetermined output signal indicating the detection result to the payout / firing control circuit 123. The second 15-ball security switch 172b detects a game ball supplied to the other ball supply passage, and outputs a predetermined output signal indicating the detection result to the payout / firing control circuit 123.

  Further, although not shown here, two payout passages are provided inside the prize ball case unit 170. Then, the first counting switch 181a detects a game ball paid out to one payout path, and outputs a predetermined output signal indicating the detection result to the payout / firing control circuit 123. Further, the second counting switch 181b detects a game ball paid out to the other payout passage, and outputs a predetermined output signal indicating the detection result to the payout / firing control circuit 123.

  The payout motor 174 is configured by a stepping motor, and is driven according to a control signal input from the payout / firing control circuit 123. The payout motor 174 rotationally drives a sprocket (rotating member) (not shown) provided in the award ball case unit 170. Then, by the rotation of the sprocket, the game balls accumulated in each ball supply path move to the corresponding payout path one by one.

  The payout state notification display device 178 is a device for notifying the type of the abnormality when an abnormality has occurred with respect to the payout of the game balls, and is configured by a 7-segment display. The payout state notification display device 178 is mounted at a position where only the manager of the game store (game room) can visually recognize the payout state notification display device 178.

  The lower plate full switch 179 detects when the game balls stored in the lower plate 22 are full, and outputs this to the payout / firing control circuit 123.

  When a signal indicating that the lower plate is full is input from the lower plate full switch 179, the dispensing / firing control circuit 123 sets the dispensing state notification display device 178 to indicate that the lower plate is full. And outputs a signal to the main control circuit 70 indicating that the lower tray is full. After that, when an effect control command is transmitted from the main control circuit 70 to the sub-control circuit 200, the sub-control circuit 200 uses the speaker 11, the lamp group 18, the display device 13 and the like, and the lower plate 22 is in a full state. Notify that there is.

  The firing device 15 has a firing handle 25 that can be rotated by a player when shooting a game ball stored in the upper plate 21 to the game area 12a. When the firing handle 25 is gripped by the player and rotated clockwise, the payout / firing control circuit 123 controls the solenoid actuator (not shown) of the firing device 15 according to the rotation angle. Supply power. Thereby, the launching device 15 launches the game ball. Note that a motor may be used as a driving unit of the firing device 15 instead of the solenoid actuator.

  The external terminal board 140 is used to transmit data to a hall computer that manages all pachinko gaming machines in the game store. The data display 141 is installed, for example, as an accessory to a game arcade above the pachinko gaming machine 1 and has a function of calling a hall clerk and a function of displaying the number of hits.

  When operated by the player, the lending operation section 151 outputs a signal requesting lending of a game ball to the card unit 150. The card unit 150 determines the number of game balls (the number of balls to be loaned) to be paid out via the prize ball case unit 170 based on a signal for requesting the lending of the game balls output from the lending operation unit 151. When the card unit 150 receives a signal requesting lending of game balls from the lending operation unit 151, the card unit 150 transmits a lending ball control signal including information on the determined number of lending balls to the payout / launch control circuit 123.

[Sub-control circuit]
The sub control circuit 200 is connected to the serial communication unit 76 of the main control circuit 70. Then, the sub-control circuit 200 (host control circuit 210 described later) controls the entire sub-control circuit 200 according to various commands (information relating to the progress of the game) transmitted from the main control circuit 70. Then, the sub-control circuit 200 controls the sound reproduction operation by the speaker 11, controls the image display operation by the display device 13, and controls the lamp group 18 including LEDs based on various commands transmitted from the main control circuit 70. The control of the lamp lighting / extinguishing operation by the means), the control of the effect operation by the accessory 20 (decorative member), and the like are performed. That is, the sub-control circuit 200 controls various effect devices based on a command from the main control circuit 70, and executes various effects according to the progress of the game. In the present embodiment, a signal cannot be supplied from the sub-control circuit 200 to the main control circuit 70. However, the present invention is not limited to this, and a signal can be transmitted from the sub-control circuit 200 to the main control circuit 70. May be provided.

  Next, the internal configuration of the sub-control circuit 200 will be described in more detail with reference to FIG. FIG. 6 is a block diagram showing a circuit configuration inside the sub-control circuit 200 and a connection relationship between the sub-control circuit 200 and various peripheral devices thereof.

  As shown in FIG. 6, the sub control circuit 200 includes a relay board 201, a sub board 202 (first board), a control ROM board 203, and a CGROM (Character Generator ROM) board 204 (second board). . The sub board 202 is connected to the relay board 201, the control ROM board 203, and the CGROM board 204. In the sub control circuit 200, the sub board 202 and various ROM boards (the control ROM board 203 and the CGROM board 204) are connected via a board-to-board connector (not shown).

  The relay board 201 is a relay board for receiving a command transmitted from the main control circuit 70 and transmitting the received command to the sub-board 202.

  The sub-board 202 includes a host control circuit 210 (host control means, effect control means), an audio / LED control circuit 220 (light emission control means, audio control means, effect control means), a display control circuit 230 (effect control means), An SDRAM (Synchronous Dynamic RAM) 250 and a built-in relay board 260 are provided.

  The host control circuit 210 is a circuit that controls the entire operation of the sub control circuit 200 based on various commands transmitted from the main control circuit 70, and is configured by a CPU processor. The host control circuit 210 is connected to the audio / LED control circuit 220, the display control circuit 230, and the built-in relay board 260 in the sub-board 202. Further, the host control circuit 210 is connected to the control ROM board 203.

  The host control circuit 210 has a subwork RAM 210a and an SRAM (Static RAM) 210b. The subwork RAM 210a is a storage device that acts as a temporary storage area for work when the host control circuit 210 executes various processes, and various flags and variables required when the host control circuit 210 executes various processes. Is stored. The SRAM 210b is a storage device for backing up predetermined data in the sub work RAM 210a. In the present embodiment, a RAM is used as a temporary storage area of the host control circuit 210. However, the present invention is not limited to this, and any storage medium that is readable and writable may be used as the temporary storage area. .

  The audio / LED control circuit 220 is connected to the speaker 11 and the lamp group 18 via the built-in relay board 260, and based on a control signal (sound request and lamp request described later) input from the host control circuit 210, Is a circuit for controlling the sound reproduction operation by the controller and the light emission operation by the lamp group 18. Therefore, functionally, the audio / LED control circuit 220 has an audio controller 220a and a lamp controller 220b. The sound controller 220a and the lamp controller 220b are substantially included in a sound lamp control module 226 described later. The internal configuration of the audio / LED control circuit 220 will be described later in detail with reference to the drawings.

  In this embodiment, when a control signal and data (for example, LED data described later) output from the audio / LED control circuit 220 are transmitted to the lamp group 18 via the built-in relay board 260, the audio / LED Communication between the control circuit 220 and the lamp group 18 is performed by a SPI (Serial Periperal Interface) communication method (a type of serial communication method). In the present embodiment, the lamp group 18 includes one or more LEDs and one or more LED drivers for controlling each LED (see FIGS. 43 to 45 described later).

  The display control circuit 230 is connected to the display device 13 and displays an image (decorative design image, background image, effect image, etc.) related to the effect based on a control signal (drawing request) input from the host control circuit 210. Is a circuit for controlling various processing operations at the time of displaying the image. The display control circuit 230 includes a display controller (a first display controller 238 and a second display controller 239, which will be described later), and a built-in VRAM (Video RAM) 237 (a fourth information storage unit and a third storage unit).

  Further, the display control circuit 230 is connected to the SDRAM 250 in the sub-substrate 202. Further, the display control circuit 230 is connected to the CGROM board 204. Further, the display controller in the display control circuit 230 is directly connected to the display device 13 without going through the relay board. The internal configuration of the display control circuit 230 will be described later in detail with reference to the drawings.

  The SDRAM 250 (third information storage means, second storage means) is constituted by a DDR2 (Double-Date Rate 2) SDRAM. Further, the SDRAM 250 is provided with various buffers for temporarily storing various image data in a drawing process of images (moving images and still images) displayed by the display device 13. Specifically, for example, as shown in FIGS. 97 to 99 described later, the SDRAM 250 includes a texture buffer, a movie buffer, a blend buffer, two frame buffers (a first frame buffer and a second frame buffer), and a motion buffer. Are provided.

  The built-in relay board 260 receives various signals and various data output from the host control circuit 210 and the audio / LED control circuit 220, and transmits the received various signals and various data to the speaker 11, the lamp group 18, and the accessory 20. This is a relay board for transmitting.

  The built-in relay board 260 includes an I2C (Inter-Integrated Circuit) controller 261, a digital audio power amplifier 262 (audio amplifying unit), and a voltage conversion circuit unit 269.

  In the present embodiment, an example is shown in which the I2C controller 261, the digital audio power amplifier 262, and the voltage conversion circuit unit 269 are mounted on the same relay board. However, the present invention is not limited to this. A board, a relay board on which the digital audio power amplifier 262 is mounted, and a relay board on which the voltage conversion circuit unit 269 is mounted may be separately provided. Further, in the present embodiment, the example in which the relay board on which the I2C controller 261, the digital audio power amplifier 262, and the voltage conversion circuit unit 269 are mounted is provided in the sub-board 202, but the present invention is not limited to this. A relay board on which the I2C controller 261, the digital audio power amplifier 262, and the voltage conversion circuit section 269 are mounted may be provided separately from the sub-board 202, and the two boards may be electrically connected by wiring or the like.

  The I2C controller 261 is connected to the host control circuit 210 and the motor controller 270 of the accessory 20. That is, the host control circuit 210 is connected to the accessory 20 via the I2C controller 261 and the motor controller 270. Then, a control signal and data (for example, excitation data described later) output from the host control circuit 210 are input to the accessory 20 via the I2C controller 261 and the motor controller 270.

  In the present embodiment, communication between the I2C controller 261 and the motor controller 270 is performed by an I2C communication method (a type of serial communication method). In the present embodiment, the accessory 20 includes one or more motors, and the motor controller 270 includes one or more motor drivers for driving the respective motors (see FIG. 67 and FIG. 68). Although FIG. 6 shows an example in which only one accessory 20 is provided, the present invention is not limited to this, and a plurality of accessories 20 may be provided.

  Further, in the configuration of the present embodiment, the host control circuit 210 may directly drive the motor of the accessory 20 without using the motor controller 270, or a control circuit for motor control may be separately provided. Good. Further, in the present embodiment, a configuration in which a single control circuit controls a plurality of motor drivers (motors) will be described (see FIGS. 67 and 68 described later), but the present invention is not limited to this. In the present 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. One motor (motor driver) may be controlled, or one control circuit may control one motor (motor driver).

  The digital audio power amplifier 262 is connected to the audio / LED control circuit 220 and the speaker 11. That is, the audio / LED control circuit 220 is connected to the speaker 11 via the digital audio power amplifier 262. Therefore, the audio signal and the like output from the audio / LED control circuit 220 are input to the speaker 11 via the digital audio power amplifier 262.

  Although not shown, the voltage conversion circuit unit 269 is connected to a power supply device (not shown) that outputs a power supply voltage of +12 V, the speaker 11, the lamp group 18, and the motor controller 270 (the accessory 20). The voltage conversion circuit unit 269 is a circuit unit (DC / DC conversion circuit unit) that converts an input DC voltage into a lower DC voltage and outputs the converted DC voltage. In this embodiment, the voltage conversion circuit unit 269 converts a +12 V power supply voltage (DC voltage) input from a power supply device (not shown) into a +5 V drive voltage (DC voltage). Then, the voltage conversion circuit unit 269 supplies the converted drive voltage of +5 V to the speaker 11, the lamp group 18, and the motor controller 270 (the accessory 20). The internal configuration of the voltage conversion circuit unit 269 will be described later in detail with reference to the drawings.

  A sub main ROM 205 is provided on the control ROM board 203. In the sub main ROM 205, various programs (see FIGS. 79, 81 to 84, 86 to 110 described later) for controlling the staging operation of the pachinko gaming machine 1 by the host control circuit 210, and various data tables ( 26 to 28 described later) are stored. Then, the host control circuit 210 executes various processes according to the program stored in the sub main ROM 205.

  In the present embodiment, the sub main ROM 205 is applied as a storage unit for storing the programs used in the host control circuit 210 and various tables, but the present invention is not limited to this. As such a storage unit, a storage medium of another mode may be used as long as it is a storage medium readable by a computer having a control unit. For example, a hard disk device, a CD-ROM, a DVD-ROM, a ROM cartridge, and the like May be applied. Further, each of the programs may be recorded on a separate storage medium. Further, the program may be recorded in a recording medium in advance, or may be downloaded from the outside or the like after the power is turned on, and may be recorded in the sub main ROM 205.

  The CGROM board 204 is provided with a CGROM 206 (first information storage means, second information storage means, first storage means). The CGROM 206 is configured by a NOR type or NAND type flash memory. The CGROM 206 stores, for example, image data displayed on the display device 13, audio data reproduced by the speaker 11 (access data to be described later), and the like. At this time, various data are compressed (encoded) and stored in the CGROM 206. However, the present invention is not limited to this, and various data may be stored in the CGROM 206 without being compressed.

  In the present embodiment, the configuration in which various ROM boards (the control ROM board 203 and the CGROM board 204) and the sub-board 202 are connected by the board-to-board connector in the sub-control circuit 200 has been described. The invention is not limited to this. For example, various types of ROMs may be directly inserted into ports such as sockets provided on the sub-substrate 202, and the sub-substrate 202 may be constituted by a single substrate having a ROM function or the ROM itself. That is, the sub-board 202 and various ROMs may be integrally configured. Further, when the sub-substrate 202 is configured by a single substrate having a ROM function or a ROM itself, the sub-control circuit 200 controls the sub-controller used according to the type of the memory used as the CGROM. Switching means for physically or electrically switching the circuit on the board, or switching means for switching information of the circuit on the sub-board used according to the type of the memory may be provided.

  Further, in the present embodiment, the magnitude relationship of the data communication speed between each of the various storage means (sub-main ROM 205, CGROM 206, built-in VRAM 237, SDRAM 250) and the corresponding control circuit is as follows: built-in VRAM 237> SDRAM 250> sub-main ROM 205 becomes CGROM 206. That is, in the present embodiment, the communication speed between the built-in VRAM 237 and various circuits in the display control circuit 230 is the fastest, and then the communication speed between the SDRAM 250 and the display control circuit 230 is fastest. Then, the communication speed between the sub main ROM 205 and the host control circuit 210 and the communication speed between the CGROM 206 and the display control circuit 230 become the slowest. However, the present invention is not limited to this, and the magnitude relationship of the communication speed between each of the various storage units and the corresponding control circuit can be arbitrarily set. For example, the magnitude of the communication speed between each of the various storage means and the corresponding control circuit may be different from that of the present embodiment, or the communication speed between each of the storage means and the corresponding control circuit may be different. May be all the same.

  Here, the possible configurations of the above-described various storage units (first information storage unit to fourth information storage unit) will be described. In the present embodiment, a storage unit (first information storage unit) for storing information (compressed (encoded) image data) related to image data includes information related to transparency data that can be used when setting transparency for the image data. The configuration example in which the storage unit (second information storage unit) of the (alpha table described later) is the same (CGROM 206) has been described. That is, the configuration example in which the “first information storage unit” is physically the same as the “second information storage unit” has been described. However, the present invention is not limited to this. For example, the “first information storage unit” may be configured by a storage unit (storage medium) that is physically different from the “second information storage unit”.

  Further, the "information storage means" in the present specification may mean not only a storage means such as the CGROM 206, but also a table stored in the storage means, a data storage area in the storage means, or the like. Good. Therefore, for example, the "first information storage means" and the "second information storage means" may be different data storage areas or different tables in the same storage means, Further, the data may be stored in different register addresses. In other words, the term "information storage means" used in this specification is different not only when the storage means (storage medium) is physically different, but also when the storage means is physically the same (for example, ROM, RAM, etc.). However, this also includes a case where the data area (a storage area distinguished by an address, a register, a table, a structure, and the like) in the storage means is different.

  The meaning of the “information storage means” in the present specification described above is also applicable to the “third information storage means” (SDRAM 250) and the “fourth information storage means” (built-in VRAM 237). Therefore, for example, the “first information storage unit” to the “fourth information storage unit” may be configured by storage units (storage media) that are physically different from each other, or the “first information storage unit” to the “first information storage unit”. The "fourth information storage means" may be constituted by different data areas (storage areas distinguished by addresses, registers, tables, structures, etc.) in one storage means.

  In the present embodiment, the “first information storage unit” and the “second information storage unit” are configured by different data areas in one storage unit (CGROM 206), and the “third information storage unit” is used. , A storage unit (SDRAM 250) physically different from the storage unit (CGROM 206) including the “first information storage unit” and the “second information storage unit”, and the “fourth information storage unit” An example will be described in which the storage unit (CGROM 206) including the “first information storage unit” and the “second information storage unit” and the storage unit (built-in VRAM 237) that is physically different from the “third information storage unit” (SDRAM 250). However, the present invention is not limited to this. Whether the "information storage means" is composed of a data area or a storage means, and how the combination of the "information storage means" defined as the data area and the "information storage means" defined as the storage means The mode can be appropriately set according to, 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 unit” to the “third information storage unit” are configured by different data areas in one storage unit, and the “fourth information storage unit” A storage unit physically different from a storage unit including “first information storage unit” to “third information storage unit” may be used.

[Audio / LED control circuit]
Next, the internal configuration of the audio / LED control circuit 220 will be described with reference to FIG. FIG. 7 is a block diagram showing an internal circuit configuration of the audio / LED control circuit 220 and a connection relation between the audio / LED control circuit 220 and various peripheral devices and peripheral circuit units. In FIG. 7, illustration of a relay board and the like provided between the audio / LED control circuit 220 and various peripheral devices and circuit units is omitted for simplification of description.

  As shown in FIG. 7, the audio / LED control circuit 220 includes an LSI (Large-Scale Integration) interface 221, a memory interface 222, a digital audio interface 223, a peripheral interface 224, a command register 225, and a sound lamp. The control module 226 includes a control module 226, a main generator 227, and a multi-effector 228. The connection relation of each unit in the audio / LED control circuit 220 is as follows.

  In the audio / LED control circuit 220, the sound / lamp control module 226 is connected to the memory interface 222, the peripheral interface 224, the command register 225, the main generator 227, and the multi-effector 228. The command register 225 is connected to the LSI interface 221 in addition to the sound lamp control module 226. The main generator 227 is connected to the memory interface 222 and the multi-effector 228 in addition to the sound lamp control module 226. Further, the multi-effector 228 is connected to the memory interface 222 and the digital audio interface 223 in addition to the sound / lamp control module 226 and the main generator 227.

  Next, the configuration of each unit in the audio / LED control circuit 220 will be described.

  The LSI interface 221 is an interface circuit used when performing an input / output operation of a control signal or the like (for example, a sound request, a lamp request, or the like) between the host control circuit 210 and the command register 225. That is, the command register 225 is connected to the host control circuit 210 via the LSI interface 221.

  The memory interface 222 is an interface circuit used when performing input / output operations of audio data and the like between the sub main ROM 205 and each of the sound / lamp control module 226, the main generator 227, and the multi-effector 228.

  The digital audio interface 223 is an interface circuit used when outputting a sound signal or the like from the multi-effector 228 to the speaker 11. The digital audio interface 223 outputs an audio input signal to the multi-effector 228.

  The peripheral interface 224 is an interface circuit used when performing an input / output operation of a lamp signal or the like (such as LED data described later) between the lamp group 18 and the sound / lamp control module 226. The peripheral interface 224 is provided with three physical systems as physical systems (SPI channels) for outputting data to the LED drivers included in the lamp group 18. In the present embodiment, two physical systems (physical system 0 (SPI channel 0) and physical system 1 (SPI channel 1)) are used as described later.

  The command register 225 includes a register group. The command register 225 sets the function control of the sound / lamp control module 226, the main generator 227, and the multi-effector 228. The command register 225 also sets the operating conditions of each interface (LSI interface 221, memory interface 222, digital audio interface 223, peripheral interface 224).

  Note that an IC (Integrated Circuit) is mounted on each register constituting the command register 225, and each register is constituted by a memory chip whose operation is stabilized by memory access control. When a register having such a configuration is used, the load on the signal bus to which each register is connected is reduced. Therefore, by increasing the number of memory chips (registers), the capacity per memory module ( The capacity of the command register 225) can be increased.

  The sound / lamp control module 226 controls the operation of each component (each block) in the audio / LED control circuit 220 according to the setting contents of the command register 225. As shown in FIG. 7, the sound / lamp control module 226 includes a simple access control unit 226a, a sequencer unit 226b, a lamp control unit 226c, and a peripheral control unit 226d.

  The simple access control unit 226a is a circuit unit that processes commands collectively. The sequencer unit 226b includes various sequencers (automatic reproduction function units) for controlling automatic reproduction operations such as lamp lighting and audio. Each sequencer controls various operations in accordance with a timer and step conditions (for example, conditions set for each step processing during sequence playback such as LED animation and audio, which will be described later).

  The lamp control unit 226c calculates the luminance value to be set for all channels (eight channels) for which LED data described later can be set, and transmits the calculation result to the outside (LED driver). Further, the peripheral control unit 226d performs physical transmission control when transmitting the calculation result data output from the lamp control unit 226c to the LED driver.

  The main generator 227 is a circuit that generates an audio signal. Specifically, the main generator 227 acquires predetermined audio data (for example, access data described later) stored in the CGROM 206 based on the control signal input from the sound / lamp control module 226, and The acquired audio data is converted into a predetermined audio signal. The main generator 227 also performs an amplification process on the generated audio signal.

  The multi-effector 228 includes a mixer that synthesizes an audio signal input from the main generator 227 and an audio input signal input from the digital audio interface 223, and various effectors for giving various sound effects to the audio. Then, the multi-effector 228 outputs an audio signal synthesized by the mixer, an output signal from the effector, and the like to the speaker 11 via the digital audio interface 223.

[Connection configuration between digital audio power amplifier and speaker]
Next, a connection configuration between the digital audio power amplifier 262 provided in the built-in relay board 260 and its peripheral circuit and the speaker 11 will be described with reference to FIG. FIG. 8 is a connection configuration diagram between the built-in relay board 260 and the speaker 11. FIG. 8 shows a state in which the speaker 11 is not connected to the built-in relay board 260 in order to clarify the configuration of the connection portion.

  In the pachinko gaming machine 1 of the present embodiment, as shown in FIG. 8, a speaker box 11a provided with a speaker 11 is connected to a built-in relay board 260 via a harness 300 (signal wiring means).

  The built-in relay board 260 includes a digital audio power amplifier 262, an LC circuit 263, a connection terminal group 264 (second terminal group) including four connection terminals (first to fourth connection terminals), and two resistors. 265, 266, a capacitor 267, and a NOT circuit (logic circuit) 268.

  The digital audio power amplifier 262 amplifies the input audio signal (audio data), outputs the amplified audio signal to the speaker 11, and drives the speaker 11. The LC circuit 263 is configured by a resonance circuit including a coil and a capacitor. The NOT circuit 268 is a logic circuit that inverts the level of an input signal and outputs the inverted signal.

  The clock input terminal (MCK) and the data input terminal (SDATA) of the digital audio power amplifier 262 are connected to the audio / LED control circuit 220. The clock signal (master clock signal) output from the audio / LED control circuit 220 is input to the clock input terminal (MCK) of the digital audio power amplifier 262, and the audio / LED is input to the data input terminal (SDATA). The audio signal (audio data) output from the control circuit 220 is input.

  Further, the first output terminal (OUTM1) and the second output terminal (OUTM2) of the digital audio power amplifier 262 are connected to the first connection terminal and the first connection terminal in the connection terminal group 264 of the built-in relay board 260 via the LC circuit 263, respectively. It is connected to a second connection terminal (first connection terminal). In the present embodiment, an example is shown in which two output terminals of the digital audio power amplifier 262 are provided. However, the present invention is not limited to this, and may be appropriately changed according to, for example, the functions and specifications of the speaker 11. Can be.

  Further, the digital audio power amplifier 262 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, the digital audio power amplifier 262 outputs the audio signal from the first output terminal (OUTM1) and the second output terminal (OUTM2). It has a function of stopping output or bringing these output terminals into a grounded state 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 a LOW level, the digital audio power amplifier 262 transmits the first audio signal from the first output terminal (OUTM1) and the second output terminal (OUTM2) to the first terminal of the internal relay board 260. 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, the digital audio power amplifier 262 outputs the first output terminal (OUTM1) and the second output terminal (OUTM2). To output an audio signal.

  The third connection terminal (second connection terminal) in the connection terminal group 264 of the built-in relay board 260 is connected to the input terminal of the NOT circuit 268 via the resistor 266. An output terminal of the NOT circuit 268 is connected to a mute terminal (MUTE) of the digital audio power amplifier 262. The signal wiring between the third connection terminal of the built-in relay board 260 and the resistor 266 is connected to a power supply voltage (+5 V) terminal provided in the built-in relay board 260 via the resistor 265. The signal wiring between the input terminal of the NOT circuit 268 and the resistor 266 is connected (grounded) to a ground (GND) terminal provided in the built-in relay board 260 via the capacitor 267. Further, the fourth connection terminal (third connection terminal) of the built-in relay board 260 is connected to a ground (GND) terminal.

  As shown in FIG. 8, the speaker 11 is mounted on a speaker box 11a formed of a wooden frame. The speaker box 11a is provided with a connection terminal group 11b (first terminal group) including four connection terminals (first connection terminal to fourth connection terminal). Then, the first connection terminal and the second connection terminal of the speaker box 11a are connected to the speaker 11 via signal wiring. Further, the third connection terminal (specific connection terminal) of the speaker box 11a is electrically connected to the fourth connection terminal by the signal wiring W1.

  As shown in FIG. 8, the harness 300 is configured by bundling four signal wires. One of the four connection terminals (first connection terminal to fourth connection terminal) of the four signal wirings is connected to the first connection terminal to fourth connection terminal of the built-in relay board 260, respectively. On the other hand, the other four connection terminals (fifth connection terminal to eighth connection terminal) of the four signal wirings are connected to the first connection terminal to fourth connection terminal of the speaker box 11a, respectively. That is, the signal wiring (first signal wiring) between the first connection terminal and the fifth connection terminal in the harness 300 connects between the first connection terminal of the built-in relay board 260 and the first connection terminal of the speaker box 11a. The second connection terminal of the built-in relay board 260 and the second connection terminal of the speaker box 11a are connected by signal wiring between the second connection terminal and the sixth connection terminal in the harness 300. Further, between the third connection terminal of the built-in relay board 260 and the third connection terminal of the speaker box 11a, a signal wiring (second signal wiring) between the third connection terminal and the seventh connection terminal in the harness 300 is provided. The signal wiring (third signal wiring) between the fourth connection terminal and the eighth connection terminal in the harness 300 is provided between the fourth connection terminal of the built-in relay board 260 and the fourth connection terminal of the speaker box 11a. Connected by Thereby, the speaker 11 is connected to the built-in relay board 260 via the harness 300.

  Note that the number of signal wires included in the harness 300 is not limited to four, and may be appropriately changed according to, for example, the specifications of the digital audio power amplifier 262 and the speaker 11 and the connection configuration between the two. In the harness 300, at least signal wiring for connecting the output terminal of the digital audio power amplifier 262 and the speaker 11 and signal wiring for grounding the mute terminal of the digital audio power amplifier 262 via the speaker box 11a. Should just be included.

  When the built-in relay board 260 and the speaker 11 are connected via the harness 300 as described above, the first output terminal (OUTM1) and the second output terminal (OUTM2) of the digital audio power amplifier 262 are connected via the harness 300. Connected to the speaker 11. The mute terminal (MUTE) of the digital audio power amplifier 262 is grounded via the NOT circuit 268, the harness 300, and the signal wiring W1 between the third and fourth connection terminals of the speaker box 11a.

  As a result, when the speaker 11 is connected to the built-in relay board 260 (digital audio power amplifier 262) via the harness 300, a LOW level voltage signal is input to the NOT circuit 268, so that the digital audio power amplifier 262 The level (amplitude value) of the voltage signal input to the mute terminal (MUTE) becomes HIGH level. In this case, an audio signal is output to the speaker 11 from the first output terminal (OUTM1) and the second output terminal (OUTM2) of the digital audio power amplifier 262.

  On the other hand, when the speaker 11 is not connected to the built-in relay board 260 (digital audio power amplifier 262), the third connection terminal of the built-in relay board 260 is open. In this case, since the power supply voltage (+5 V) is input to the NOT circuit 268, the level (amplitude value) of the voltage signal input to the mute terminal (MUTE) of the digital audio power amplifier 262 becomes the LOW level, and the digital audio power amplifier The mute function described above at 262 operates.

  That is, when the speaker 11 is separated from the built-in relay board 260 (digital audio power amplifier 262), the built-in relay board 260 is connected to the first output terminal (OUTM1) and the second output terminal (OUTM2) of the digital audio power amplifier 262. Is generated such that the output of the audio signal to the first connection terminal and the second connection terminal is stopped. As a result, occurrence of a resonance phenomenon between the digital audio power amplifier 262 (output terminal) and the first and second connection terminals of the built-in relay board 260 is suppressed, and trouble such as failure of the digital audio power amplifier 262 is prevented. Can be prevented.

  As described above, in the present embodiment, the mute function of the digital audio power amplifier 262 can be operated regardless of software control by the host control circuit 210 and the audio / LED control circuit 220. Therefore, for example, even when the host control circuit 210 and the audio / LED control circuit 220 recognize that the output stop control of the audio signal is being performed in a situation where the speaker 11 is separated from the built-in relay board 260, In the case where the audio signal is output erroneously due to a bug (defect) or in the pachinko gaming machine 1 having a structure in which the gaming board cannot be replaced unless the speaker 11 is removed from the harness 300, after the replacement of the gaming board is completed. Even if the door is closed and the audio output is started without connecting the speaker 11 and the harness 300 by mistake, the above-described mute function of the digital audio power amplifier 262 is activated in hardware. In this case, the digital audio power amplifier 262 can be reliably protected, and the safety of the pachinko gaming machine 1 can be improved.

  Further, in the present embodiment, as described above, the third connection terminal of the built-in relay board 260 is connected to the harness 300 and the signal wiring W1 between the third and fourth connection terminals of the speaker box 11a. It is connected to a ground (GND) terminal provided in built-in relay board 260. With such a configuration, when the signal level of the third connection terminal of the built-in relay board 260 is LOW, is this factor due to the grounding of the fourth connection terminal of the built-in relay board 260? Since the determination can be made by measuring the signal level of the fourth connection terminal of the built-in relay board 260, the digital output operation from the digital audio power amplifier 262 can be managed more accurately.

[Voltage conversion circuit section]
(1) Internal Configuration Next, the configuration of the voltage conversion circuit unit 269 mounted on the built-in relay board 260 will be described with reference to FIG. FIG. 9 is a diagram showing the internal configuration of the voltage conversion circuit unit 269.

  The voltage conversion circuit unit 269 includes a voltage drop circuit unit 350 (first voltage conversion circuit unit), a linear regulator 360 (second voltage conversion circuit unit), and two capacitors 361 and 362 (hereinafter, a first capacitor 361). And a second capacitor 362).

  The voltage drop circuit unit 350 connects five diodes 351 to 355 (hereinafter, referred to as first to fifth diodes 355) in series (a cathode of one diode is connected to an anode of the other diode between two adjacent diodes). ). Each of the first diode 351 to the fifth diode 355 is configured by a diode (voltage lowering unit) having the same rectification characteristic (performance). As each diode, a diode having a characteristic that a forward voltage (energization start voltage) is 1.1 V is used. Therefore, at the time of energization, a voltage drop of at least 1.1 V occurs in each diode.

  The linear regulator 350 is a circuit that has a function of dropping the input voltage (DC voltage) by consuming the input power (voltage drop function), and converts the input voltage to a DC voltage of +5 V and outputs the converted DC voltage.

  In the voltage conversion circuit section 269, the anode of the first diode 351 is connected to an input terminal (not shown) of a power supply voltage of +12 V, and the cathode of the fifth diode 355 is connected to the input terminal of the linear regulator 360 (Vin in FIG. 9). Terminal).

  An output terminal (Vout terminal in FIG. 9) of the linear regulator 360 is an input terminal (not shown) of a driving voltage of +5 V (for example, each power input terminal of the speaker 11, the lamp group 18, and the motor controller 270 (the accessory 20)). ).

  The first capacitor 361 is connected between a wiring between the cathode of the fifth diode 355 and the input terminal of the linear regulator 360, and a ground (GND) terminal provided in the built-in relay board 260. The second capacitor 362 is connected between the output terminal of the linear regulator 360 and a ground (GND) terminal provided in the built-in relay board 260. Further, a ground (GND) terminal of the linear regulator 360 is also connected to a ground (GND) terminal provided in the built-in relay board 260.

  In the voltage conversion circuit unit 269 having the above-described configuration, the +12 V power supply voltage (first DC voltage) supplied (input) to the voltage conversion circuit unit 269 is supplied to the voltage drop circuit unit 350 (the first diode 351 connected in series). To the fifth diode 355) to a predetermined DC voltage (however, a DC voltage higher than + 5V). Next, the predetermined DC voltage (second DC voltage) dropped by the voltage dropping circuit section 350 (first diode 351 to fifth diode 355) is input to the input terminal (Vin terminal) of the linear regulator 360. Then, the linear regulator 360 converts the input predetermined DC voltage (+6.5 V in the present embodiment) to a DC voltage of +5 V (third DC voltage), and outputs the converted DC voltage of +5 V to an output terminal. (Vout terminal) to each of the speaker 11, the lamp group 18, and the motor controller 270 (the accessory 20).

(2) Heating Suppression Characteristics of Linear Regulator As in the voltage conversion circuit unit 269 of the present embodiment described above, a voltage drop circuit unit 350 configured by connecting a plurality of diodes in series is provided on the input side of the linear regulator 360. In this case, the DC voltage input to the linear regulator 350 can be reduced. In this case, the difference between the input voltage and the output voltage (+5 V) of the linear regulator 360 is reduced, and the amount of heat generated during the operation of the linear regulator 360 can be reduced.

  Here, referring to FIG. 10, the number of diodes provided in the voltage dropping circuit section 350 (the input side of the linear regulator 360), and the element temperature (junction temperature) at the time of operation of the linear regulator 360 for each number of diodes An example of the correspondence relationship with will be described.

  FIG. 10 shows that the linear regulator 360 has a maximum output current of 1 A, an operating junction temperature (Tj) range of −40 ° C. to 150 ° C., and a thermal resistance (θja) of 125.0 when the element is used alone. The following is an example of characteristics when a linear regulator having a characteristic (performance) of 12.5 ° C./W and a thermal resistance (θja) of 12.5 ° C./W when using an infinite heatsink is shown. FIG. 10 shows an example in which a diode having characteristics such that the voltage drop per diode is 1.1 V (the forward voltage of the diode is 1.1 V) is used.

  “Vin” (input voltage) in FIG. 10 is a DC voltage input to the linear regulator 360. “Vout” (output voltage) is a DC voltage output from the linear regulator 360, and is +5 V regardless of the number of diodes in the present embodiment. “Iin” (input current) is a current flowing in the linear regulator 360, and is set to 0.5 A in the example shown in FIG. 10 regardless of the number of diodes. “Pc” (power loss) is power consumed by the linear regulator 360, and the power loss Pc is calculated by the equation Pc = (Vin−Vout) × Iin.

  Further, “θja” (thermal resistance) in FIG. 10 is a thermal resistance value generated by the linear regulator 360, and is set to 50 ° C./W in the example shown in FIG. The value near the middle of the thermal resistance when a large heat sink is used.) “Ta” (ambient temperature) is the ambient temperature (environmental temperature) of the linear regulator 360, and is set to 25 ° C. (about room temperature) in the example shown in FIG. “Tj” (element temperature) is the temperature of the linear regulator 360 during the operation of the linear regulator 360, and the element temperature Tj is calculated by the equation Tj = Pc × θja + Ta.

  In the example shown in FIG. 10, when the number of diodes connected in series is 0, 1, 2, 3, 4, and 5, the input voltages Vin of the linear regulator 360 are 12 V and 10.9 V, respectively. , 9.8V, 8.7V, 7.6V and 6.5V. That is, in the example shown in FIG. 10, each time the number of diodes increases by one, the input voltage Vin of the linear regulator 360 decreases at intervals of 1.1V.

  Assuming that the number of diodes connected in series is 0, 1, 2, 3, 4, and 5, the element temperatures Tj of the linear regulator 360 are 200 ° C., 172.5 ° C., and 145 ° C., respectively. , 117.5 ° C, 90 ° C and 62.5 ° C. That is, in the example shown in FIG. 10, each time the number of diodes increases by one, the element temperature Tj of the linear regulator 360 decreases at intervals of 27.5 ° C.

  As described above, when the voltage drop circuit unit 350 configured by connecting five diodes (first diode 351 to fifth diode 355) in series is provided on the input side of the linear regulator 360, the elements of the linear regulator 360 The temperature Tj is 62.5 ° C., which is not more than ３ of the element temperature Tj (200 ° C.) when the voltage drop circuit section 350 (diode) is not provided, and the amount of heat generated when the linear regulator 360 operates is greatly reduced. can do. Further, in the pachinko gaming machine 1 of the present embodiment having the above-described configuration, since heat generation of the linear regulator 360 can be suppressed, heat radiation measures such as installing a heat sink and increasing a substrate area are performed on the linear regulator 360. Since the necessity is eliminated, cost increase can be suppressed.

  That is, in the pachinko gaming machine 1 of the present embodiment, it is possible to suppress the heat generation of the linear regulator 360 (the second voltage conversion circuit unit) and also suppress the cost increase.

  Note that, in the example shown in FIG. 10, the configuration example in which the input voltage Vin of the linear regulator 360 is higher than the output voltage Vout (5 V) is shown, but the present invention is not limited to this. The voltage dropping circuit section 350 may be configured to drop the voltage to 5V, that is, the input voltage Vin of the linear regulator 360 may have the same value as the output voltage Vout (5V). In this case, heat generation of the linear regulator 360 can be substantially eliminated (minimized).

  Further, in the present embodiment, an example has been described in which five diodes having the same rectification characteristics (performance) are provided in series on the input side of the linear regulator 360, but the present invention is not limited to this. The rectification characteristics (performance) of the diodes connected in series may be different from each other, or diodes having different rectification characteristics (performance) may be used for only some of the plurality of diodes. The number of diodes connected in series is not limited to five. For example, the rectification characteristics (forward voltage value) of each diode, the value of the power supply voltage input to the voltage conversion circuit unit 269, the voltage conversion circuit unit 269 can be set as appropriate according to the value of the DC voltage (drive voltage) output from the linear regulator 360, the performance of the linear regulator 360, and the like.

  Furthermore, in the present embodiment, an example in which a diode is used as a circuit element constituting the voltage drop circuit unit 350 has been described, but the present invention is not limited to this, and any circuit element having a voltage lowering function may be used. It can be used instead of a diode. However, depending on the configuration (material, shape, size, etc.) of the circuit element to be used, one having a compact configuration such as a diode may be considered. Therefore, from the viewpoint of space saving, it is preferable to use a diode as a circuit element constituting the voltage drop circuit unit 350. In particular, when a diode that can be surface-mounted (plane mounted) on a substrate (in this embodiment, the built-in relay substrate 260) is used as the diode, a heat-dissipating mechanism such as a heat sink is provided on the substrate. The space can be significantly reduced as compared to the configuration described above.

  In the present embodiment, an example is described in which the linear regulator 360 is used as a voltage conversion circuit (a circuit that generates a drive voltage of a staging device) provided on the output side of the voltage drop circuit unit 350, but the present invention is not limited to this. Not done. A voltage conversion circuit that consumes input power internally and drops a DC voltage, that is, a voltage conversion circuit in which the amount of heat generated changes according to the voltage difference between the input voltage and the output voltage due to the principle of DC / DC conversion , An arbitrary voltage conversion circuit can be applied instead of the linear regulator 360.

[Display control circuit]
Next, the internal configuration of the display control circuit 230 will be described with reference to FIG. FIG. 11 is a block diagram showing a circuit configuration inside the display control circuit 230 and a connection relationship between the display control circuit 230 and various peripheral devices and peripheral circuit units.

  As shown in FIG. 11, the display control circuit 230 includes a memory controller 231, a command memory 232, a command parser 233, a moving image decoder 234, a still image decoder 235, an SDRAM controller 236, a built-in VRAM 237, A display controller 238, a second display controller 239, a 3D (Dimension) geometry engine 240, and a rendering engine 241 are provided. The connection relation of each part in the display control circuit 230 and the connection relation between the display control circuit 230 and its various peripheral devices and peripheral circuits are as follows.

  In the display control circuit 230, the memory controller 231 is connected to a command parser 233, a moving image decoder 234, and a still image decoder 235. The command parser 233 is connected to a command memory 232, a moving image decoder 234, a still image decoder 235, and a 3D geometry engine 240, in addition to the memory controller 231. The video decoder 234 is connected to the SDRAM controller 236 in addition to the memory controller 231 and the command parser 233. The still image decoder 235 is connected to the built-in VRAM 237 in addition to the memory controller 231 and the command parser 233.

  In the display control circuit 230, the SDRAM controller 236 is connected to the built-in VRAM 237, the first display controller 238, and the second display controller 239 in addition to the moving image decoder 234. The built-in VRAM 237 is connected to the first display controller 238, the second display controller 239, and the rendering engine 241 in addition to the still image decoder 235 and the SDRAM controller 236. Further, the 3D geometry engine 240 is connected to a rendering engine 241 in addition to the command parser 233.

  The SDRAM 250 is connected to the memory controller 231 and the SDRAM controller 236 in the display control circuit 230. Further, the CGROM board 204 is connected to a memory controller 231 in the display control circuit 230. The host control circuit 210 is connected to the memory controller 231 and the command memory 232 in the display control circuit 230. Further, the display device 13 is connected to a first display controller 238 and a second display controller 239 in the display control circuit 230.

  Next, the configuration of each unit in the display control circuit 230 will be described.

  The memory controller 231 mainly performs communication control between various external memories (the CGROM board 204 and the SDRAM 250) and the display control circuit 230. For example, the memory controller 231 performs transmission / reception of an address designation signal of an external memory to be controlled, memory ready, busy management, and the like, and stores data (effect data) stored at addresses designated for various memories. , Command data, etc.).

  The command memory 232 is a built-in memory for storing a command list. Note that the command list can be stored in the SDRAM 250 and the CGROM board 204 (CGROM 206) in addition to the command memory 232.

  The command parser 233 acquires a command list from a specified memory (command memory 232, SDRAM 250, or CGROM 206). Specifically, in the present embodiment, the type of the memory in which the command list is arranged (command memory 232, SDRAM 250, or CGROM 206) is stored in a system control register (not shown) in the display control circuit 230 by the host control circuit 210; The start address is set. Then, the command parser 233 accesses the start address in the memory specified in the system control register (not shown) to acquire the command list.

  The command parser 233 analyzes the acquired command list to generate a specific control code, and outputs the control code to the moving image decoder 234, the still image decoder 235, and the 3D geometry engine 240. In the present embodiment, each image processing module in the display control circuit 230 operates based on the control code output by the command parser 233.

  The moving image decoder 234 decodes (decodes) the compressed moving image data obtained from the CGROM board 204 or the SDRAM 250. Then, the moving image decoder 234 outputs the decoded moving image data to the SDRAM 250 (external RAM). The moving image data (decoding result) output from the moving image decoder 234 is stored in a movie buffer provided in the SDRAM 250.

  The still image decoder 235 decodes the compressed still image data obtained from the CGROM board 204 or the SDRAM 250. Then, the still image decoder 235 outputs the decoded still image data to the built-in VRAM 237. Note that the still image data (decoding result) output from the still image decoder 235 is temporarily stored in a sprite buffer described later provided in the built-in VRAM 237.

  The SDRAM controller 236 stores the decoded moving image data and still image data in the RAM, as well as the built-in VRAM 237 and the CGROM board 204 or the SDRAM 250, as described in a drawing process described later (see FIGS. 97 to 99 described later). This is a controller that controls operations such as a process of transferring image data between the device and the device.

  The built-in VRAM 237 operates as a work RAM when performing various processes such as a decoding process and a rendering process in a later-described drawing process (see FIGS. 97 to 99 described later) by the display control circuit 230. Further, in image data transfer processing between the built-in VRAM 237 and the CGROM board 204 or the SDRAM 250, which is performed in each processing step in a drawing process described later, various image data are temporarily stored in the built-in VRAM 237.

  Each of the first display controller 238 and the second display controller 239 obtains a rendering result (rendering result) generated by the rendering engine 241 and outputs the rendering result to the display device 13. Thereby, a predetermined image is displayed on the display screen of the display device 13. When two display controllers are provided as in the pachinko gaming machine 1 of the present embodiment, two screens are provided on the display device 13 by one display control circuit 230 (one chip) and each screen is provided. Can be controlled independently.

  The 3D geometry engine 240 converts three-dimensional information into two-dimensional information (projection conversion processing) based on a control code input from the command parser 233, and performs affine transformation such as enlargement, reduction, rotation, and movement of a figure. (Graphic conversion) processing is performed. Then, the 3D geometry engine 240 outputs the result of the conversion process to the rendering engine 241.

  The rendering engine 241 refers to a texture source (SDRAM 250 in the present embodiment) in which the expanded still image data and moving image data are stored, and performs a rendering (drawing) process on the image data. Then, the rendering engine 241 writes the rendering result to a rendering target (in the present embodiment, the built-in VRAM 237 or the SDRAM 250).

  In the present specification, “rendering (drawing)” refers to editing decoded data in accordance with designation information such as scaling and rotation of a moving image (in this embodiment, information output from the 3D geometry engine 240). It is to be. The “rendering engine” here includes, for example, a “rasterizer”, a “pixel shader”, and the like. Therefore, in the rendering engine 241, similarly to the pixel shader, the ARGB value (A: alpha value indicating transparency (opacity), R: luminance value of a red component, and G: green component in pixel units with respect to image data. , And B: the luminance value of the blue component).

[Connection between display control circuit and CGROM]
The pachinko gaming machine 1 according to the present embodiment has a configuration that can cope with different types of CGROM (NOR type or NAND type) connected to the display control circuit 230. Here, the connection configuration between the display control circuit 230 provided in the sub-substrate 202 and its peripheral circuits and the CGROM mounted on the CGROM substrate will be described with reference to FIGS.

  FIG. 12 is a connection configuration diagram between the sub-board 202 and the CGROM board 204a when the CGROM is a NOR-type CGROM 206a (NOR-type flash memory). FIG. 13 is a connection configuration diagram between the sub board 202 and the CGROM board 204b when the CGROM is a NAND CGROM 206b (NAND flash memory). 12 and 13 show a state in which the CGROM board is detached from the sub-board 202 in order to make the configuration of the connection part clearer, but actually, both boards are connected via the board-to-board connector. Connected.

(1) Configuration of Sub-Substrate First, the internal configuration of the sub-substrate 202 will be described. As is clear from the comparison between FIG. 12 and FIG. 13, the configuration of the sub-substrate 202 when the NOR-type CGROM 206a is mounted on the CGROM substrate 204a is different from that when the NAND-type CGROM 206b is mounted on the CGROM substrate 204b. The same is true.

  As shown in FIGS. 12 and 13, the sub-substrate 202 is provided with a display control circuit 230 and, as its peripheral circuits, a bidirectional balance transceiver 301 (communication mode setting means) and an AND circuit 302 (AND gate). Provided. The sub-board 202 has a terminal group 303 (first terminal group) including various signal wirings (buses) and a plurality of connection terminals directly or indirectly connected to the display control circuit 230 via the various buses. Are provided.

  The two-way balance transceiver 301 includes four input / output terminals (terminals A0 to A3 in FIG. 12) and the other four input / output terminals (terminals A0 to A3) connected to the four input / output terminals (terminals A0 to A3). And two input / output terminals (terminals B0 to B3 in FIG. 12). The two-way balance transceiver 301 has two control terminals (terminals in FIG. 12) for switching control of the signal communication direction between the input / output terminals A0 to A3 and the input / output terminals B0 to B3. OE and terminal DIR).

  The bidirectional balance transceiver 301 is connected between the input / output terminals A0 to A3 and the input / output terminals B0 to B3 according to the combination of the signal levels of the voltage signals applied to the control terminal OE and the control terminal DIR. Switch the communication direction of the signal. Thereby, even if the communication direction (communication operation) is inconsistent for some reason, the safety of the communication operation between the display control circuit 230 and the CGROM can be ensured. The communication direction switching control operation in the bidirectional balanced transceiver 301 will be described later in detail. In addition, the bidirectional balanced transceiver 301 used in the present embodiment can support a system having two power supplies of 3.3 V and 5 V.

  The display control circuit 230 is provided with four input / output terminals (terminals GMA31 / GRB3 to GMA28 / GRB0 in FIG. 12). These input / output terminals GMA31 / GRB3 to input / output terminals GMA28 / GRB0 function as address bus output terminals when the CGROM is a NOR type CGROM 206a, and ready when the CGROM is a NAND type CGROM 206b. / Busy signal input terminal. Further, the display control circuit 230 is provided with 26 output terminals (terminals GMA27 to GMA2 in FIG. 12) which function as output terminals for data relating to the address of the data storage area in the CGROM (such as address designation data). Can be

  Further, the display control circuit 230 is provided with two CG memory chip enable output terminals (terminals GCE_0 and GCE_1 in FIG. 12). In the present embodiment, the display control circuit 230 has two memory spaces corresponding to the two CG memory chip enable output terminals (GCE_0, GCE_1: specific output terminals). Information such as type, bus width, and access timing is set. However, in the present embodiment, the display control circuit 230 cannot support (use) the case where the ROM in the synchronous mode and the ROM in the asynchronous mode are mixed.

  Further, the display control circuit 230 is provided with a plurality of data bus input terminals for acquiring image data (compressed moving image / still image data) from the CGROM via the data bus.

  The electrical connection relationship between the above components provided on the sub-substrate 202 is as follows.

  The input / output terminals GMA31 / GRB3 to the input / output terminals GMA28 / GRB0 of the display control circuit 230 are connected to the input / output terminals B0 to B3 of the bidirectional balance transceiver 301, respectively, as shown in FIGS. Is done. The input / output terminals A0 to A3 of the bidirectional balanced transceiver 301 are connected to the first to fourth connection terminals of the terminal group 303, respectively. That is, the input / output terminal GMA31 / GRB3 to the input / output terminal GMA28 / GRB0 of the display control circuit 230 are connected to the first to fourth connection terminals of the terminal group 303 via the bidirectional balance transceiver 301, respectively. You.

  The output terminals GMA27 to GMA2 of the display control circuit 230 are respectively connected to the ninth to thirty-fourth connection terminals of the terminal group 303, and the CG memory chip enable output terminal GCE_0 and the CG memory chip enable output terminal GCE_1 , And the 35th connection terminal and the 36th connection terminal of the terminal group 303, respectively. Further, the plurality of data bus input terminals of the display control circuit 230 are respectively connected to corresponding connection terminals of the terminal group 303 from the 37th connection terminal.

  The control terminal DIR of the bidirectional balance transceiver 301 is connected to the fifth connection terminal of the terminal group 303, 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. The sixth connection terminal and the seventh connection terminal of the terminal group 303 of the sub-board 202 are connected to a power supply voltage (+3.3 V) terminal provided on the sub-board 202, and the eighth connection terminal is connected to the sub-board 202. It is connected to the provided ground (GND) terminal.

(2) Configuration of CGROM Board (NOR Type) Next, the internal configuration of the CGROM board 204a on which the NOR type CGROM 206a is mounted will be described with reference to FIG.

  When the NOR-type CGROM 206a is mounted on the CGROM board 204a, the CGROM board 204a has various signal wirings (buses) and terminals including a plurality of connection terminals connected to the CGROM 206a via the various buses, together with the NOR-type CGROM 206a. A group 311 (second terminal group) is provided.

  The first to fourth connection terminals and the connection terminals after the ninth connection terminal in the terminal group 311 provided on the CGROM board 204a are connected to the CGROM 206a.

  In the example shown in FIG. 12, the CGROM 206a is a NOR type flash memory (a flash memory of a random access system), and thus the first to fourth connection terminals and the ninth to thirty-fourth connection terminals in the terminal group 311. The connection terminal is connected to an input terminal (not shown) of an address bus of the CGROM 206a. The 35th connection terminal and the 36th connection terminal in the terminal group 311 are connected to the CG memory chip enable input terminal (not shown) of the CGROM 206a, and the connection terminals after the 37th connection terminal are connected to the CGROM 206a by the display control circuit 230. Is connected to the data output terminal of the CGROM 206a used when acquiring image data (compressed data of moving image / still image) from the CGROM 206a.

  The fifth connection terminal (predetermined connection terminal) in the terminal group 311 provided on the CGROM board 204a is connected to the eighth connection terminal via the signal wiring W2, and the eighth connection terminal is connected to the CGROM board 204a. It is connected to the provided ground (GND) terminal. That is, when the CGROM 206a 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 311 are connected to a power supply voltage (+3.3 V) terminal provided on the CGROM board 204a.

  The number of connection terminals included in the terminal group 311 is the same as the number of connection terminals of the CGROM board connection terminal group 303 provided on the sub-board 202. When connecting (attaching) the CGROM board 204a to the sub-board 202, the two boards are connected so that the connection terminals of the CGROM board 204a are connected to the connection terminals of the sub-board 202 having the same terminal number. That is, as shown in FIG. 12, the first connection terminal, the second connection terminal,..., The thirty-seventh connection terminal of the CGROM board 204a are replaced with the first connection terminal, the second connection terminal,. 37 connection terminals.

(3) Configuration of CGROM Board (NAND) Next, the internal configuration of the CGROM board 204b on which the NAND CGROM 206b is mounted will be described with reference to FIG. In the configuration of the CGROM board 204b shown in FIG. 13, the same components as those of the CGROM board 204a mounted with the NOR type CGROM 206a shown in FIG.

  When the NAND-type CGROM 206b is mounted on the CGROM substrate 204b, the CGROM substrate 204b is provided with a transistor circuit 312 as a peripheral circuit along with the NAND-type CGROM 206b. The CGROM board 204b is provided with various signal wirings (buses) and a terminal group 311 (second terminal group) including a plurality of connection terminals connected directly or indirectly to the CGROM 206b via the various buses. Can be

  The first to fourth connection terminals in the terminal group 311 of the CGROM board 204b 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 206b, and the source terminal is connected to a ground (GND) terminal provided on the CGROM substrate 204b. That is, the first to fourth connection terminals are connected to the CGROM 206b via the transistor circuit 312.

  In the example shown in FIG. 13, the CGROM 206 b is a NAND flash memory (sequential access flash memory), so the gate terminal of the transistor circuit 312, that is, the first to fourth connection terminals in the terminal group 311. The terminal is connected to a ready / busy output terminal (not shown) provided in the CGROM 206b.

  The fifth connection terminal (predetermined connection terminal) in the terminal group 311 of the CGROM board 204b 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. The terminal is connected to a power supply voltage (+3.3 V) terminal provided on the CGROM board 204b. That is, when the CGROM 206b is a NAND flash memory, the fifth connection terminal is connected to the power supply voltage (+3.3 V) terminal via the signal wiring W3.

  The eighth connection terminal in the terminal group 311 of the CGROM board 204b is connected to a ground (GND) terminal provided on the CGROM board 204b.

  Further, the connection terminals after the ninth connection terminal in the terminal group 311 of the CGROM board 204b are connected to the CGROM 206b. At this time, the ninth to thirty-fourth connection terminals are connected to an address input terminal (not shown) provided for the address provided in the CGROM 206b, and the thirty-fifth connection terminal and the thirty-sixth connection terminal are connected to the CG ROM 206b. Connected to memory chip enable input terminal. The 37th connection terminal and the subsequent connection terminals are connected to a data output terminal (not shown) of the CGROM 206b used when the display control circuit 230 acquires image data (compressed data of moving image / still image) from the CGROM 206b. You.

  Even when the NAND-type CGROM 206 b is mounted on the CGROM board 204 b, the number of connection terminals included in the terminal group 311 of the CGROM board 204 b is the same as that of the CGROM board connection terminal group 303 provided on the sub-board 202. It is the same as the number of connection terminals. When connecting (mounting) the CGROM board 204b to the sub-board 202, the two boards are connected so that the connection terminals of the CGROM board 204b are connected to the connection terminals of the sub-board 202 having the same terminal number. That is, as shown in FIG. 13, the first connection terminal, the second connection terminal,..., The 37th connection terminal of the CGROM board 204b are replaced with the first connection terminal, the second connection terminal,. 37 connection terminals.

[Communication operation between display control circuit and CGROM]
Next, an operation when the display control circuit 230 acquires image data (compressed data of moving image / still image) from the CGROM will be described with reference to FIGS. FIG. 14 is a truth table showing the correspondence between input signals and output signals in the AND circuit 302 provided on the sub-substrate 202, and FIG. 5 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.

(1) Operation of AND Circuit and Bidirectional Balanced Transceiver As shown in FIG. 14, the AND circuit 302 operates the bidirectional balanced transceiver 301 only when a HIGH-level signal (voltage signal) is input to both input terminals. A high-level signal is output to the control terminal OE, and a low-level signal is output to the control terminal OE under other input conditions.

  As shown in FIG. 15, the bidirectional balance transceiver 301 receives a LOW level signal (voltage signal) at the control terminal OE and a LOW level signal at the control terminal DIR, as shown in FIG. The input / output terminals A0 to A3 of 301 function as output terminals, and the input / output terminals B0 to B3 function as input terminals. In this case, the communication direction between the display control circuit 230 and the CGROM is a direction from the display control circuit 230 to the CGROM.

  In addition, 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 balance transceiver 301 has input / output terminals A0 to A0 of the bidirectional balance transceiver 301. The terminal A3 functions as an input terminal, and the input / output terminals B0 to B3 function as output terminals. In this case, the communication direction between the display control circuit 230 and the CGROM is a direction from the CGROM to the display control circuit 230.

  When the combination of the signal level input to the control terminal OE of the bidirectional balance transceiver 301 and the signal level input to the control terminal DIR is a combination other than the above (the control terminal OE of the bidirectional balance transceiver 301 is set to HIGH). When a level signal is input, the input / output terminals A0 to A3 and the input / output terminals B0 to B3 of the bidirectional balance transceiver 301 are in the HIGH impedance state (“Z” in FIG. 15). That is, the state is equivalent to the open state, and no communication is performed between the display control circuit 230 and the CGROM.

(2) Communication operation between display control circuit and CGROM (NOR type) First, a case where a CGROM board 204a on which a NOR type CGROM 206a is mounted is connected (mounted) to the sub-board 202 is considered.

  In this case, in the present embodiment, 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 230. 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 hardware initialization processing (see FIG. 81 described later).

  In the present embodiment, the amplitude values of the output signals from the CG memory chip enable output terminals GCE_0 and GCE_1 (specific terminals), which are preset by the sub-control circuit 200, differ depending on the type of CGROM (storage means). The amplitude value of the signal output from the CG memory chip enable output terminals GCE_0 and GCE_1 provided in the display control circuit 230 changes according to the type of the storage means. However, the mode in which the amplitude value of the output signal changes according to the type of the CGROM (storage unit) is not limited to this mode. As will be described in a modified example 7 described later, the display control circuit 230 detects the type of the connected storage means and, based on the detection result, changes the CG memory chip enable output terminals GCE_0 and GCE_1 (specific terminals). The amplitude value of the output signal may be set.

  The fifth connection terminal of the sub-board 202 to which the control terminal DIR of the bidirectional balance transceiver 301 is connected is grounded via the fifth connection terminal of the CGROM board 204a 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 204a on which the NOR type CGROM 206a is mounted is connected to the sub board 202, as shown in FIG. 15, the input / output terminals A0 to A3 of the bidirectional balance transceiver 301 are output terminals. The input / output terminals B0 to B3 act as input terminals. That is, the communication direction between the display control circuit 230 and the CGROM 206a in the bidirectional balance transceiver 301 is a direction from the display control circuit 230 to the CGROM 206a.

  In this case, signal wiring connected via the first to fourth connection terminals of the sub-board 202 and the first to fourth connection terminals of the CGROM board 204a can be used as an address bus, and display control can be performed. The circuit 230 can normally execute a memory addressing operation on the NOR-type CGROM 206a. As a result, the display control circuit 230 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) Next, a case where a CGROM board 204b on which a NAND CGROM 206b is mounted is connected (mounted) to the sub-board 202 will be considered.

  Also in this case, in the present 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 230. Is a LOW level signal. That is, in the present embodiment, a LOW level signal is input to the control terminal OE of the bidirectional balance transceiver 301 regardless of whether the type of the CGROM is the NOR type or the NAND type. As shown in FIG. 13, the fifth connection terminal of the sub-board 202 to which the control terminal DIR of the bidirectional balance transceiver 301 is connected is connected to the fifth connection terminal of the CGROM board 204b and the signal voltage W3 via the signal wiring W3. + 3.3V) terminal, a HIGH-level signal is input to the control terminal DIR.

  Therefore, when the CGROM board 204b on which the NAND type CGROM 206b is mounted is connected to the sub-board 202, as shown in FIG. 15, the input / output terminals A0 to A3 of the bidirectional balance transceiver 301 are used as input terminals. The input / output terminals B0 to B3 act as output terminals. That is, the communication direction between the display control circuit 230 and the CGROM 206b in the bidirectional balance transceiver 301 is a direction from the CGROM 206b to the display control circuit 230.

  In this case, the signal wiring connected via the first to fourth connection terminals of the sub-board 202 and the first to fourth connection terminals of the CGROM board 204b is used as the communication wiring for the ready / busy signal. Can be. That is, in this case, it is possible to execute a transmission process from the CGROM 206 to the display control circuit 230 of a ready / busy signal referred to by the display control circuit 230 when reading data from the NAND CGROM 206b by the sequential access method. As a result, the display control circuit 230 can normally execute the operation of acquiring the memory state (ready / busy state) for the NAND CGROM 206b.

  As described above, in the present embodiment, even if the type of the CGROM changes, the communication operation between the display control circuit 230 and the CGROM can be performed normally without changing the configuration of the sub-substrate 202. Therefore, in the present embodiment, an optimal CGROM can be selected in consideration of, for example, data capacity, communication speed, price, and the like. Also, for example, when manufacturing a new pachinko gaming machine 1, only the type of CGROM is changed by diverting the sub-board 202 used in the pachinko gaming machine manufactured in the past from conditions such as data capacity and communication speed. Can be easily dealt with. That is, in the pachinko gaming machine 1 of the present embodiment, the CGROM can be selected according to the embodiment, and the expandability of the pachinko gaming machine 1 can be secured.

  Further, in the present embodiment, by using the bidirectional balance transceiver 301, the first to fourth connection terminals in the terminal group 303 of the sub-board 202 and the first connection terminal in the terminal group 311 of the CGROM board 204 are used. The terminal to the fourth connection terminal can be used as data input / output terminals. In this case, there is no need to separately provide a data input terminal and a data output terminal corresponding to the first to fourth connection terminals of the sub-board 202 and the CGROM board 204. Can be achieved.

  As described above, in the present embodiment, the “communication mode” between the display control circuit 230 and the CGROM can be switched by the bidirectional balance transceiver 301 according to the type of the CGROM. However, the “communication form” between the display control circuit 230 and the CGROM as referred to in this specification means the overall transmission and reception of various information between the display control circuit 230 and the CGROM.

  For example, the “communication form” between the display control circuit 230 and the CGROM referred to in the present specification includes data (image data (compressed data of a moving image / still image) required when displaying information related to a staging operation on the display device 13. Not only the transmission / reception mode between the display control circuit 230 and the CGROM) but also the transmission / reception mode when information specifying the address of the data stored in the CGROM is communicated between the display control circuit 230 and the CGROM, and This also includes a transmission / reception mode when the control circuit 230 receives a ready / busy signal from the CGROM. Note that the present invention is not limited to this, and the “communication form” referred to in the present specification may mean only the communication form of a portion where the information transmission / reception mode changes according to the type of CGROM.

<Type of game state>
Next, the types of gaming states controlled and managed by the main CPU 71 will be described.

  In the present embodiment, the types of game states controlled and managed by the main CPU 71 are “big hit game state” (special game state) and “small hit game state” (specific game state) in which the degree of expectation of prize balls is different from each other. There is. The “big hit gaming state” is a gaming state in which a round game occurs in which the shutter opening period (that is, one round period) of the first big winning opening 53 or the second big winning opening 54 is long (for example, 30 sec), This is a game state in which a large prize ball can be expected for the player. That is, in the "big hit gaming state", the repeated state of the open state and the closed state of the shutter of the special winning opening is in a state more advantageous to the player.

  On the other hand, the “small hit gaming state” is a gaming state in which a round game occurs in which one round is shorter (for example, 1.8 sec) than the “big hit gaming state”, and a large prize ball cannot be expected for the player. It is a game state. That is, in the "small hitting game state", the repeated state of the open state and the closed state of the shutter of the big winning port is disadvantageous for the player.

  In the present embodiment, the types of game states controlled and managed by the main CPU 71 are “probable change game state” (high-probability game state) and “normal game state” (low Probability game state).

  The “probable change game state” is a game state in which the winning probability of “big hit” (1/131 in the present embodiment) is high. On the other hand, the “normal gaming state” is a gaming state in which the winning probability of “big hit” (1/392 in the present embodiment) is lower than the “probable changing gaming state”.

  Further, in the present embodiment, as a type of the game state controlled and managed by the main CPU 71, a normal symbol winning probability (a probability that the normal symbol becomes “hit”) is different from each other in “time-saving gaming state” (high). (A winning game state) and a "non-time saving game state" (a low winning game state).

  The "time reduction gaming state" in this specification is a gaming state in which the winning probability of a normal symbol is high. In other words, the “time-saving gaming state” is a gaming state in which the ordinary electric accessory 46 (blade member) provided in the second starting port 45 is likely to be opened (a gaming state in which the second starting port winning is likely to occur). , A game state that is advantageous for the player. The "time saving game state" ends when "big hit" is determined or when a special symbol variation display for a predetermined number of time savings described later is executed. Further, in the time-saving game state, as a fluctuation time which is a time for performing the fluctuation display of the special symbol executed during the state, a fluctuation time shorter than the fluctuation time selected during the normal game state is easily selected. It may be controlled. With such control, the variation time may be reduced in the time-saving gaming state compared to the normal gaming state, and the number of games per unit time may be increased to provide a gaming state advantageous to the player.

  On the other hand, the “non-time-saving (no time-saving) gaming state” is a gaming state in which the winning probability of a normal symbol is lower than the “time-saving gaming state”. Therefore, the “non-time-saving gaming state” is a gaming state in which the ordinary electric accessory 46 (blade member) is unlikely to be in an open state (a gaming state in which it is difficult for the second starting opening prize to occur), and is a disadvantageous game for the player. State.

  In the present embodiment, game states of various combinations of the above-described game states other than the “big hit game state” and the “small hit game state” are provided. Specifically, in the present embodiment, a game state in which a “probable change game state” and a “time saving game state” occur simultaneously (hereinafter, referred to as a “high-precision time reduction state”), and a “probable change game state” A game state in which the “non-time saving game state” and the “non-time saving game state” occur simultaneously is provided. Note that in the state of "high accuracy time saving no", it is difficult for the player to determine whether or not the game state is the "probable change game state". Also called. Further, in the present embodiment, a gaming state in which a “normal gaming state” and a “non-time saving gaming state” occur simultaneously (hereinafter, referred to as a “low accuracy time saving no state”), and a “normal gaming state” and a “time saving A game state in which the “game state” occurs at the same time (hereinafter, referred to as a “low-probability state”) is also provided.

<Configuration of data table stored in main ROM>
Next, the configuration of various data tables stored in the main ROM 72 of the main control circuit 70 will be described with reference to FIGS.

[Big hit random number determination table (at the time of winning the first opening)]
First, the big hit random number determination table (at the time of winning the first starting opening) will be described with reference to FIG. The big hit random number determination table (at the time of the first starting mouth winning) is based on the big hit determining random number value acquired when the game ball enters (wins) the first starting mouth 44, and the "big hit", "small hit" And a table which is referred to when any one of “losing” and “losing” is determined by lottery.

  The big hit determination random value is a random value for determining a lottery result performed at the time of starting opening winning, and more specifically, a lottery of a special symbol (a first special symbol and a second special symbol). This is a random value indicating the result. In the present embodiment, the random number for jackpot determination (the random number for lottery of a special symbol) is selected from 0 to 65535 (65536 types).

  In the present embodiment, when a game ball wins in the first starting port 44, one of “big hit”, “small hit” and “loss” is determined by lottery. Therefore, as shown in FIG. 16, in the big hit random number determination table (at the time of winning the first starting opening), for each value of the probability change flag (“0 (= off)” or “1 (= on)”), “ The range of the random numbers for the jackpot determination for which the winning of "big hit", "small hit" and "losing" is determined, and the corresponding judgment value data ("big hit judgment value data", "small hit judgment value data" And any one of “loss determination value data”). The probable change flag is one of the management flags stored in the main RAM 73, and is a flag for managing whether the game state is the “probable change game state”. When the game state is the “probable change game state”, the confirmation flag is “1”.

  In the present embodiment, as shown in FIG. 16, when the first starting port 44 wins, when the probability variable flag is “0” and the random number for jackpot determination is any of “777” to “943”, , "Big hit" is won, and "big hit determination value data" is determined. That is, the winning probability of “big hit” (“selection rate” in FIG. 16) in this case is 167/65536.

  If the probability variable flag is “0” and the big hit determination random number is one of “1” to “300” at the time of winning the first starting opening 44, “small hit” is won and “ Small hit determination value data "is determined. That is, the winning probability of “small hit” in this case is 300/65536.

  Further, when the first starting port 44 wins, the probability change flag is “0”, and if the random number for jackpot determination is not any of “1” to “300” or “777” to “943”, “losing” is performed. ”Is won, and“ losing determination value data ”is determined.

  On the other hand, if the probability change flag is “1” and the big hit determination random number is one of “777” to “1277” at the time of winning the first starting opening 44, as shown in FIG. "Is won, and" big hit determination value data "is determined. That is, in this case, the winning probability of “big hit” (“selection rate” in FIG. 16) is 500/65536, which is higher than that in the case where the probability change flag is “0”.

  In addition, when the first starting port 44 wins, if the probability variable flag is “1” and the random number for jackpot determination is any of “1” to “300”, “small hit” is won and “ Small hit determination value data "is determined. That is, the winning probability of “small hit” in this case is 300/65536, which is the same as that when the probability change flag is “0”.

  Furthermore, if the probability change flag is “1” at the time of winning the first starting opening 44 and the random number value for jackpot determination is not any of “1” to “300” or “777” to “1277”, “losing” is performed. ”Is won, and“ losing determination value data ”is determined.

  As described above, in the present embodiment, when a game ball wins in the first starting port 44, the selection rate (big hit probability) depends on whether or not the game state at the time of winning is the “probable change game state”. fluctuate. Specifically, the probability of a big hit when a gaming ball wins in the first starting port 44 when the gaming state is the “probably changing game state” is about three times that of when the gaming state is not the “probably changing game state”. Get higher.

[Big hit random number determination table (at the time of winning the second opening)]
Next, the big hit random number determination table (at the time of winning the second starting opening) will be described with reference to FIG. The big hit random number determination table (at the time of winning the second starting opening) is a lottery based on the big hit determining random value acquired when the game ball enters (wins) the second starting opening 45 or not. This is a table that is referred to when performing.

  In the present embodiment, when a game ball wins in the second starting port 45, one of "big hit" and "losing" is determined by lottery. If a game ball has won the second starting port 45, the "small hit" is not won. Therefore, in the big hit random number determination table (at the time of winning the second starting opening), as shown in FIG. 17, for each value of the probability change flag (“0 (= off)” or “1 (= on)”), “ Relationship between the range of the random number for jackpot determination for which each of the "big hit" and "losing" is determined and the corresponding determination value data (either "big hit determination value data" or "losing determination value data") Is defined.

  In the present embodiment, as shown in FIG. 17, when the second starting opening 45 wins, when the probability variable flag is “0” and the random number for jackpot determination is any of “777” to “943”, , "Big hit" is won, and "big hit determination value data" is determined. That is, the winning probability of “big hit” (“selection rate” in FIG. 17) in this case is 167/65536.

  If the probability change flag is “0” and the big hit determination random number is not any of “777” to “943” at the time of winning the second starting port 45, “losing” is won, and “losing determination” is performed. Value data "is determined.

  On the other hand, at the time of winning the second starting opening 45, if the probability variable flag is “1” and the random number for jackpot determination is any of “777” to “1277”, as shown in FIG. "Is won, and" big hit determination value data "is determined. That is, the winning probability (big hit probability) of “big hit” in this case is 500/65536, which is higher than that in the case where the probability change flag is “0”.

  If the probability change flag is “1” and the big hit determination random number is not any one of “777” to “1277” at the time of winning the second starting opening 45, the result is “losing” and “losing determination value data”. Is determined.

  As described above, in the present embodiment, even when a game ball wins in the second starting port 45, the selection rate (big hit probability) also depends on whether or not the game state at the time of winning is the “probable change game state”. Fluctuates. Specifically, similarly to the case of winning the first starting port 44, also at the time of winning the second starting port 45, when the game ball is won in the second starting port 45 when the gaming state is the “probable changing game state”. The jackpot probability is about three times higher than that when the game state is not the “probable change game state”.

[Symbol judgment table (at the time of winning the first opening)]
Next, the symbol determination table (at the time of winning the first opening) will be described with reference to FIG.

  In the present embodiment, the winning type (“big hit”, “small hit” or “losing”) of the lottery based on the random number value for big hit determination performed when a game ball wins in the first starting port 44, and the first start A special symbol is selected based on a symbol random number value (a symbol determining random number value) acquired at the time of winning a prize. The symbol determination table (at the time of winning the first opening) is a table that is referred to when the special symbol is selected. The symbol random value is a random value for determining a special symbol, and is selected from 0 to 99 (100 types) regardless of the winning type of the lottery based on the random number value for jackpot determination.

  As shown in FIG. 18, in the symbol determination table (at the time of winning the first starting opening), a symbol designating command for designating a special symbol for each determination value data indicating a winning type of a lottery based on the random number value for big hit determination. The relationship between (“zA1” to “zA3”) and the symbol random number value at which the symbol designation command is selected is defined.

  When the winning type of the lottery based on the random number value for the big hit determination is “small hit” (small hit determination value data), the symbol designation command to be selected is one type (zA2), and the symbol designation The command (zA2) is determined. Also, when the winning type of the lottery based on the big hit determination random number is “losing” (losing determination value data), the symbol designating command to be selected is one type (zA3), and the symbol designating command (zA3) is always required. zA3) is determined.

  On the other hand, when the winning type of the lottery based on the big hit determination random number is “big hit” (big hit determination value data), as shown in FIG. 18, there are a plurality of special symbol types to be selected, and “big hit” A plurality of types (“z0” to “z4”) are also prepared for the symbol designating command at the time (the symbol selecting command at the time of the big hit in FIG. 18). And at the time of "big hit", the big hit selection symbol command determined also changes according to the acquired symbol random number value. For example, when the symbol random number value acquired at the time of “big hit” is any of “40” to “59”, the big hit selection symbol command “z2” is selected, and the selection rate is 20/100. Become.

[Symbol judgment table (at the time of winning the second opening)]
Next, the symbol determination table (at the time of winning the second opening) will be described with reference to FIG.

  In the present embodiment, the winning type (“big hit” or “losing”) of the lottery based on the random number for big hit determination performed when a game ball wins in the second starting port 45, and the winning type obtained at the time of the second starting port winning. The special symbol is selected based on the symbol random number value (the random number value for symbol determination). The symbol determination table (at the time of winning the second opening) is a table that is referred to when the special symbol is selected.

  As shown in FIG. 19, in the symbol determination table (at the time of winning the second starting opening), a symbol designating command for designating a special symbol for each determination value data indicating a winning type of a lottery based on the random number value for big hit determination. The relationship between (“zA1” and “zA3”) and the symbol random number value at which the symbol designation command is selected is defined.

  In addition, even when the winning type of the lottery based on the random number value for jackpot determination is “losing” (losing determination value data), the symbol designating command to be selected is one type (zA3), and the symbol designating command (zA3) is always required. zA3) is determined.

  On the other hand, when the winning type of the lottery based on the random number value for the jackpot determination is “big hit” (big hit determination value data), as shown in FIG. 19, there are a plurality of types of special symbols to be selected, and “big hit” A plurality of types (“z0” and “z4”) are also prepared for the symbol design command at the time (the symbol design command at the time of big hit in FIG. 19). And at the time of "big hit", the big hit selection symbol command determined also changes according to the acquired symbol random number value. For example, when the symbol random number value acquired at the time of “big hit” is any of “29” to “99”, the big hit selection symbol command “z4” is selected, and the selection rate is 80/100. Become.

[Big hit type determination table]
Next, the big hit type determination table will be described with reference to FIGS. In the present embodiment, when the big hit selection symbol command (any one of “z0” to “z4”) is determined with reference to the symbol determination table (see FIGS. 18 and 19), the determined big hit selection is performed. Based on the symbol command, the type of “big hit” (the content of the big hit game) is determined. The big hit type determination table is a table that is referred to when determining the type of “big hit” (contents of the big hit game) based on the big hit selection symbol command.

  In the present embodiment, a big hit type determination table is provided for each game state at the time of "big hit" winning. FIG. 20 is a jackpot type determination table (1) which is referred to when a “big hit” is won when the gaming state is “low probability time saving”, and FIG. 21 is a gaming state “low probability time saving”. It is a big hit type determination table (No. 2) which is referred to when "big hit" is won when "Yes". FIG. 22 is a big hit type determination table (3) which is referred to when a “big hit” is won when the gaming state is “high accuracy time saving”, and FIG. It is a jackpot type determination table (No. 4) which is referred to when a "big hit" is won when "sure time is short".

  In each big hit type determination table, the relationship between the big hit selection symbol commands ("z0" to "z4") and various parameters for determining the type of "big hit" is defined. As the various parameters for determining the type of “big hit” (contents of the big hit game), the value of the time saving flag, the number of time savings, the value of the probability change flag, and the number of rounds in the big hit game are defined.

  For example, when the "big hit" is won in the state of "high accuracy time reduction" and "z1" is determined as the big hit selection symbol command, as shown in FIG. As the various parameters for determining the big hit game), the time saving flag “1”, the number of time savings “100”, the probability variable flag “0”, and the number of rounds “10” are set.

  The “number of rounds” defined in each of the jackpot type determination tables is the number of rounds in which the opening time of the special winning opening is relatively long in the big hit game. The "time reduction flag" is one of the management flags stored in the main RAM 73, and is a flag for managing whether or not the gaming state is the "time reduction gaming state". When the game state is the "time reduction game state", the time reduction flag is set to "1 (on)". Further, the “time saving number of times” is the number of times the special symbol is fluctuated and displayed in the “time saving game state”.

[Winning prize production information decision table]
Next, the winning effect information determination table will be described with reference to FIG.

  In the present embodiment, the main control circuit 70 (main CPU 71) determines the winning type ("big hit", "small hit" or "losing") determined at the time of winning (at the time of starting opening winning), a symbol designation command or a big hit. Based on the time-selection symbol command, the sub-control circuit 200 determines information to be used when determining the effect contents. For example, in the sub-control circuit 200, information used when determining the content related to the color change effect of the holding symbol indicating the holding ball of the special symbol, the content related to the look-ahead effect, and the like is determined. The winning effect information determination table is referred to when determining the outline of the effect content executed by the sub-control circuit 200 based on the information acquired by the main control circuit 70 at the time of winning (at the time of starting opening winning). It is a table.

  The prize-winning effect information determination table includes “winning-time effect information 1” and “winning-time effect information 1” indicating an outline of the effect contents executed by the sub-control circuit 200, as well as a combination of various types of information determined at the time of prize (start-up opening prize). The relationship with "prize-winning effect information 2" is defined. In the present embodiment, the various types of information determined at the time of winning (at the time of starting opening winning) include the type of starting opening, the type of determination value data, the type of the symbol pattern selected at the time of the big hit, and the type of the symbol designating command. It is defined in the time effect information determination table.

  The prize effect information 1 (“1A” to “1D”) defined in the prize effect information determination table is mainly used by the sub control circuit 200 to change the color of the holding symbol indicating a special symbol holding ball. This is production information used when deciding the contents regarding. When the sub-control circuit 200 receives the prize effect information 1 determined based on the prize effect information determination table, the sub-control circuit 200 causes the color change effect of the holding symbol included in the classification of the prize effect information 1. One effect pattern is selected from a plurality of effect patterns related to.

  The prize-winning effect information 2 (“2A” to “2D”) specified in the prize-winning effect information determination table is mainly processed by the sub-control circuit 200 in a pre-reading effect (pre-reading continuous This is production information used when deciding the contents related to production. When the sub-control circuit 200 receives the prize effect information 2 determined based on the prize effect information determination table, the sub-control circuit 200 generates a plurality of types of pre-reading effects included in the classification of the prize effect information 2. One effect pattern is selected from the patterns.

  When the prize-winning effect information determination table of the present embodiment is referred to, for example, when “big hit” is won at the time of winning the first starting opening, “1A” is obtained as prize-winning effect information 1 regardless of the type of the big hit selection symbol command. Is determined, and “2A” is determined as the prize effect information 2.

[Variation effect pattern determination table]
Next, the variation effect pattern determination table will be described with reference to FIG.

  In the present embodiment, the main control circuit 70 (main CPU 71), at the start of the variable display of the special symbol, the winning type ("big hit", "small hit" or "losing"), symbol design command, big hit selection symbol command, Based on information such as the fluctuation time, the fluctuation effect pattern of the special symbol is determined. The variation effect pattern determination table is a table that is referred to when determining the variation effect pattern of the special symbol.

  The variable effect pattern (information included in a special symbol effect start command described later) determined based on the variable effect pattern determination table is transmitted from the main control circuit 70 to the sub control circuit 200 (host control circuit 210). . Then, upon receiving the information on the variable effect pattern, the sub-control circuit 200 determines the type of the effect based on the received information on the variable effect pattern and the game state.

  As shown in FIG. 25, in the variation effect pattern determination table, a combination of a symbol designation command, a big hit selection symbol command, a variation time of a special symbol, and a variation display of a special symbol determined at the time of winning (starting opening winning). The relationship with the type of effect performed by the sub-control circuit 200 (variable effect pattern) is defined therein.

  In the present embodiment, the variable effect pattern is represented by a two-digit number, and the “higher” (first digit) parameter and the “lower” (second digit) described in the variable effect pattern column in FIG. Expressed in combination with parameters. For example, a fluctuation effect in a case where the symbol designating command determined at the time of winning (at the time of starting opening winning) is “zA1”, the big hit selecting symbol command is “z0”, and the fluctuation time of the special symbol is “15000 msec”. The parameter is “C1” (combination of upper “C” and lower “1”).

  In the present embodiment, the information of the variable effect parameter is included in a special symbol effect start command described later. At this time, the “upper” parameter and the “lower” parameter defined in the fluctuation effect pattern column are stored in different parameter areas. Therefore, in the variation effect pattern determination table, the “upper” parameter and the “lower” parameter of the variation effect pattern are separately defined.

<Configuration of Data Table Stored in Sub Main ROM>
Next, the configuration of various data tables stored in the sub main ROM 205 of the sub control circuit 200 will be described with reference to FIGS.

[Variable production table]
First, the fluctuation effect table will be described with reference to FIG.

  In the pachinko gaming machine 1 of the present embodiment, as described above, under the control of the sub-control circuit 200 (host control circuit 210), various effects are executed during the variable display of the special symbol. At this time, the effect (effect pattern) of the effect performed at the time of the start of the fluctuation display of the special symbol is a fluctuation effect of the special symbol included in a later-described special symbol effect start command transmitted from the main control circuit 70 to the sub-control circuit 200. It is determined based on information on the pattern. The variable effect table is referred to when determining the effect contents (effect pattern) based on information such as the variable effect pattern and the game state.

  As shown in FIG. 26, the variable effect table includes a combination of various information (including information on the variable effect pattern) determined at the time of winning (starting port winning) and an effect pattern determined by lottery (“EN00”). "To" EN44 ") and the effect contents, the random number value for selecting (determining) each effect pattern, and the selection ratio (winning probability) are defined. In the present embodiment, as the various information determined at the time of winning (at the time of starting opening winning), the types (“A0” to “A4”, “B1” to “B3”, and “C1”) of the fluctuation design patterns of the special symbols are used. "-" CF "), the special symbol fluctuation time, the winning type (" big hit "," small hit "or" losing "), the symbol designation command, and the big hit selection symbol command are defined in the fluctuation effect table.

  In the present embodiment, it is assumed that the variation time of the special symbol specified in the variation effect table is substantially the same as the effect time of the corresponding effect pattern. The random number value specified in the fluctuation effect table is a random number value obtained in the process of S319 (sub-lottery process) in the command analysis process shown in FIG. 90 described later, and is “0” to “999” ( 1000 types).

  When determining an effect pattern with reference to the variable effect table of the present embodiment, for example, when the change pattern of the special symbol determined at the start of the special symbol change display is “C1” and the effect pattern is selected. Is "0" to "499", "EN15" is selected as the effect pattern. In this case, an effect called “normal reach effect A” is performed during the special symbol change display period (15000 msec). When the "normal reach effect A" ends, the "big hit" mode is displayed on the display area 13a of the display device 13, and the special symbol stops changing.

[Pending production table]
Next, with reference to FIG. 27, the hold effect table will be described.

  In the pachinko gaming machine 1 of the present embodiment, various effects relating to the color change of the symbol for holding indicating the holding ball of the special symbol are executed under the control of the sub control circuit 200 (host control circuit 210). The content (effect pattern) of the color change effect of the symbol for hold performed at this time is a prize included in a hold addition command described later transmitted from the main control circuit 70 to the sub-control circuit 200 at the start of the variation display of the special symbol. It is determined based on the time effect information 1 (“1A” to “1D”). The hold effect table is referred to when the content (effect pattern) of the color change effect of the holding symbol is determined based on information such as the winning effect information 1.

  As shown in FIG. 27, the hold effect table includes a combination of various information (including the effect information 1 at the time of winning) determined at the time of winning (starting time winning), and the color of the symbol for holding determined by lottery. The correspondence relationship between the effect patterns (“HE00” to “HE19”) of the change effect and the effect contents, the random value for selecting (determining) each effect pattern, and the selection rate (winning probability) is defined. In the present embodiment, as the various information determined at the time of winning (at the time of starting opening winning), at-winning effect information 1 (“1A” to “1D”), a winning type (“big hit”, “small hit” or “Loss”), a symbol designation command and a big hit selection symbol command are defined in the holding effect table. The random number value specified in the hold effect table is a random number value obtained in the process of S319 (sub-lottery process) in the command analysis process shown in FIG. 90 described later, and is “0” to “999” ( 1000 types).

  When determining the effect pattern of the color change effect of the symbol for hold with reference to the hold effect table of the present embodiment, for example, the prize-winning effect information 1 determined at the start of the fluctuation display of the special symbol is “1A”, If the big hit selection symbol command is “z0” and the random number value obtained when selecting the effect pattern is any one of “0” to “499”, the color of the symbol for holding “HE00” is selected as the effect pattern of the change effect. In this case, an effect called “holding effect A” is performed as the color change effect of the symbol for holding.

[Pre-reading production table]
Next, the look-ahead effect table will be described with reference to FIG.

  In the pachinko gaming machine 1 according to the present embodiment, when the variable display of the special symbol is suspended, the sub-control circuit 200 (host control circuit 210) changes the content of the variable display of the retained special symbol (the content of the reserved ball). A predetermined look-ahead effect is performed according to (contents). At this time, the contents of the look-ahead effect (effect pattern) performed at the time of the start of the fluctuation display of the special symbol include the prize-winning effect information 2 ( "2A" to "2D"). The look-ahead effect table is referred to when the content (effect pattern) of the pre-read effect is determined based on information such as winning effect information 2.

  As shown in FIG. 28, in the look-ahead effect table, a combination of various information (including the effect information 2 at the time of winning) determined at the time of winning (start-up opening winning) and the effect pattern of the look-ahead effect determined by lottery (“SE00” to “SE19”) and the correspondence between the effect contents, the random value for selecting (determining) each effect pattern, and the selection rate (winning probability) are defined. In the present embodiment, as the various information determined at the time of winning (at the time of starting opening winning), at-time information 2 (“2A” to “2D”), winning type (“big hit”, “small hit” or “Loss”), a symbol designating command and a big hit selected symbol command are defined in the look-ahead effect table. The random number value specified in the look-ahead effect table is a random number value obtained in the process of S319 (sub-lottery process) in the command analysis process shown in FIG. 90 described later, and is “0” to “999” ( 1000 types).

  When determining the effect pattern of the look-ahead effect with reference to the look-ahead effect table of the present embodiment, for example, the prize-winning effect information 2 determined at the time of starting the fluctuation display of the special symbol is “2A”, and the big hit selection symbol command Is “z0”, and the random number value obtained when selecting the effect pattern is any value from “0” to “499”, “SE00” is the effect pattern of the look-ahead effect. Selected. In this case, an effect called “prefetch effect A” is performed as the prefetch effect.

<Configuration of various commands>
Here, the configuration of various commands transmitted from the main control circuit 70 to the sub control circuit 200 will be described. In the present embodiment, the main control circuit 70 also functions as a unit (command transmission unit, game information transmission unit) that generates a command including information on the progress of the game and transmits the command data to the sub control circuit 200. .

[Basic configuration]
First, the basic configuration of the command will be described with reference to FIG. FIG. 29 is a diagram showing a basic configuration (basic format) of command data.

  In the present embodiment, the command transmitted from the main control circuit 70 to the sub control circuit 200 is composed of a command type section storing information of the command type, and a parameter field section storing various information on games and effects. Is done. In the present embodiment, the information in the parameter field portion is analyzed by the later-described command analysis process executed in the sub-control circuit 200, and various information related to the game and the effect is obtained.

  The command type part is provided at the head of the command, and is composed of 8 bits (1 byte: fixed length). On the other hand, in the parameter field portion, information on games and effects is defined in bit units, and the bit length (length) of the parameter field portion changes according to the command type.

  In the present embodiment, since the command transmission / reception operation is repeatedly performed in units of 8 bits, the parameter field portion is also managed in units of 8 bits. Here, the area in units of 8 bits is referred to as a “parameter”. Also, the names of the parameters arranged in the parameter field portion are referred to as “first parameter”, “second parameter”, “third parameter”,... From the head of the command (command type portion side).

  Hereinafter, as examples of the command, the configuration of the demonstration display command, the special symbol effect start command, the power interruption return command and the hold addition command, and the contents of various information included in these commands will be specifically described with reference to the drawings. explain.

[Demo display command]
First, the configuration of the demonstration display command and the contents of various information included in the command will be described with reference to FIG. FIG. 30 is a diagram showing a bit-by-bit configuration of the demo display command and the contents of various information stored in each bit.

  The demonstration display command includes a command type section and a parameter field section including one parameter (first parameter). That is, the number of bytes (command length) of the entire demo display command is 2 bytes (16 bits), and the number of bytes of the parameter field portion is 1 byte (8 bits).

  A value “80H” indicating the type of the demo display command is stored in the command type portion of the demo display command.

  Bits 0 (b0) to 2 (b2) of the first parameter of the demonstration display command store a "state number" (any one of 0 to 7) corresponding to a gaming state. For example, if the value of the probable change flag is “0” and the value of the time reduction flag is “0”, any of “0” to “2” among “0” to “7” is used as the “state number”. Is set in bits 0 (b0) to 2 (b2). Bit 4 (b4) and bit 5 (b5) of the first parameter store the value of the time saving flag ("0" or "1") and the value of the probable change flag ("0" or "1"), respectively. . Further, data “0” is always stored in each of bit 3 (b3), bit 6 (b6), and bit 7 (b7) of the first parameter. In the following, a bit in which data “0” is always stored is also referred to as “always 0 area”.

  In the sub-control circuit 200, when the below-described command analysis processing is performed on the demonstration display command having the above configuration, game state information (game status) at the time of the demonstration screen display is obtained from the first parameter as an analysis result.

[Special design effect start command]
Next, the configuration of the special symbol effect start command and the contents of various information included in the command will be described with reference to FIG. FIG. 31 is a diagram showing a bit structure of the special symbol effect start command and contents of various information stored in each bit.

  The special symbol effect start command includes a command type portion and a parameter field portion including five parameters (first parameter to fifth parameter). That is, the total number of bytes of the special symbol effect start command is 6 bytes (48 bits), and the number of bytes of the parameter field portion is 5 bytes (40 bits).

  The command type part of the special symbol effect start command stores a value “81H” indicating the type of the special symbol effect start command.

  A “state number” (any of 0 to 7) corresponding to the gaming state is stored in bits 0 to 2 of the first parameter of the special symbol effect start command. Bit 4 and bit 5 of the first parameter store the value of the time reduction flag ("0" or "1") and the value of the probability variable flag ("0" or "1"), respectively.

  Bit 6 of the first parameter stores information on the winning / non-winning of the falling lottery (“falling lottery success / failure information”). In the case of non-winning in the drop lottery, "0" is stored in the bit 6 of the first parameter as "fall lottery information", and in the case of winning in the fall lottery, "0" "1" is stored in bit 6 of the first parameter. Bits 3 and 7 of the first parameter are always in the 0 area.

  Bit 0 to bit 6 of the second parameter of the special symbol effect start command include symbol designating commands (“zA1” to “zA3”) determined by lottery using the symbol determination table (see FIGS. 18 and 19). Is stored. Note that bit 7 of the second parameter is always in the 0 area.

  Bits 0 to 3 of the third parameter of the special symbol effect start command include information (“A”) of “upper” of the variable effect pattern determined by lottery using the variable effect pattern determination table (see FIG. 25). To “C”) are stored. Note that bits 4 to 7 of the third parameter are “always 0 area”.

  Bits 0 to 3 of the fourth parameter of the special symbol effect start command include “lower” information (“0”) of the variable effect pattern determined by lottery using the variable effect pattern determination table (see FIG. 25). To “9” and “A” to “F”) are stored. Note that bits 4 to 7 of the fourth parameter are “always 0 area”.

  Further, in bits 0 to 6 of the fifth parameter of the special symbol effect start command, a value corresponding to the number of remaining time saving changes is stored. Note that bit 7 of the fifth parameter is always in the 0 area.

  In the sub-control circuit 200, when a command analysis process described later is performed on the special symbol effect start command having the above configuration, game state information (game status) at the start of the special symbol effect is obtained from the first parameter as an analysis result. Then, the stop symbol designating information of the special symbol is acquired from the second parameter, the designating information of the variation effect pattern number is acquired from the third parameter and the fourth parameter, and the designating information of the number of remaining time-saving variations is acquired from the fifth parameter. You.

[Power-off reset command]
Next, the configuration of the power interruption recovery command and the contents of various information included in the command will be described with reference to FIGS. 32 and 33. In the present embodiment, the power interruption recovery command is configured by a set of two commands (a first power interruption recovery command and a second power interruption recovery command). FIG. 32 is a diagram illustrating a bit-by-bit configuration of the first power interruption recovery command and the contents of various information stored in each bit. FIG. 33 is a diagram showing a bit-by-bit configuration of the second power interruption recovery command and the contents of various information stored in each bit.

(1) First Power Loss Return Command As shown in FIG. 32, the first power failure recovery command is composed of a command type part and a parameter field part including three parameters (first parameter to third parameter). You. That is, the total number of bytes of the first power-off command is 4 bytes (32 bits), and the number of bytes of the parameter field portion is 3 bytes (24 bits).

  A value “D1H” indicating the type of the first power failure return command is stored in the command type part of the first power failure return command.

  A “state number” (any of 0 to 7) corresponding to the gaming state is stored in bits 0 to 2 of the first parameter of the first power interruption return command. Bit 4 and bit 5 of the first parameter store the value of the time reduction flag ("0" or "1") and the value of the probability variable flag ("0" or "1"), respectively. Bit 6 of the first parameter stores “falling lottery success / failure information”. Note that bits 3 and 7 of the first parameter are always 0 areas.

  Bits 0 to 5 of the second parameter of the first power-off reset command store special symbol stop designating information (“special stop designating information”). In the bit 6 of the second parameter, a value (“0” or “1”) corresponding to the selected state of the stop symbol of the first special symbol (“first special stop symbol selection state”) at the time of detecting the power failure. Is stored. It should be noted that, in the latest special symbol change display (the latest executed change display among the change displays performed at the time of power failure detection and before the power failure detection), the stop symbol of the first special symbol is selected. For example, the value of the “first special symbol selection state” is “1”, and if the stop symbol of the first special symbol is not selected, the value of the “first special symbol selection state” is “0”. Bit 7 of the second parameter is always in the 0 area.

  "Special stop symbol designation information" is stored in bits 0 to 5 of the third parameter of the first power interruption return command. In the bit 6 of the third parameter, a value (“0” or “1”) corresponding to the selection state of the stop symbol of the second special symbol (“second special stop symbol selection state”) at the time of power interruption detection. Is stored. It should be noted that, in the latest special symbol change display (the latest executed change display among the change displays executed at the time of power cut detection and before the power cut detection), the stop symbol of the second special symbol is selected. For example, the value of the “second special stop symbol selection state” is “1”, and if the stop symbol of the second special symbol is not selected, the value of the “second special symbol selection state” is “0”. Bit 7 of the third parameter is always in the 0 area.

  In the sub-control circuit 200, when a command analysis process described later is performed on the first power interruption return command having the above configuration, game state information (game status) at the time of power interruption recovery is obtained from the first parameter as an analysis result. Then, the information of the stop symbol of the first special symbol at the time of the recovery from the power failure is obtained from the second parameter, and the information of the stop symbol of the second special symbol at the time of the recovery from the power failure is obtained from the third parameter.

(2) Second Power Loss Return Command As shown in FIG. 33, the second power failure recovery command is composed of a command type part and a parameter field part including three parameters (first parameter to third parameter). You. That is, the total number of bytes of the second power-off recovery command is 4 bytes (32 bits), and the number of bytes of the parameter field portion is 3 bytes (24 bits).

  A value “D2H” indicating the type of the second power failure return command is stored in the command type part of the second power failure return command.

  In bits 0 to 2 of the first parameter of the second power-off reset command, a value corresponding to the number of variable display reservations of the second special symbol is stored. Bits 4 to 6 of the first parameter store values corresponding to the number of variable display reservations of the first special symbol. In addition, bits 3 and 7 of the first parameter are always 0 areas.

  In addition, “000” is stored in the first parameter of the second power interruption return command in bits 0 to 2 or bits 4 to 6 when the number of reserved items is 0, and when the number of reserved items is 1, Stores “001”, “010” is stored when the number of reservations is two, “011” is stored when the number of reservations is three, and “100” is stored.

  “Internal control state number” is stored in bits 0 to 2 of the second parameter of the second power-off recovery command. Bits 3 to 7 of the second parameter are always in the 0 area.

  When the internal control state is the demonstration screen display state, “000” is stored as “internal control state number” in bits 0 to 2 of the second parameter of the second power-off reset command. When the state is the special symbol change state (special symbol change state), “001” is stored as the “internal control state number”, and when the internal control state is the special symbol fixed state, “010” is stored. When the internal control state is the special symbol start state, “011” is stored as the “internal control state number”. When the internal control state is the special winning opening state, “100” is stored as “internal control state number” in bits 0 to 2 of the second parameter of the second power-off reset command. If the control state is the inter-round interval state, “101” is stored as the “internal control state number”, and if the internal control state is the end state per special symbol, “110” is the “internal control state number”. Is stored as

  In addition, in the bits 0 to 6 of the third parameter of the second power interruption recovery command, “the number of remaining time saving state changes” (“0” to “99”) is stored. Bit 7 of the third parameter is always in the 0 area.

  In the sub-control circuit 200, when the later-described command analysis processing is performed on the second power interruption return command having the above-described configuration, the analysis result indicates the number of suspended special display variable display numbers at the time of power interruption recovery from the first parameter. Information is acquired, information on the internal state at the time of power failure recovery is obtained from the second parameter, and information on the number of remaining time fluctuations at the time of power recovery is obtained from the third parameter.

[Hold addition command]
Next, the configuration of the hold addition command and the contents of various information included in the command will be described with reference to FIG. FIG. 34 is a diagram showing a bit-by-bit configuration of the hold addition command and the contents of various information stored in each bit.

  The hold addition command includes a command type section and a parameter field section including three parameters (first parameter to third parameter). That is, the total number of bytes of the pending addition command is 4 bytes (32 bits), and the number of bytes of the parameter field portion is 3 bytes (24 bits).

  A value “85H” indicating the type of the hold addition command is stored in the command type part of the hold addition command.

  In bits 0 to 2 of the first parameter of the hold addition command, a value corresponding to the number of holds of the variable display of the second special symbol is stored. Bits 4 to 6 of the first parameter store values corresponding to the number of variable display reservations of the first special symbol. In addition, bits 3 and 7 of the first parameter are always 0 areas.

  "Big hit selection symbol information" is stored in bits 0 to 2 of the second parameter of the hold addition command. The “big hit selection symbol information” is information corresponding to the big hit selection symbol commands (“z0” to “z4”) determined by lottery using the above-described symbol determination table (see FIGS. 18 and 19). is there.

  In bit 3 of the second parameter, “low probability big hit hit / fail information” is stored. In addition, when the "big hit" is won in the low probability, "1" is stored in the bit 3 as "low probability big hit success / failure information", and when the "losing" is won in the low probability, the "low probability" is won. “0” is stored in bit 3 as “big hit success / failure information”. Bit 4 of the second parameter stores “high-probability jackpot success / failure information”. In addition, in the case of winning the "big hit" at the time of high accuracy, "1" is stored in bit 4 as "high probability big hit success / failure information". “0” is stored in bit 4 as “big hit hit information”. These pieces of information are determined based on the result of the lottery used in the big hit type determination table (see FIGS. 20 to 23).

  Bits 5 and 6 of the second parameter store “first winning effect information”. The “first prize production information” is information corresponding to prize production information 1 (“1A” to “1D”) determined by lottery using the prize production information determination table (see FIG. 24). It is. For example, when the winning effect information 1 is “1A”, “00” is stored in bits 5 and 6 as “first winning effect information”, and the winning effect information 1 is “1B”. In this case, “01” is stored in bit 5 and bit 6 as “first winning effect information”. Further, for example, when the winning effect information 1 is “1C”, “10” is stored in bits 5 and 6 as “first winning effect information”, and the winning effect information 1 is “1D”. In the case of “11,” “11” is stored in the bit 5 and the bit 6 as “first winning effect information”. Bit 7 of the second parameter is always in the 0 area.

  In the bits 4 and 5 of the third parameter of the hold addition command, “second winning effect information” is stored. The “second prize production information” is information corresponding to prize production information 2 (“2A” to “2D”) determined by lottery using the prize production information determination table (see FIG. 24). It is. For example, when the winning effect information 2 is “2A”, “00” is stored in bits 4 and 5 as “second winning effect information”, and the winning effect information 2 is “2B”. In this case, “01” is stored in the bit 4 and the bit 5 as “second winning effect information”. Further, for example, when the winning effect information 2 is “2C”, “10” is stored in bits 4 and 5 as “second winning effect information”, and the winning effect information 2 is “2D”. In the case of, “11” is stored in the bit 4 and the bit 5 as “second winning effect information”.

  Note that the values of the “first prize effect information” and the “second prize effect information” are executed based on the look-ahead information (information on the hold before the change) when the hold addition command is generated (at the time of hold addition). May be changed (updated) in accordance with the number of effects (the number of pending executions of the prefetch effect).

  Bit 6 of the third parameter stores “falling lottery information”. If no fall, “0” is stored in bit 6 as “fall lottery information”, and if there is a fall, “1” is stored in bit 6 as “fall lottery information”. Also, each of the bits 0 to 3 and bit 7 of the third parameter is always in the 0 area.

  In the sub-control circuit 200, when a command analysis process described later is performed on the hold addition command having the above-described configuration, information on the number of holds for variable display of a special symbol at the time of winning from the first parameter is obtained as an analysis result, The designation information of the reserved effect is acquired from the second parameter, and the designation information of the prefetch effect is acquired from the third parameter.

[Other commands]
Next, the configuration of commands other than the various commands described above and the contents of various information included in the commands will be described. Here, the illustration of the configuration of other various commands is omitted, and only the configuration of the parameter field portion in each command and the outline of various information included in the command will be described.

(1) Special effect stop command The parameter field portion of the special effect stop command is composed of two parameters (a first parameter and a second parameter).

  The first parameter of the special effect stop command stores, for example, game state information (game status) such as a drop lottery, a probability change flag, a time saving flag, and a state number. In addition, the information of the stop symbol of the special symbol is stored in the second parameter.

  In the sub-control circuit 200, when a command analysis process described later is performed on the special effect stop command having the above-described configuration, as a result of the analysis, when the effect at the time of the special symbol change display from the first parameter and the second parameter is ended. Are obtained.

(2) Special Symbol Start Display Command The parameter field portion of the special symbol start display command includes two parameters (a first parameter and a second parameter).

  In the first parameter of the special symbol hit start display command, for example, game state information (game status) such as a state number is stored. In addition, the information of the stop symbol of the special symbol is stored in the second parameter.

  In the sub-control circuit 200, when a command analysis process described later is performed on the special symbol hit start display command having the above-described configuration, information on the special symbol hit state (for example, Information such as whether or not a big hit is being made and whether or not a small hit is being made are acquired.

(3) Big Win Opening Display Command The parameter field portion of the big win opening display command is composed of three parameters (first parameter to third parameter).

  For example, game state information (game status) such as a state number is stored in the first parameter of the large winning opening opening command. In the second parameter, information of a special symbol stopped symbol is stored. Further, information on the number of rounds (“0” to “15”) is stored in the third parameter.

  In the sub-control circuit 200, when a command analyzing process described later is performed on the special winning opening opening command having the above configuration, information on a special symbol hit state is obtained from the first parameter and the second parameter as an analysis result. Then, information on the number of rounds is obtained from the third parameter.

(4) Inter-round display command The parameter field portion of the inter-round display command is composed of three parameters (first parameter to third parameter).

  In the first parameter of the display command between rounds, for example, game state information (game status) such as a state number is stored. In the second parameter, information of a special symbol stopped symbol is stored. The third parameter stores information on the number of rounds ("0" to "14").

  In the sub-control circuit 200, when a later-described command analysis process is performed on the inter-round display command having the above-described configuration, information on a special symbol hit state is acquired from the first parameter and the second parameter as an analysis result. Information on the number of rounds is obtained from the three parameters.

(5) Special symbol end display command The parameter field portion of the special symbol end display command is composed of two parameters (a first parameter and a second parameter).

  In the first parameter of the special symbol hit end display command, for example, game state information (game status) such as a state number is stored. In addition, the information of the stop symbol of the special symbol is stored in the second parameter.

  In the sub control circuit 200, when a command analysis process described later is performed on the special symbol hit end display command having the above configuration, information on the special symbol hit state from the first parameter and the second parameter is obtained as an analysis result. You.

(6) Hold Subtraction Command The parameter field portion of the hold subtraction command is composed of three parameters (first parameter to third parameter).

  The first parameter of the hold subtraction command stores, for example, game state information (game status) such as a drop lottery, a probability change flag, a time saving flag, and a state number. In the second parameter, information on the number of suspended special symbols in variable display is stored. In the third parameter, information on the number of remaining time-saving games is stored.

  In the sub-control circuit 200, when a command analysis process described later is performed on the hold subtraction command having the above-described configuration, information on the game state at the start of the variation is obtained from the first parameter as an analysis result, and the variation is obtained from the second parameter. Information on the number of suspended games at the start is obtained, and information on the number of remaining time-saving games is obtained from the third parameter.

(7) Winning Information Command The parameter field portion of the winning information command is composed of one parameter (first parameter).

  In the first parameter of the winning information command, for example, winning detecting information such as a detection result of the count sensors 53c and 54c is stored.

  In the sub-control circuit 200, when the below-described command analysis processing is performed on the winning information command having the above-described configuration, winning detection information on the special winning opening is obtained from the first parameter as an analysis result.

(8) Fraud Detection Related Command The parameter field part of the fraud detection related command is composed of two parameters (a first parameter and a second parameter).

  The first parameter of the fraud detection-related command includes, for example, door open detection (open / closed non-detection, close detection, and open detection), unauthorized win detection of the first big winning opening, illegal winning detection of the second big winning opening, and ordinary electric power. Information such as the detection of unauthorized winning of the accessory is stored. The second parameter stores information such as induction magnetic field detection, magnetic detection, and sensor abnormality detection.

  In the sub-control circuit 200, when a command analysis process described later is performed on the fraud detection-related command having the above configuration, fraud detection information is obtained from the first parameter and the second parameter as a result of the analysis.

(9) Dispensing abnormality related command The parameter field part of the dispensing abnormality related command is composed of one parameter (first parameter).

  In the first parameter of the dispensing abnormality related command, for example, information such as dispensing error information and lower plate full information is stored.

  In the sub-control circuit 200, when a command analysis process described below is performed on the dispensing abnormality related command having the above configuration, dispensing abnormality information is obtained from the first parameter as an analysis result.

(10) Initialization Command The parameter field of the initialization command is composed of one parameter (first parameter).

  In the first parameter of the initialization command, for example, information on an initialization factor at the time of power-on such as when a checksum is abnormal, power-off is recovered when power-off is not detected, and backup clear is pressed is stored.

  In the sub-control circuit 200, when the below-described command analysis processing is performed on the initialization command having the above-described configuration, the specification information of the initialization factor is obtained from the first parameter as an analysis result.

<Overview of command reception processing and command analysis processing>
Next, an outline of a command reception process and a command analysis process performed by the host control circuit 210 when receiving the various commands described above will be described with reference to FIG. FIG. 35 is a diagram illustrating an outline of a command receiving process according to the present embodiment. This command reception process is performed as a reception interrupt process in a main / sub command control process (see FIG. 79 described later) executed by the host control circuit 210.

  In this embodiment, as shown in FIG. 35, when the above-described command is transmitted from the main control circuit 70 (main CPU 71) to the host control circuit 210, and the command is received by the host control circuit 210, first, the host control circuit 210 Writes the data of the received command into a ring buffer provided in the host control circuit 210. If an error occurs during command reception, the set information of the received command data and error information is written to the ring buffer.

  Here, FIG. 36 shows a schematic configuration of the ring buffer. In the present embodiment, the ring buffer includes a buffer area for storing received command data and a buffer area for storing corresponding error information. The size of each buffer area is 2048 bytes, and addresses ("0" to "2047") are assigned to each 1-byte storage area.

  In the buffer area for storing command data, command data is stored for each 1-byte storage area, and command data is stored in the order of command reception from the area of the head address of the buffer area. Also, in the buffer area for storing error information, error information is stored for each 1-byte storage area, and error information is stored in order of command reception from the head address side of the buffer area. At this time, the error information is stored in the storage area of the address of the error information that is associated one-to-one with the address of the storage area of the corresponding command data.

  If a command is received after the command data is stored at the last address “2047” of the ring buffer, the command data is stored in the storage area of the first address “0” of the ring buffer.

  Next, after the command data is stored in the above-described ring buffer, the host control circuit 210 transfers the command data stored in the ring buffer to the subwork RAM 210a and stores it.

  Then, the host control circuit 210 analyzes the contents of the command stored in the subwork RAM 210a and acquires various information. Specifically, the host control circuit 210 determines the command type based on the information stored in the command type portion of the command, and acquires various information related to the game and the performance stored in the parameter field portion of the command.

  When the above-described command analysis processing is performed, the following effects can be obtained based on the structural characteristics of the command.

  As described above, among the above various commands, for example, commands such as a demo display command, a special symbol effect start command, a first power interruption return command, a special effect stop command, a special symbol hit start display command, etc. Game status information (game state information) is stored in the first parameter located at the beginning (the second byte from the beginning of the command). Therefore, if the command is analyzed for each byte while receiving these commands, regardless of the command type, the command analysis for the second byte from the start of the command reception always includes the game status. Since the analysis processing is performed, the analysis processing of the second byte can be shared in the analysis processing of these commands. That is, when the command analysis processing is performed on these commands, the timing of the game status analysis processing based on the start of the command analysis processing becomes the same for any command, and the game status The analysis process can be shared. In this case, the efficiency of the command analysis process in the host control circuit 210 can be improved, and more sophisticated effect control can be performed.

  In the command analysis processing for a command having the above-described configuration, a check is always performed on a zero area provided in a predetermined bit area in each parameter, a valid range of each data stored in the parameter is checked, and a stored data is checked. By checking the combination of the commands, it is possible to determine whether the command is valid. In this case, since the number of check items in the determination process increases, the presence or absence of the validity of the received command can be more accurately determined, and a safer game can be provided to the player.

<Animation request construction method>
In the pachinko gaming machine 1 of the present embodiment, the host control circuit 210 in the sub-control circuit 200 controls various effects when controlling the effect using the display device 13 based on various commands received from the main control circuit 70. A process for generating a command signal (request) for operating the effect device (including the display device 13) (hereinafter, referred to as an animation request construction process) is performed.

[Overview of animation request construction processing]
First, an outline of the animation request construction process will be described with reference to FIG. FIG. 37 is a diagram showing an outline of the operation when constructing an animation request.

  When the host control circuit 210 receives various commands from the main control circuit 70, first, as shown in FIG. 37, based on the received command, an object for generating a request called an animation request including designation information of production contents (Hereinafter referred to as an animation object).

  The “object” (processing information) referred to in the present specification is a concept in a broad sense that abstracts an object of a program procedure, and in the present embodiment, is a set of one or more processes. More specifically, the “object” in the present embodiment is a set of commands for invoking a process (designation of a name as an execution trigger, a call, an execution start process), and the structure includes one or a plurality of variables. A call ID (a name for specifying a process, etc.) of a process executed for each variable is registered. The "object" executes the processing registered in each variable by executing such a structure. Also, since the “object” is the name of the structure, the ID that can specify the structure, or the structure itself, the “object” is not limited to the structure and can be obtained by grouping one or more processes. This includes names, IDs, processes, storage information, and the like that can manage the execution order of the processes.

  In recent years, when software is constructed, it is managed on an object basis, and software is constructed by combining a plurality of objects. In this case, when using an existing object, there is no need to know the details of its internal configuration or operation principle. If a message (identification command, argument, etc.) is sent to the object from the outside, the function of the object is activated. Can be made to do.

  Next, the host control circuit 210 generates an animation request based on the animation object (using the animation object). Then, based on the generated animation request, the host control circuit 210 generates various requests (production start requests) such as a drawing request, a sound request, a lamp request, and an accessory request.

  After that, the host control circuit 210 outputs each generated request to the control circuit (controller) of the corresponding rendering device. Specifically, the host control circuit 210 outputs a sound request and a lamp request to the audio / LED control circuit 220, and outputs a drawing request to the display control circuit 230. Although not shown in FIG. 37, the accessory request generated by the host control circuit 210 is passed between processes relating to the accessory control performed in the host control circuit 210.

  Then, the audio / LED control circuit 220 controls the audio reproduction operation by the speaker 11 based on the input sound request. Further, the audio / LED control circuit 220 controls a light emission effect (LED animation) operation by the lamp (LED) group 18 based on the input lamp request. The display control circuit 230 controls the image display effect operation by the display device 13 based on the input drawing request. Further, the host control circuit 210 controls the effect operation by the accessory 20 based on the generated accessory request.

[Animation object type]
Here, various animation objects generated (used) in the animation request construction process will be described. In the animation request construction process of the present embodiment, basically, an animation object called an effect object and an animation object called a reservation object are generated, and an animation request is generated using these two animation objects.

  The effect object is an animation object generated according to the received command. For example, an animation object (object name “Demo”, identification command “80H”: hereinafter referred to as a demo object) generated when receiving a demo display command, or an animation object (object name “HendoTz01” generated when receiving a special design effect start command) , Identification command “81H”: hereinafter referred to as a variable object), and the like.

  In addition, after the lottery process, only one effect object is generated with the latter-come-first-served basis each time a command is received. That is, a plurality of effect objects are not generated at the same time, and each time a command is received, the effect object is overwritten. Since the reception command is called one by one, if an object is generated based on the late-arrival reception command while the objects are being generated in the first-come-first-served order, the object is generated based on the latter-arrival reception command. The generated object overwrites the object generated based on the first received command. Therefore, it is referred to as “late-arrival priority” here. In the present embodiment, when an object is generated based on a later-received reception command, the object generated based on the first-arrival reception command may be discarded.

  The suspended object (object name “Horyu”) is an animation object generated at the time of activation. In this suspension object, processing for displaying the current suspension state on the screen is performed. A pending object is basically an object that is not destroyed during activation (one of the resident objects). However, when a simple mode object described later is generated, the suspended object is also destroyed.

  In the present embodiment, in addition to the above-described animation objects, for example, an animation object having an object name “SimpleMode” (hereinafter, referred to as a simple mode object), an animation object having an object name “InitAnm”, and the like are generated in the animation request construction process. (Used). The simple mode object will be described later in detail.

  The animation object having the object name “InitAnm” is executed by a command (for example, a call command of a time setting screen, a time change is executed on the time setting screen) generated in the sub-substrate 202 at the time of startup or when an RTC (Real Time Clock) error occurs. Is an object generated based on a command at the time of performing the operation, and performs display processing of a time setting screen. When the host control circuit 210 receives a command from the main control circuit 70 and another effect object is generated, the animation object with the object name “InitAnm” is discarded.

[Various processes performed by animation objects]
Next, an outline of various processes performed in the above-described animation object will be described. The animation object basically includes an initialization process, a main process, and an end process. In the effect object generated in response to the received command, the command receiving process is further included in the animation object. Then, a predetermined process is called and executed from these various processes included in the animation object according to the situation of the game.

  The initialization process is a process that is executed only once at the start of object generation. In the initialization processing, for example, processing such as initialization of an object and acquisition of a lottery result is performed. The main process is a process executed for each frame (in an FPS (Frames per Second) cycle) during object generation. In the main processing, processing such as generation and setting of an animation request is performed. At the start of object generation, an initialization process and a main process are executed in the same frame. The termination process is a process executed only once when the object is destroyed. In the termination processing, processing such as termination of reproduction of unnecessary effects is performed. The command reception process is a process executed only once when a command is received. This command reception processing is used, for example, when performing animation control or the like based on a hold addition command or a hold subtraction command.

  Here, an example of the flow of the animation request construction process using the above-described animation object will be described with reference to FIGS. 38 and 39. FIG. 38 is a diagram showing a processing flow of the animation object during the animation request construction processing performed when the demo display command is received. FIG. 39 is a diagram showing a processing flow of the animation object during the animation request construction processing which is performed when a special symbol effect start command is received after the demonstration display command. 38 and 39, in order to simplify the description, the main-sub command control processing, the command analysis processing, and the animation request construction processing in the flow of the main processing performed by the host control circuit 210 (see FIG. 79 described later). Is shown only in the flow part where the loop processing is performed for the number of received commands.

  In the animation request construction process at the time of receiving the demo display command, the initialization process of the demo object, the process of receiving the command of the demo object, the command receiving process of the pending object, and the main process of the demo object are executed in this order. In the initialization processing of the demo object, a demo object is generated. The process of receiving a command of the demo object and the process of receiving a command of the suspended object are called and executed with the identification command “80H” as an argument. Then, in the main processing of the demo object, an animation request is generated.

  Next, when a special symbol effect start command is received after the demonstration display command, the end processing of the demo object, the initialization processing of the variable object, the command reception processing of the variable object, the command reception processing of the pending object, and the main processing of the variable object Are executed in this order. In the end processing of the demo object, the demo object generated at this time is discarded. In the initialization processing of the variable object, a variable object is generated. The process of receiving a command of a variable object and the process of receiving a command of a suspended object are called and executed with the identification command “81H” as an argument. Then, in the main processing of the variable object, an animation request is generated. This main process is performed until the next command is received.

  The command reception processing of the suspended object is executed irrespective of the command type, but the processing content (processing result) differs depending on the state of the suspended object at the time of executing the suspended object, the game status, and the like.

[Simple mode object]
The simple mode object (specific processing information) is an object generated in the simple screen state, and the simple mode object performs a simple screen display process. The simple mode object is basically at the time of receiving the power failure recovery command (identification command “D1H”) and includes the internal control state (variation of the identification symbol) included in the received power failure recovery command (see FIG. 32). This is generated only when the information of (display related information) is in the special symbol change state. In other words, the simple mode object is generated when a power interruption occurs during the special symbol change display, and thereafter, when the power interruption is restored. However, in this embodiment, since the presence / absence of the simple screen state is checked every frame, a simple mode object is generated when the simple screen state occurs.

  In the present embodiment, when a simple mode object is generated, all objects (including resident objects such as pending objects) generated at that time are terminated (discarded).

  Then, when the power interruption recovery command is received (at the time of activation) and the internal control state is the special symbol change state, the host control circuit 210 generates an animation request based on the simple mode object, The various requests described above are generated based on the animation request. In the present embodiment, when a drawing request generated based on the simple mode object is output from the host control circuit 210 to the display control circuit 230, the display control circuit 230 resets the power based on the drawing request. An animation (including a moving image and a still image) for informing the user of information is created, and the animation is displayed on the display device 13.

  In this embodiment, when a simple mode object is generated, no new object is generated until the simple mode object ends. That is, during the simple screen state, no effect object other than the simple mode object is generated. Then, the simple mode object ends when a command relating to the fluctuation stop (a fluctuation stop command, a command indicating a jackpot, or the like) is transmitted from the main control circuit 70.

  As described above, in the present embodiment, only the simple mode object is generated in the process at the time of power failure recovery executed when the internal control state is the special symbol change state (the change display state of the identification information). In addition, it is possible to quickly recover from a power failure.

  Further, in the present embodiment, when the simple mode object is generated, it is determined whether or not the received power interruption return command includes information indicating that the internal control state (information regarding the variable display of the identification symbol) is the special symbol variable state. I do. Therefore, in the present embodiment, the power interruption recovery processing can be performed in consideration of the consistency of the game state between before the power interruption detection and after the power interruption recovery.

  Further, in the present embodiment, as described above, each time the host control circuit 210 receives a command, only one object is generated with priority on a later-arriving basis (the object is overwritten). If no, no new object is created. Therefore, the consistency of the object generated based on the received command by the host control circuit 210 is also ensured.

  Further, in the present embodiment, at the time of power recovery, information indicating that power recovery is being performed is notified by the display device 13 based on an animation request generated by the simple mode object. Even if the gaming machine does not have a function of playing back from the middle of the game, it is possible to perform the power-off recovery without giving the player an uncomfortable feeling.

  Further, in the present embodiment, as described above, the end of the simple mode object is triggered when the command relating to the fluctuation stop is transmitted from the main control circuit 70 to the host control circuit 210. Therefore, for example, even if the power interruption is detected during the fluctuation and then the power is restored, for example, the animation type after the power interruption is restored on the display device 13 at the end of the simple mode object is the power interruption. An effect that is different from the type of animation during the fluctuation before the detection is executed, or the execution of an unnatural effect such as the same effect as the effect before the power failure is returned from the beginning is suppressed. As a result, even in an abnormal state such as when the power is restored, it is possible to suppress an effect that gives the player a sense of incongruity, and the game can proceed smoothly.

<Overview of drawing control method>
Next, an outline of a drawing process executed by the display control circuit 230 when a drawing request is output from the host control circuit 210 to the display control circuit 230 will be described with reference to FIG. FIG. 40 is a diagram showing a flow of image data (moving image data and still image data) at the time of drawing processing.

  In the present embodiment, data (compressed data) of an image (moving image and / or still image) displayed on the liquid crystal screen of the display device 13 is stored in the CGROM 206 in the CGROM board 204. Then, when the drawing request is input to the display control circuit 230, the display control circuit 230 first reads and decodes (decompresses) the image compression data from the CGROM 206. At this time, when the moving image compressed data is read, the moving image decoder 234 in the display control circuit 230 decodes the moving image compressed data. When the still image compressed data is read, the moving image The still image decoder 235 decodes the compressed still image data.

  Next, the display control circuit 230 writes the decoding result (decompressed image data) of the image data to a predetermined buffer specified as a texture source. In this embodiment, a movie buffer and a texture buffer provided in the SDRAM 250 (external RAM) and a sprite buffer in the built-in VRAM 237 are designated as texture sources. For example, when displaying one moving image, the expanded moving image data (decoding result) is written to a movie buffer in the SDRAM 250. For example, when displaying a single still image, the expanded still image data is written out to a sprite buffer in the built-in VRAM 237.

  Next, the display control circuit 230 specifies a rendering target to which a rendering (rendering) result of the image data is written. As the rendering target, for example, a frame buffer provided in the SDRAM 250 (external RAM), a frame buffer provided in the built-in VRAM 237, or the like can be designated.

  Next, the display control circuit 230 operates the rendering engine 241 to perform a rendering process on the decoding result of the image data written to the texture source, and writes the rendering result to the rendering target. In this process, the rendering process is performed in accordance with designation information (various information input from the 3D geometry engine 240) such as enlargement / reduction and rotation of the moving image.

  Next, the display control circuit 230 displays the rendering result (display output data) written on the rendering target on the display screen of the display device 13.

  In this embodiment, two frame buffers are prepared as rendering targets (see FIGS. 97 to 99 described later). When writing the rendering result from the rendering engine 241 to the frame buffer, the frame buffer in which the rendering result is written is switched for each frame. For example, when 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 the present 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 alternately executed for each frame.

  In the above-described flow of the rendering result writing process and the display process, the rendering result written to one frame buffer in a predetermined frame is displayed on the display screen of the display device 13 in the next frame (one side). The function of the frame buffer is switched from the drawing function to the display function.) The rendering result written to the other frame buffer in the next frame is displayed on the display screen of the display device 13 in the next frame (the function of the other frame buffer is switched from the drawing function to the display function). That is, in the present embodiment, the process of displaying the rendering result in one frame buffer and the process of displaying the rendering result in the other frame buffer are alternately executed for each frame.

<Overview of audio playback control method>
Next, an outline of a sound reproduction process executed by the sound / LED control circuit 220 when a sound request is output from the host control circuit 210 to the sound / LED control circuit 220 will be described with reference to FIG. FIG. 41 is a diagram showing an outline of the operation of the audio / LED control circuit 220 during the audio reproduction process.

  In the present embodiment, the sound data output to the speaker 11 is stored in the CGROM 206. When a sound request is input to the audio / LED control circuit 220, the audio / LED control circuit 220 specifies an access number based on the sound request, and reads out access data associated with the access number from the CGROM 206.

  In the present embodiment, the sound request includes not only the access number but also various sequence reproduction control commands (for example, start, stop, loop, etc., of sound reproduction) necessary for the sound reproduction processing generated in the sub-substrate 202. Command to instruct).

  Then, the audio / LED control circuit 220 performs an audio reproduction process based on the read access data. At this time, in the present embodiment, sound reproduction control is performed by simple access control. Here, the “simple access control” means that the voice / LED control circuit 220 transmits a plurality of command register strings registered in the CGROM 206 (external ROM) based on a sound request transmitted from the host control circuit 210. This is a control method for batch setting. Further, the number of simple access controls that can be executed simultaneously by the audio / LED control circuit 220 depends on the number of execution systems (four in this embodiment).

  FIG. 42 shows a schematic configuration of the access data. As shown in FIG. 42, the access data includes a plurality of sets of set data and addresses arranged in a predetermined order. At the end of the access data, a simple access end code (a code indicating the end of audio reproduction) is provided. ) Is stored. As shown in FIG. 41, when a plurality of access data is associated with one access number, a simple access end code is provided only for the last access data.

  When the setting data is set to the corresponding address with respect to the access data having such a configuration, the reproduction code corresponding to the setting data is executed, and the audio is reproduced. Then, the reproduction code execution process is sequentially performed from the first set data to the last data in the access data, and when the simple access end code is finally set, the sound reproduction operation based on the read access data ends. I do.

<Various drive control methods for lamps (LEDs)>
Next, details of various drive control processes of a plurality of LEDs included in the lamp group 18 executed by the audio / LED control circuit 220 when a lamp request is output from the host control circuit 210 to the audio / LED control circuit 220 Will be described. In the lamp control method of the present embodiment described below, an LED will be described as an example of a light emitting element, but the present invention is not limited to this, and the present embodiment is applicable to any other light emitting element. The lamp control method can be similarly applied.

[Overview of LED control]
First, with reference to FIG. 43, an outline of a control method for driving (turning on / off) an LED provided in the pachinko gaming machine 1 will be described. FIG. 43 is a signal flow diagram at the time of LED driving (lighting / light-out).

  When driving (turning on / off) the LED, first, the host control circuit 210 in the sub control circuit 200 outputs a lamp request (LED control request) to the audio / LED control circuit 220. In the present embodiment, the effect control processing of the host control circuit 210 (sub-control main processing shown in FIG. 79 described later) is performed at a predetermined FPS cycle (for example, about 16.7 msec, about 33.3 msec, or the like). Therefore, the process of transmitting the lamp request to the audio / LED control circuit 220 is also performed at a predetermined FPS cycle.

  Next, when a lamp request is input to the audio / LED control circuit 220, the audio / LED control circuit 220 outputs LED data (drive data) for setting an LED lighting pattern (LED animation) based on the lamp request. ) Is transmitted to each LED driver 280 (light emission drive means, effect drive means) in the lamp group 18. At this time, transmission of the LED data from the audio / LED control circuit 220 to the LED driver 280 is performed by the SPI communication method. The process of transmitting the LED data from the audio / LED control circuit 220 to the LED driver 280 is performed at a cycle of about 4 msec.

  Then, the LED driver 280 turns on / off the connected LED 281 (light emitting unit) in a predetermined pattern based on the received LED data. As a result, an effect operation based on the LED animation is executed.

  The light emission mode based on the LED data is controlled by a signal (control signal) transmitted from the LED driver 280 to the LED 281 and generated based on the LED data capable of controlling the light emission mode. Specifically, the light emission mode such as lighting, extinguishing, blinking, and brightness of the LED 281 is determined by an electrical waveform parameter (a voltage value, a current value, a duty ratio of a pulse width, and the like) of a signal transmitted from the LED driver 280 to the LED 281. Is controlled.

  In the present embodiment, an example is described in which a signal generated based on LED data is used as a “control signal based on drive data” for driving LED 281; however, the present invention is not limited to this. The “control signal based on drive data” when driving the LED 281 may be a transfer mode of LED data (drive data) or data generated based on the LED data. Here, the “data generated based on the LED data” includes a signal, a command, and a voltage change. In this case, the control unit that has received the LED data drives the other control unit with respect to the other control units. In this mode, a control signal based on data or drive data is transmitted.

[Connection configuration between audio / LED control circuit and LED]
Next, the connection configuration between the audio / LED control circuit 220 and each LED 281 will be described with reference to FIG. FIG. 44 is a schematic diagram showing the connection between the audio / LED control circuit 220 and the LED 281.

  In the present embodiment, as shown in FIG. 44, the audio / LED control circuit 220 sets a physical system 0 (SPI channel 0) and a physical system 1 (SPI channel 1) as an LED data output system (SPI channel). use. A plurality of LED drivers (devices) 280 are connected to each physical system in parallel via an SPI bus. In the example shown in FIG. 44, 16 LED drivers 280 (device 0 to device 15) are connected in parallel to each physical system.

  Each LED driver 280 is provided with a plurality of output ports (hereinafter, simply referred to as “ports”) on which LED data is set, and one LED 281 is connected to each port (connection unit). That is, in the present embodiment, the LED 281 is the LED 281 that is statically controlled. In the present specification, the statically controlled LED 281 is referred to as a static LED 281.

  In the example shown in FIG. 44, each of the LED drivers 280 (each device) is provided with 16 ports (port 0 to port 15). That is, 16 LEDs 281 are connected to each LED driver 280 (each device). In the present embodiment, 16 LEDs 281 are connected to each LED driver 280. However, the present invention is not limited to this, and each LED driver 280 (device) has its own LED driver 280 (device). 280 may be connected to 8, 32, 64, etc. LEDs 281.

  In the pachinko gaming machine 1 having the configuration shown in FIG. 44, at startup, the audio / LED control circuit 220 sets various parameters related to the connection configuration of the LED 281 for each SPI channel. More specifically, the audio / LED control circuit 220, upon startup, determines the number of devices used in each SPI (the number of LED drivers 280 connected to each SPI channel), the start port of the LED 281, the end port of the LED 281, and the LED driver. 280 start address is set. For example, in the example shown in FIG. 44, “16” is set for the number of devices used by the SPI, “0” is set for the start port, “15” is set for the end port, and “0” is set for the start address. Note that the start address of the LED driver 280 is appropriately set for each SPI channel, and is not limited to “0”.

  When various parameters related to the connection configuration of the LED 281 are set as described above, for example, the address of the LED 281 connected to the port 15 of the device 15 (LED driver) connected to the SPI channel 0 in FIG. , Device number = 15 and port number = 15.

  Here, the connection configuration between the audio / LED control circuit 220 and the LED driver 280 will be described in more detail with reference to FIG. FIG. 45 is a connection configuration diagram between the audio / LED control circuit 220 and the LED driver 280.

  As described above, the audio / LED control circuit 220 and the LED driver 280 are connected by the SPI bus (signal wiring means), and therefore, in each physical system (SPI channel), the signal wiring of the serial clock (SCL) is used. Timing signal lines) and signal lines (data signal lines) for serial data (SDO, SDI) are provided separately. Then, in each physical system (SPI channel) of the audio / LED control circuit 220 (master), the output terminal (SCL_P *, SCL_N *: “*”) of the serial clock signal (timing signal) of the audio / LED control circuit 220 is 1) or 2) is connected to the input terminal (SCL_P, SCL_N) of the serial clock signal of each LED driver 280 (slave). Further, output terminals (SDO_P *, SDO_N *) of the serial data (transmission data including drive data) of the audio / LED control circuit 220 are connected to input terminals (SDI_P, SDI_N) of the serial data of each LED driver 280. Is done.

  In the present embodiment, basically, the audio / LED control circuit 220 (master) continues to transmit data between the audio / LED control circuit 220 and the LED driver 280, and each LED driver 280 (slave) transmits data. Received data unilaterally. At this time, each LED driver 280 detects the rising edge of the serial data and starts inputting the serial data to the internal shift register.

[Structure of serial data]
Here, FIG. 46 shows a configuration (format) of serial data transmitted from the audio / LED control circuit 220 to the LED driver 280.

  In the present embodiment, as shown in FIG. 46, “1” (specific data) is stored at the beginning of serial data in an area of 16 bits or more continuously. Therefore, when the LED driver 280 detects the reception of “1” continuously 16 times or more, the state of the LED driver 280 becomes a serial data input standby state.

  After the storage area (first data section) of 16 bits or more in the serial data (first data section), the storage area of the device address (address of the LED driver 280) and the storage area of the register address are arranged in this order. . The storage area (second data section) for the device address (output destination information) and the storage area for the register address are each composed of an 8-bit (1 byte) area.

  In the present embodiment, as shown in FIG. 46, “0” (predetermined data) is stored in the storage area of the first bit of the device address. Therefore, when the LED driver 280 detects the reception of “0” after continuously detecting the reception of “1” 16 times or more, the state of the LED driver 280 becomes the state of the signal (output destination designation signal) corresponding to the device address. It will be in a standby state.

  An LED data storage area (third data section) is arranged after the register address storage area in the serial data, and the end of the serial data is stored in the last storage area of the serial data. "FFH" (FF) shown in FIG. The “0FFH” is composed of an 8-bit (1 byte) storage area, and “1” is stored in each bit area.

[Configuration and operation of LED driver]
Next, an example of the internal configuration of the LED driver 280 will be described with reference to FIG. FIG. 47 is a schematic internal configuration diagram of the LED driver 280.

  As shown in FIG. 47, the LED driver 280 includes a digital control unit 280a, an I / O unit 280b, an ISET unit 280c, a terminal group 280d, and a port group 280e.

  The digital control unit 280a outputs a drive signal (light-on / light-off signal) to the LED 281 connected to its own LED driver 280 based on a signal received via the terminal group 280d and the I / O unit 280b.

  The ISET unit 280c is a functional unit provided to prevent an excessive current from flowing through the LED 281. The ISET unit 280c forcibly stops the operation of the LED driver 280 (turns off the light) when detecting an excessive current.

  The terminal group 280d includes a serial clock signal input terminal (SCL), a serial data input terminal (SDI), a serial data output terminal (SDO), a signal format selection terminal (IFMODE), and an output enable terminal (OE). , A plurality of device address selection terminals (DA0 to DA5), and an error flag output terminal (XERR). In FIG. 47, for simplification of description, the two input terminals “SCL_P” and “SCL_N” of the serial clock signal shown in FIG. 45 are represented by one input terminal “SCL”, and the serial terminal shown in FIG. Two input terminals “SDI_P” and “SDI_N” of data are indicated by one input terminal “SDI”.

  In the present embodiment, since the LED driver 280 is an SPI-compatible driver, the LED driver 280 has a serial clock signal input terminal (SCL), a serial data input terminal (SDI), and a serial data output terminal (SDO), respectively. It is possible to communicate with the outside through the three connected communication wires. At this time, the LED driver 280 (slave) controls input / output of serial data based on the serial clock signal input from the master (audio / LED control circuit 220).

  In the present embodiment, as described above, between the audio / LED control circuit 220 and the LED driver 280, the serial data is unidirectionally transmitted from the audio / LED control circuit 220 to the LED driver 280. Therefore, in the present embodiment, when transmitting / receiving serial data between the audio / LED control circuit 220 and the LED driver 280, the input terminal of the LED driver 280 for the serial clock signal among the three communication wirings (SCL) and communication wiring connected to the serial data input terminal (SDI) are used.

  Here, FIG. 48 shows an operation outline when 1-bit data is input to the LED driver 280 to each input terminal (SDI_P, SDI_N, SCL_P, SCL_N).

  In the present embodiment, when “0” is input to the input terminal SDI_P of the LED driver 280 and “1” is input to the input terminal SDI_N, as shown in FIG. “0” is input to a digital circuit (for example, a digital control unit 280a described later). When “1” is input to the input terminal SDI_P of the LED driver 280 and “0” is input to the input terminal SDI_N, “1” is input to a digital circuit inside the LED driver 280. If the 1-bit data input to the input terminal SDI_P and the input terminal SDI_N of the LED driver 280 are the same (when “0” or “1” is input to both input terminals), the LED driver In the digital circuit inside 280, the previous input value is maintained.

  Note that, as shown in FIG. 48, the relationship between the combination of 1-bit data input to each of the input terminal SCL_P and the input terminal SCL_N of the LED driver 280 and the input value input to the internal digital circuit is also described above. This is the same as that of the input terminal SDI_P and the input terminal SDI_N.

  At the signal format selection terminal (IFMODE), a predetermined interface can be selected from a differential interface having a different logic operation method in SDI and SCL and an interface in the single-end mode. The output enable terminal (OE) is a terminal that enables lighting / non-lighting of all the LEDs 281 by an external terminal. Specifically, by setting the signal level of the output enable terminal (OE) to a high level, the output of the LED driver 280 can be turned on. By setting the signal level of the output enable terminal (OE) to a low level, , The output of the LED driver 280 can be turned off.

  A device address of the LED driver 280 is set to a plurality of device address selection terminals (DA0 to DA5). When reading the serial data into the shift register in the LED driver 280, the device address (device address information input from the audio / LED control circuit 220) specified by the output destination of the serial data includes a plurality of addresses. When the address matches the address set in the device address selection terminals (DA0 to DA5), the serial data is read. The device address determination process is performed by the digital control unit 280a.

  Here, FIG. 49 shows a table summarizing the address setting mode of the LED driver 280.

  In the present embodiment, as the address setting mode of the LED driver 280, two types of modes, a device control mode and a bus control mode, are provided. The bus control mode is a mode in which serial data is read regardless of data (device addresses) set in a plurality of device address selection terminals (DA0 to DA5).

  When the device address of the LED driver 280 is set in the device control mode, the data “a0” to “a5” defined in “Bit0” to “Bit5” in FIG. To be set to the device address selection terminal (DA5). The data “a0” to “a5” defined in “Bit0” to “Bit5” in FIG. 49 change according to the device address of the LED driver 280. Further, it is possible to determine whether the currently set address setting mode is the bus control mode or the device control mode from the data defined in “Bit 6” in FIG.

  The error flag output terminal (XERR) is a terminal to which an error flag value “1” is output when an abnormality is detected. The output operation of the error flag from the error flag output terminal (XERR) is performed only during the abnormality detection period, and when the error flag value “1” is output, the LED driver 280 automatically returns.

  Note that the error flag value “1” output from the error flag output terminal (XERR) is stored in the register. Further, while the error flag value “1” is being output from the error flag output terminal (XERR), the register of the LED driver 280 is latched (the state is held). When the register becomes readable, the error is released and "0" is output to the register from the error flag output terminal (XERR).

  The port group 280e includes a plurality of ports (48 ports in the example shown in FIG. 47), and one LED 281 is connected to each port. In addition, a red component LED 281 is connected to the port “OUTR *” (“*” is 0 to 15) in FIG. 47, a green component LED 281 is connected to the port “OUTG *”, and the port “OUTB”. The blue component LED 281 is connected to “*”.

  In the present embodiment, a configuration in which one color is emitted by the red component LED 281, the green component LED 281, and the blue component LED 281 connected to the ports “OUTR *”, “OUTG *”, and “OUTB *” adjacent to each other, respectively. To Note that the present invention is not limited to this, and as the type of LED connected to the port of the LED driver 280, other than the LED type that emits one color using the LED 281 of each of the three primary colors, An LED dedicated to monochromatic emission may be separately provided.

  Here, FIG. 50 shows a table summarizing the relationship between the physical system (SPI channel) to which the LED 281 is connected, the device address of the LED driver 280, and the output terminal of the LED driver 280. In the example shown in FIG. 50, two physical systems (physical system 0 and physical system 1) are used as the physical systems, the number of LED drivers 280 connected to each physical system is set to 16, and each LED driver 280 is connected. This is a configuration example when the number of LEDs 281 connected to is set to 48.

[LED data]
Next, the configuration of LED data (LED data set for each port) output from the audio / LED control circuit 220 to the LED driver 280 (LED 281) will be described with reference to FIG. FIG. 51 is a diagram showing a format (data type) of LED data.

  The LED data includes reproduction time (lighting time), red component luminance data (light emission data), green component luminance data, and blue component luminance data, and is set for each port. Note that the LED data is stored in the CGROM 206. The data length (the number of bytes) of the reproduction time is 2 bytes, and the data length of the luminance data of each color component is 1 byte.

  In the example shown in FIG. 51, the LED data is also provided with a data area called "alignment" of 1 byte. However, this is provided to make the data length (the number of bytes) of the LED data even. Adjustment region.

  The value specified in the column of the reproduction time (lighting time) is not a time value, but a period (about 4 msec) of a transmission process of LED data from the audio / LED control circuit 220 to the LED driver 280, that is, an audio / LED. This is a value when the cycle of the interrupt processing for the LED driver 280 of the control circuit 220 is “1”. For example, when “12” is set in the reproduction time (lighting time), the actual lighting time of the LED is about 48 msec (about 4 msec × 12). Further, when “0” is set to the reproduction time (lighting time) in the LED data, it means that the output of the LED data is completed (the predetermined LED animation is completed), and the LED data corresponding to the LED 281 corresponding to the LED data is output. When output, the effect operation by the series of LED animation ends.

  The method for defining the reproduction time (lighting time) in the LED data is not limited to the example shown in FIG. 51, and the time value of the reproduction time (lighting time) may be specified. Also in this case, a value that is an integral multiple of the cycle (about 4 msec) of the interruption process for the LED driver 280 of the audio / LED control circuit 220 is defined in the LED data. If a value other than an integral multiple of the interrupt processing cycle (about 4 msec) is specified in the column of the reproduction time (lighting time) in the LED data due to a calculation failure or the like, the cycle (about 4 msec) Any value exceeding the integral multiple is truncated. For example, if the interrupt processing cycle is 4 msec and 47 msec is specified in the reproduction time (lighting time) column, the value in the reproduction time (lighting time) column is rewritten to 44 msec.

  For the luminance data of each color component, an integer value in a range from “0” (lights out) to “255” is set. In addition, as in the present embodiment, by including the red component luminance data, the green component luminance data, and the blue component luminance data in the LED data, full-color light emission is performed by three of the red LED, the blue LED, and the green LED. In addition to the case where the LED is used, it is possible to cope with the case where each of the red LED, the blue LED, and the green LED is used as a single color LED.

  The luminance data “244” and “255” are “0xFF” and “0xFE” in hexadecimal (HEX), respectively. When the luminance data of each of the red, green, and blue components is “0xFE”, the LED 281 lights up in white. When each of the luminance data of the red, green, and blue components is “0xFF”, the luminance data is luminance data of “transparency definition”, and the lighting mode of “transparency definition” corresponds to generation (synthesis) of LED data described later. The method will be described. When the luminance data of each of the red, green, and blue components is “0”, the LED 281 is turned off, and these luminance data are referred to as “light-off data”.

  Here, an example of an LED data output control process for a static LED will be described with reference to FIG. The example shown in FIG. 52 shows an example in which one LED driver 280 is connected to one red LED, one blue LED, and one green LED. In this example, the reproduction time (lighting time) in the LED data is set to “12” (about 48 msec), and each of the red luminance data, the green luminance data, and the blue luminance data is set to “0xFE”. Will be described. In this LED data, white lighting is performed by three LEDs of a red LED, a blue LED, and a green LED.

  When the LED data described above is input to the LED driver 280, the LED driver 280 refers to the information of the control part (port information of each port) described later and corresponds to the type of the connected LED 281 from the LED data. With reference to the luminance data to be output, a driving signal corresponding to the luminance data is output to the LED 281. Therefore, in the example shown in FIG. 52, only the red luminance data “0xFE” in the LED data is output to the red LED connected to port 0, and the red LED corresponds to the red luminance data “0xFE”. Lights for about 48 msec at a high luminance. At this time, only the blue luminance data “0xFE” in the LED data is output to the blue LED connected to the port 1, and the blue LED has a luminance corresponding to the blue luminance data “0xFE” for about 48 msec. Lights up for a while. Further, at this time, only the green luminance data “0xFE” in the LED data is output to the green LED connected to the port 2, and the green LED has a luminance corresponding to the green luminance data “0xFE” for about 48 msec. Lights up for a while.

  In the example shown in FIG. 52, when performing the light-off operation, “0” is set to the luminance data of each color.

  As described above, in the present embodiment, the LED data output to the LED driver 280 includes at least the luminance value of each color (red, blue, green) component, and has a data form that can specify the light emission mode. Then, when the LED data is output from the LED driver 280 to the plurality of LEDs 281 connected to the LED driver 280, the luminance data of the color component corresponding to its own emission color in the LED data is output to each LED 281 (each LED 281). , Only the luminance data of the corresponding color component in the LED data is referred to).

  When the plurality of LEDs 281 are controlled to emit light by one LED driver 280 using the LED data having such a configuration, even if the plurality of LEDs are LEDs 281 having different emission colors, the luminance value (data) of each LED 281 is changed. Since it is easy to grasp, the process of synthesizing the emission colors by the plurality of LEDs 281 becomes easy. In addition, since the processing related to the synthesis of the emission colors at this time can be executed by the LED driver 280 in which the LED data is set, complicated LED emission control can be easily executed. Effect control (LED animation control) can be easily executed.

  In the present embodiment, the configuration of the LED data output to the LED driver 280 is the same regardless of the type of the LED 281 connected to the LED driver 280. Therefore, the LED data used in the predetermined LED driver 280 is also used in the other LED driver 280 (LED data) with respect to the other LED driver 280 that performs the same light emission mode (emission color) in the predetermined LED driver 280. Can be standardized). In this case, the LED data can be shared, and the process related to the lighting operation of the LED 281 can be shared.

  Such an effect of commonization of the LED data and the lighting operation processing is achieved when full-color lighting is performed using a red LED, a green LED, and a blue LED connected to one LED driver 280, that is, the light emission distribution of each color is important. This is particularly noticeable when executing the LED light emission control which is a parameter. Therefore, in the present embodiment, the emission control of the full-color LED can also be easily executed.

  The “format of LED data (drive data)” referred to in the present specification is not limited to the data format including the above-described luminance data of a plurality of types of color components and data on the lighting time. For example, the data format of the luminance data includes a data format used when generating the luminance data, a data format when stored in the CGROM 206, and the like. Further, even when the luminance data stored in the CGROM 206 is a variable, a group of variables, or data that does not have a data format due to a compression process, a file format conversion process, or the like, the program uses the When a variable, a group of variables (structure) or data is used as a group of luminance data, the variable, the group of variables (structure) or data is used as a data format of the luminance data. Can be recognized. Therefore, the “format of the LED data (drive data)” in the present specification includes the data format of the luminance data.

[LED data generation (synthesis) method]
Next, a method of generating (synthesizing) the LED data performed by the audio / LED control circuit 220 will be described. In the present embodiment, the audio / LED control circuit 220 can output the predetermined LED data read from the CGROM 206 to the LED driver 280 (port) as it is, but reads a plurality of LED data from the CGROM 206 and outputs the LED data. And a function of synthesizing and outputting the result to the corresponding port.

  In order to realize this function, the audio / LED control circuit 220 is provided with a plurality of channels (systems) for reading out each of the plurality of LED data and performing various processes for each port. Specifically, in the audio / LED control circuit 220, eight channels (first channel to eighth channel) in which LED data can be set are provided for each port.

  In the present embodiment, the execution priority of the LED data is determined in advance for each channel, and when the LED data is set in a plurality of channels, the execution priority is determined according to the execution priority. Or (correspondingly), the LED data to be set to the port in the LED driver 280 is determined. The process of determining (selecting) the LED data based on the execution priority is performed by the audio / LED control circuit 220. Therefore, the audio / LED control circuit 220 also functions as a means (selection means) for selecting, as output data, LED data set to a predetermined channel from a plurality of channels (systems).

  In the present embodiment, the first channel is the channel with the lowest execution priority of the LED data, and the execution priority of the LED data is set so that the execution priority becomes higher as the channel number increases. Therefore, in the present embodiment, the eighth channel is the channel with the highest execution priority. In the present embodiment, the eighth channel is set as a channel dedicated to the occurrence of an error. It should be noted that the “LED data execution priority” set for each channel in this specification is a priority when outputting, using, setting, setting, loading, and the like LED data (drive data).

  For example, when LED data (luminance data) is set for the second, fourth, and sixth channels for a predetermined port in the LED driver 280, the execution priority of these channels is The highest LED data of the sixth channel is output (set) from the audio / LED control circuit 220 to a predetermined port in the LED driver 280 as a synthesis result.

  The LED data read to the channel is stored in a channel registration buffer (storage means) together with data table information described later. Specifically, first, when a lamp request (LED control request) is input from the host control circuit 210 to the audio / LED control circuit 220, the audio / LED control circuit 220 stores the data in the CGROM 206 based on the lamp request. The obtained data table information and the LED data associated therewith are acquired. The data table information includes information on the channel in which the read LED data is set, and the audio / LED control circuit 220 stores the read LED data and the data in the registration buffer of the channel specified by the data table information. Overwrite and store table information. However, when storing (overwriting) the read LED data in the registration buffer, it is determined whether to overwrite the LED data in the registration buffer based on the execution priority of the LED data set for the channel. Done. The contents of the data table information will be described later in detail.

  In the present embodiment, an example has been described in which the read LED data and the data table information are overwritten and stored in the registration buffer. However, information (light emission control) capable of specifying the LED data and the data table information as shown in FIG. Information corresponding to the information) may be overwritten and stored in the registration buffer. In this case, the LED data and the data table information are obtained from a storage area different from the registration buffer (when the storage area and the registration buffer are physically separated from each other in the same storage medium). Or may be controlled to acquire LED data and data table information from storage areas of physically different storage media based on information stored in the registration buffer.

  The “information corresponding to the light emission control information” is not limited to information including the LED control ID (information for specifying the light emission control information) shown in FIG. Can be adopted. Therefore, as in the configuration of the present embodiment, the light emission control information itself (LED data and data table information) may be employed as the information corresponding to the light emission control information.

  Here, a lighting mode when LED data (luminance data) of “transparency definition” is set will be described. For example, when LED data (luminance data) for performing red lighting is set to the fourth channel and LED data (luminance data) of “transparency definition” is set to the sixth channel, LED data for red lighting is output. In other words, when LED data is set for a plurality of channels and the LED data of a channel with a lower execution priority is desired to be output with priority, the LED data of “transparent definition” is assigned to a channel with a higher execution priority. Set. When LED data for turning on red light is set for the fourth channel and “light-out data” is set for the sixth channel, “light-out data” of the sixth channel having a higher execution priority is given priority. And the LED 281 does not light up. The LED 281 also emits light when, for example, LED data is set only on the second channel, the fourth channel, and the sixth channel, and all the set LED data are LED data of “transparency definition”. do not do.

  In the present embodiment, the LED data of “transparency definition” is not set in the channel of the lowest execution priority. However, the present invention is not limited to this. LED data of “Definition” may be set.

  Further, the data of “light-off data” and “transparency definition” may be treated the same, and both data may be treated as “light-off data” or “transparency definition” data. In that case, the configuration of the LED control is appropriately changed, for example, by arbitrarily changing the configuration of the LED data and preventing the LEDs that can be controlled in each channel from overlapping in advance. When such a configuration is employed, for example, a gaming machine that handles only one of the data of “light-off data” and “transparency definition” can be handled.

  In the present embodiment, the “channel” (system) indicates a sequencer channel, and it is possible to express such that the sequencer channel sets a value in a variable or a register. However, the present invention is not limited to this, and the “channel” may simply indicate the number of sequencers, for example, or may be a reproduction unit (automatic reproduction function) including a sequencer. Also, a “channel” may include a stop channel (a channel for stopping the designated sound reproduction). Further, the “channel” is a generic name of a reproduction function capable of executing (including start, stop, end, interruption, etc.) animations, LED animations, and voices displayed on the display device 13. It is also a unit for expressing the number of data that can be reproduced simultaneously (the number of animations) (speaking of eight channels, eight data can be reproduced simultaneously).

[LED Animation Generation Method]
In the pachinko gaming machine 1 of the present embodiment, as described above, the lamp group 18 includes the plurality of LEDs 281. Then, according to the determined effect contents, the audio / LED control circuit 220 turns on / off the plurality of LEDs 281 in various patterns to perform a predetermined effect (LED animation). Therefore, in the present embodiment, when the LED animation is determined, various LED data necessary for the effect are specified.

  Further, in the present embodiment, since the effect of the predetermined LED animation is performed by linking the plurality of LEDs 281, the on / off operation of the plurality of LEDs 281 involved in the predetermined LED animation is collectively managed and controlled. Hereinafter, a port group (LED group) that collectively manages and controls the light-emitting operation in order to execute the LED animation by the audio / LED control circuit 220 is referred to as a “control part”.

  In the present embodiment, as described above, the audio / LED control circuit 220 is provided with eight channels (first channel to eighth channel) in which LED data can be set for each LED 281 (port). The control part is also set for each channel. Then, when the LED animation is executed by the audio / LED control circuit 220, data obtained by synthesizing the LED data of the control part of each channel between the channels is output as LED animation data. In addition, the control part may be the same for each channel, or may be different for each channel.

  In the audio / LED control circuit 220, a sequencer (drive data control means) for collectively managing and controlling the ON / OFF operation of the LED 281 in the control part set in each channel is provided for each control part. Can be

  Here, an example of generating an LED animation (an example of synthesizing LED data) will be specifically described with reference to FIGS.

(1) Generation example 1
FIG. 53A and FIG. 53B are diagrams illustrating an outline of the operation of generating and outputting the LED animation when the range of the control part is the same between channels. In the example illustrated in FIGS. 53A and 53B, an example in which a predetermined LED animation is executed using eight LEDs 281 (first to eighth LEDs) will be described. In the example shown in FIGS. 53A and 53B, an example will be described in which LED data is set in channels 6 to 8 of the eight channels.

  Further, in the example shown in FIGS. 53A and 53B, an example in which all the LEDs 281 (first LED to eighth LED) are set as control parts in each of the sixth to eighth channels will be described. In such a case, predetermined LED data is set to each LED 281 of the sixth to eighth channels.

  Specifically, in the eighth channel, LED data of “red” lighting is set to the first LED and the third LED, and “no data” (light-out data) is set to the other LEDs 281. In the seventh channel, LED data of “green” lighting is set to the first LED to the fifth LED, and “no data” (light-out data) is set to the other LEDs 281. In the sixth channel, the LED data of “blue” lighting is set to all the LEDs 281.

  In the example illustrated in FIG. 53A, when the LED data of the sixth to eighth channels is combined, the LED data of the eighth channel having the highest execution priority is set as the combination result in each LED 281 in the control part (all the LEDs). Set. Therefore, in this example, as shown in FIG. 53B, the same pattern as the lighting pattern of the LED 281 stored in the eighth channel is output as the synthesized LED animation.

(2) Generation example 2
FIGS. 54A and 54B are diagrams illustrating an outline of an operation of generating and outputting an LED animation in a case where the ranges of the control parts are different from each other between the channels. In the example illustrated in FIGS. 54A and 54B, an example in which a predetermined LED animation is executed using eight LEDs 281 (first LED to eighth LED), as in the first generation example, will be described. In the example shown in FIGS. 54A and 54B, an example in which LED data is set in channels 6 to 8 of the eight channels will be described, similarly to the first generation example.

  Further, in the example shown in FIGS. 54A and 54B, the control part of the eighth channel is set to the first LED to the third LED, the control part of the seventh channel is set to the first LED to the fifth LED, and the control part of the sixth channel is set. An example in which the control part is set to all the LEDs 281 will be described.

  In the eighth channel, LED data of “red” lighting is set to the first LED and the third LED, and “no data” (light-out data) is set to the second LED. In the seventh channel, LED data of “green” lighting is set in the first to fifth LEDs. In the sixth channel, the LED data of “blue” lighting is set to all the LEDs 281. In the eighth and seventh channels, no LED data is set to the port of the LED 281 that is not designated as the control part.

  In the example illustrated in FIG. 54A, when the LED data of the sixth to eighth channels are combined, the LED data of the sixth to eighth channels overlap in the first to third LEDs, but the LED data of the sixth to eighth channels has the highest execution priority. Eight-channel LED data is set as a synthesis result. In the fourth LED and the fifth LED, the LED data of the seventh channel and the sixth channel overlap, but the LED data of the seventh channel having a higher execution priority is set as a synthesis result. In the sixth to eighth LEDs, since LED data is set only in the sixth channel, the LED data of the sixth channel is set as a synthesis result.

  Therefore, the lighting pattern of the first LED to the third LED in the combined LED animation is the same as the lighting pattern of the first LED to the third LED of the eighth channel as shown in FIG. The lighting pattern is the same as the lighting patterns of the fourth and fifth LEDs of the seventh channel, and the lighting patterns of the sixth to eighth LEDs are the same as the lighting patterns of the sixth to eighth LEDs of the sixth channel.

(3) Generation example 3
In the third example of the generation of the LED animation, an example of the procedure of overwriting the LED data of each channel will be described with reference to FIGS. 55 and 56A to 56C. FIG. 55 is a diagram showing the correspondence between each channel and the LED data name (LED control ID) set in each channel. FIGS. 56A to 56C are diagrams illustrating the flow of the procedure for overwriting the LED data of each port in generation example 3. FIG.

  In the third generation example, as shown in FIGS. 56A to 56C, the LED 281 connected to the port A, the LED 281 connected to the port B, the LED 281 connected to the port C, and the LED 281 connected to the port D are: A configuration example of the LED group arranged in a rectangular shape will be described. The control part of the first channel is all ports, the control part of the third channel is ports A to C, and the control part of the sixth channel is only port A. In this example, the LED data “LED_ID_B” for turning on the LED 281 in “blue” is set in the first channel, the LED data “LED_ID_R” for turning on the LED 281 in “red” is set in the third channel, and the sixth channel is set. Consider a case where LED data “LED_ID_G” for turning on the LED 281 in “yellow” is set in the channel.

  When the voice / LED control circuit 220 combines and outputs such LED data, the voice / LED control circuit 220 first outputs the LED of the first channel having the lowest execution priority, as shown in FIG. 56A. Data “LED_ID_B” is set to all ports.

  Next, as shown in FIG. 56B, the audio / LED control circuit 220 transmits the LED data “LED_ID_R” of the third channel having the next lowest execution priority (higher execution priority than the first channel) to the ports A to C. Set to. As a result, in the ports A to C, the LED data “LED_ID_R” is overwritten on the LED data “LED_ID_B”.

  Then, the audio / LED control circuit 220 sets the LED data “LED_ID_Y” of the sixth channel having the next lowest execution priority (higher execution priority than the third channel) to the port A, as shown in FIG. 56C. . As a result, in the port A, the LED data “LED_ID_Y” is overwritten on the LED data “LED_ID_R”.

  When the above-described overwriting operation of the LED data is completed, the LED data “LED_ID_Y” is set in the port A, the LED data “LED_ID_R” is set in the ports B and C, and the LED data “LED_ID_B” is set in the port D. Set. As a result, an LED animation in which the LED 281 of the port A illuminates yellow, the LED 281 of the port B and port C illuminates red, and the LED 281 of the port D illuminates blue is executed.

  Since the overwriting process of the LED data is performed based on the execution priority between the channels, the overwriting order of the LED data is not limited to the examples shown in FIGS. 56A to 56C, and the overwriting order of the LED data is arbitrary. is there.

[Playback channel and expansion channel]
The pachinko gaming machine 1 according to the present embodiment has not only a function of executing one LED animation based on one lamp request but also a function of simultaneously executing two LED animations based on one lamp request. In the present embodiment, in order to realize the latter function, each channel is divided into two control parts, one LED animation is executed using one control part, and the other LED is used using the other control part. Run the animation.

  In the following, one control part used when executing one LED animation (normal LED animation) based on one lamp request is referred to as a “reproduction channel”, and based on one lamp request. The other control part used for simultaneously executing two LED animations is referred to as an “extended channel”. Therefore, the processing of the various examples of generating the LED animation described with reference to FIGS. 53 to 56 is executed using the reproduction channel in each channel. When two LED animations are simultaneously executed, a predetermined In the channel, both the reproduction channel (first system) and the extension channel (second system) are used.

  In addition, when two LED animations are executed at the same time, it is necessary to separately control the operations of the playback channel and the extension channel. Therefore, the sequencer (automatic playback control function) and the sequencer are separately provided for the playback channel and the extension channel. A registration buffer (a first registration buffer and a second registration buffer) is provided.

  Here, the configuration of the reproduction channel and the extension channel provided for each channel, and the outline of the configuration of the sequencer associated therewith will be described with reference to FIGS. 57 and 58. FIG. 57 is a diagram showing the configuration of the playback channel and the extension channel provided on the eighth channel and the configuration of the sequencer associated with them. FIG. 58 is a diagram showing the configuration of the playback channel and the extension channel provided on the seventh channel. It is a figure which shows the structure of the extension channel, and the structure of the sequencer matched with them.

  In the examples shown in FIGS. 57 and 58, an example in which a predetermined LED animation is executed using eight LEDs 281 (first to eighth LEDs) will be described. In this example, two sequencers are provided for each channel. That is, 16 sequencers are provided in total (for 8 channels). In each sequencer, a sequencer number is sequentially set from the first channel sequencer.

  Therefore, for example, sequencer numbers “0” and “1” are set for the two sequencers of the first channel, respectively, and sequencer numbers “6” and “7” are set for the two sequencers of the fourth channel, respectively. You. In each channel, the sequencer with the smaller sequencer number among the two sequencers is set as the sequencer used in the reproduction channel. That is, for example, in the playback channel of the first channel, the sequencer of the sequencer number “0” is used, and when the extension channel is set in the first channel, the sequencer of the sequencer number “1” is assigned to the extension channel. Used.

  Therefore, as in the example shown in FIG. 57, in the eighth channel, the control portions of the first to fifth LEDs are controlled as reproduction channels, and the control portions of the remaining LEDs 281 (sixth to eighth LEDs) are controlled as expansion channels. In this case, the sequencer with the sequencer number "14" (sequencer 14 in the figure: first drive data control means) is used in the reproduction channel, and the sequencer with the sequencer number "15" (sequencer 15 in the figure: second Drive data control means) is used in the extension channel. Also, as in the example shown in FIG. 58, in the seventh channel, when the control part of the first LED to the seventh LED is controlled as a reproduction channel and the control part of the remaining LED 281 (eighth LED) is controlled as an extension channel, , The sequencer with the sequencer number “12” (the sequencer 12 in the figure) is used for the reproduction channel, and the sequencer with the sequencer number “13” (the sequencer 13 in the figure) is used for the extension channel.

  When two LED animations are simultaneously executed using the above-described playback channel and the extension channel, since the two sequencers update the data for one channel, the overlapping LED 281 between the playback channel and the extension channel Is present, it is difficult to determine which sequencer controls the LED 281. Therefore, in the present embodiment, in order to prevent the occurrence of the duplicated LED 281 between the reproduction channel and the extension channel, it is determined which of the control parts of the reproduction channel and the extension channel belongs to all the control target LEDs 281. Define in advance. That is, a boundary between the control part of the reproduction channel and the control part of the extension channel is defined in advance.

  Note that the boundary between the control part of the reproduction channel and the control part of the extension channel can be set arbitrarily. However, the boundary between the control part of the reproduction channel and the control part of the extension channel is registered in the LED control program at the time of program initialization. Therefore, the position of the boundary cannot be changed during the operation of the LED control program.

  In addition, the pachinko gaming machine 1 of the present embodiment has a function of clearing the reproduction channel (a function of setting light-out data in each port of the reproduction channel) when only the reproduction channel is used. When used, there is no clear function for each channel. Therefore, in the present embodiment, in consideration of the case where both the reproduction channel and the extension channel are used, clear data (light-out data) of each channel is prepared in advance, and when the reproduction channel and the extension channel are cleared (LED animation). At the end), the prepared clear data is used.

[Type of LED animation playback method]
In the present embodiment, based on a lamp request (LED control request), the audio / LED control circuit 220 outputs the LED data generated as described above to the lamp (LED) group 18 and performs a predetermined LED animation. Execute At this time, the predetermined LED animation is executed in accordance with the reproduction method (information specifying the execution timing and the reproduction mode of the LED animation) specified in the data table information acquired when the lamp request is input. Here, various reproduction methods of the LED animation prepared in the present embodiment will be described. The playback method is specified for each channel in each frame of the LED animation (each time a lamp request is received).

In the present embodiment, the following five types of names are prepared.
(1) "SHOT"
(2) “SHOT2”
(3) "LOOP"
(4) "NEXT"
(5) "ODONLY"

  In the present embodiment, as the information of the “reproducing method”, any information can be used as long as it is information that can specify information on lighting / turning off of the LED 281 such as a lighting mode of the LED 281 and a lighting time of the LED 281. be able to. As the reproduction method, for example, an ID, a numerical value, a symbol, or the like capable of designating the reproduction method of the LED 281 may be set, and information on the lighting mode of the LED 281 may be referred to based on such information. , The information on the lighting mode of the LED 281 may be set.

  “SHOT” is a playback method in which the set LED animation is played once, and then the lighting state of the last frame (the lighting pattern of the LED at the end of the LED animation) is maintained. “SHOT2” is a playback method in which the set LED animation is played once, and then the LED 281 is turned off.

  “LOOP” is a playback method in which, when the LED animation is played back to the last frame, the playback returns to the start frame and repeats the playback of the LED animation, that is, a loop playback of the LED animation.

  “NEXT” (predetermined playback method) means that, when a lamp request is input to the audio / LED control circuit 220 and another LED animation is being played, the LED animation specified by the lamp request is played back. This is a method of playing back after the end of the LED animation. Even if the information of the reproduction method obtained at the time of input of the lamp request includes “NEXT” designation, if there is no LED animation being reproduced at the time of inputting the lamp request, the LED animation designated by “NEXT” is immediately reproduced. If the LED animation being played at the time of inputting the lamp request designated as “NEXT” is the LED animation of the “LOOP” playback method, the “NEXT” is played after the last frame of the LED animation being played in a loop. Plays the specified LED animation.

  “ODONLY” (specific reproduction method) is a reproduction method in which LED data is output from a port only when there is LED data (second drive data) to be set in the port. However, when the LED data to be set to the port in the channel designated as “ODONLY” is the light-off data (first drive data) (for example, all the LED data to be output to the adjacent red LED, blue LED, and green LED are If it is 0), it is determined that there is no LED data, and no LED data (light-off data) is set in the port.

Note that there are the following twelve types of reproduction method patterns specified in the data table information acquired when the lamp request is input to the audio / LED control circuit 220.
(1) "SHOT"
(2) “SHOT2”
(3) "LOOP"
(4) “SHOT | NEXT”
(5) “SHOT2 | NEXT”
(6) "LOOP | NEXT"
(7) “SHOT ｜ ODONLY”
(8) “SHOT2 ｜ ODONLY”
(9) “LOOP ｜ ODONLY”
(10) “SHOT ｜ NEXT ｜ ODONLY”
(11) "SHOT2 | NEXT | ODONLY"
(12) “LOOP ｜ NEXT ｜ ODONLY”

  As described above, in the present embodiment, one of “SHOT”, “SHOT2”, and “LOOP” is always specified as the LED animation playback method, and “NEXT” and / or “ODONLY” are necessary (production The content is specified along with one of “SHOT”, “SHOT2”, and “LOOP” according to the content. It should be noted that examples of the LED animation playback operation based on the various playback methods described above will be specifically described later with reference to the drawings.

[Switching playback of LED animation based on playback method]
In this embodiment, the execution period of the LED animation may be longer than the FPS cycle (for example, about 16.7 msec, about 33.3 msec, etc.) of the output processing of the lamp request of the host control circuit 210. In this case, the next lamp request may be input to the audio / LED control circuit 220 during the reproduction of the LED animation.

  In such a case, the audio / LED control circuit 220 performs switching reproduction of the LED animation in accordance with the reproduction method acquired based on the newly input lamp request. For example, if “NEXT” is not specified for the reproduction method acquired based on the next lamp request, the data of the LED animation being reproduced is discarded, and the LED created based on the newly input lamp request is discarded. Start playing the animation immediately.

  Here, FIG. 59 shows various examples of the switching reproduction pattern of the LED animation. FIG. 59 shows that during the reproduction of the LED animation created based on the first lamp request, the second lamp request or the second lamp request and the third lamp request are controlled by the audio / LED control for the same channel. 9 is a table summarizing an example of a switching reproduction pattern of LED animation when input to a circuit 220.

  Hereinafter, the switching reproduction pattern of a part of the LED animation in FIG. 59 will be described with reference to FIGS.

  FIG. 60 is a diagram showing a switching reproduction flow on the time axis of the LED animation corresponding to the switching reproduction pattern 2 in FIG. In the switching reproduction pattern 2, during the reproduction of the LED animation of the reproduction method "SHOT" created based on the first lamp request, the second lamp request is input to the audio / LED control circuit 220, and the reproduction at that time is performed. This is a switching reproduction pattern when “LOOP” is specified as the method.

  In the switching reproduction pattern 2, when the first lamp request is input, the reproduction of the LED animation of the reproduction method “SHOT” based on the first lamp request is started. Next, the second lamp request is input to the audio / LED control circuit 220 during the reproduction of the LED animation based on the first lamp request. If only “LOOP” is specified in the reproduction method information obtained at this time, as shown in FIG. 60, at the time of inputting the second lamp request, the data of the LED animation based on the first lamp request being reproduced is input. Is discarded (the LED animation being reproduced is terminated), and the reproduction of the LED animation of the reproduction method “LOOP” based on the second lamp request is immediately started.

  FIG. 61 is a diagram showing a switching playback flow on the time axis of the LED animation corresponding to the switching playback pattern 4 in FIG. In the switching reproduction pattern 4, during the reproduction of the LED animation of the reproduction method "SHOT" created based on the first lamp request, the second lamp request is input to the audio / LED control circuit 220, and the reproduction at that time is performed. This is a switching reproduction pattern when “SHOT | NEXT” is specified as the method.

  In the switching reproduction pattern 4, when the first lamp request is input, the reproduction of the LED animation of the reproduction method “SHOT” based on the first lamp request is started. Next, the second lamp request is input to the audio / LED control circuit 220 during the reproduction of the LED animation based on the first lamp request. If “SHOT | NEXT” is specified in the information of the reproduction method obtained at this time, as shown in FIG. 61, after the reproduction of the LED animation based on the first lamp request being reproduced, the second lamp request is completed. The reproduction of the LED animation of the reproduction method “SHOT | NEXT” based on the video is started. In this case, the reproduction operation of the LED animation based on the second lamp request is in a standby state from the time when the second lamp request is input to the time when the reproduction of the LED animation based on the first lamp request is completed.

  FIG. 62 is a diagram showing a switching playback flow on the time axis of the LED animation corresponding to the switching playback pattern 6 in FIG. Note that the switching reproduction pattern 6 is such that during the reproduction of the LED animation of the reproduction method “SHOT” created based on the first lamp request, the second lamp request and the third lamp request are transmitted in the audio / LED control circuit 220 in this order. Is a switching reproduction pattern when “SHOT | NEXT” is specified as the reproduction method in each lamp request.

  In the switching reproduction pattern 6, when the first lamp request is input, the reproduction of the LED animation of the reproduction method “SHOT” based on the first lamp request is started. Next, during the reproduction of the LED animation based on the first lamp request, the second lamp request and the third lamp request are input to the audio / LED control circuit 220 in this order. When “SHOT | NEXT” is specified as the information of the reproduction method in each lamp request, as shown in FIG. 62, after the reproduction of the LED animation based on the first lamp request being reproduced, the second lamp request is made. The reproduction of the LED animation of the reproduction method “SHOT | NEXT” based on the second ramp request is started, and the reproduction of the LED animation of the reproduction method “SHOT | NEXT” based on the third lamp request is started after the reproduction of the LED animation based on the second lamp request. You.

  In this case, the reproduction operation of the LED animation based on the second lamp request is in a standby state from the time when the second lamp request is input to the time when the reproduction of the LED animation based on the first lamp request is completed. In addition, the reproduction operation of the LED animation based on the third lamp request is in a standby state from the time when the third lamp request is input to the time when the reproduction of the LED animation based on the second lamp request is completed.

  FIG. 63 is a diagram showing a switching playback flow on the time axis of the LED animation corresponding to the switching playback pattern 7 in FIG. In the switching reproduction pattern 7, during the reproduction of the LED animation of the reproduction method “LOOP” created based on the first lamp request, the second lamp request is input to the audio / LED control circuit 220, and the reproduction at that time is performed. This is a switching reproduction pattern when “SHOT | NEXT” is specified as the method.

  In the switching reproduction pattern 7, when the first lamp request is input, the reproduction of the LED animation of the reproduction method “LOOP” based on the first lamp request is started. Next, the second lamp request is input to the audio / LED control circuit 220 during the predetermined number of times (second time in the example shown in FIG. 63) of the LED animation based on the first lamp request. If “SHOT | NEXT” is specified in the information of the reproduction method obtained at this time, as shown in FIG. 63, after the loop reproduction of the LED animation based on the first lamp request for the predetermined number of times, the second reproduction is completed. The reproduction of the LED animation of the reproduction method “SHOT | NEXT” based on the lamp request is started. In this case, the reproduction operation of the LED animation based on the second lamp request is in a standby state during a period from the input of the second lamp request to the end of the predetermined number of loop reproductions of the LED animation based on the first lamp request.

  In the present embodiment, for example, as shown in FIGS. 62 and 63, when a lamp request specifying “NEXT” is continuously input to the audio / LED control circuit 220, the continuous LED animation is performed. Playback is performed. However, in the present embodiment, the maximum number of LED animations reproduced in one continuous reproduction is eight. Then, a lamp request is input to the audio / LED control circuit 220 during the reproduction of the eighth LED animation, and if the reproduction method obtained at that time includes “NEXT” designation, the lamp request is created based on the lamp request. The data of the performed LED animation is discarded. FIG. 64 shows a switching reproduction flow on the time axis of this reproduction operation.

  Although a flow chart on the time axis is not shown, the switching reproduction mode of the switching reproduction pattern 11 in FIG. 59 will be briefly described. The switching reproduction pattern 11 is such that during the reproduction of the LED animation of the reproduction method “SHOT” created based on the first lamp request, the second lamp request and the third lamp request are input to the audio / LED control circuit 220 in this order. This is a pattern in the case where the information on the reproduction method obtained when the second ramp request is input is “LOOP | NEXT” and the information on the reproduction method obtained when the third lamp request is input is “SHOT”. In this switching reproduction pattern 11, since “NEXT” is not specified as the reproduction method of the third ramp request which is the latest request, when the third ramp request is input, the LED animation based on the first lamp request being reproduced is performed. The data and the LED animation data generated based on the second lamp request are discarded, and the reproduction of the LED animation of the reproduction method “SHOT” based on the third lamp request is immediately started.

[Playback example when ODONLY is specified]
Next, the lighting operation of the LED animation (the operation of synthesizing the LED data) when “ODONLY” is specified in the reproduction method will be described.

  Here, an example in which an LED animation is executed by a plurality of LEDs 281 arranged in a rectangular shape as shown in FIGS. 65 and 66 described below will be described. Further, as a reproduction channel used when creating the LED animation, a reproduction channel of a first channel (hereinafter, referred to as a first reproduction channel) and a reproduction channel of a second channel (hereinafter, referred to as a second reproduction channel) are used. The control portion of the first reproduction channel is all LEDs 281, and the control portion of the second reproduction channel is a plurality of control portions arranged on the left side and the right side (side) (in the examples shown in FIGS. 65 and 66 described later, 8) LED281.

  First, an example of a reproduction mode of an LED animation when “ODONLY” is not specified for each reproduction channel will be described with reference to FIGS. 65A and 65B. FIG. 65A is a table in which information on reproduction specifications of each reproduction channel included in data table information acquired when a lamp request is input to the audio / LED control circuit 220. FIG. 65B is a diagram showing a state when an LED animation is generated based on information on the reproduction specification of each reproduction channel defined in the table of FIG. 65A.

  In this example, a lighting pattern (ptnA) for turning on all the LEDs 281 in red at the control portion (entire) of the first reproduction channel (1 ch) and a control portion (side) of the second reproduction channel (2 ch) at a cycle of 12 msec. An example in which an LED animation is created by synthesizing a lighting pattern (ptnB) for sequentially moving the LED 281 that emits blue light in the control portion will be described.

  If "ODONLY" is not specified for each playback channel, the execution priority of the second playback channel is higher than that of the first playback channel. Is overwritten on the LED data of the corresponding LED 281 in the control part. Therefore, when “ODONLY” is not specified for each playback channel, as shown in FIG. 65B, in the LED animation after composition, the LED lighting pattern on the side is the same as the lighting pattern (ptnB) of the second playback channel. Will be the same.

  Next, an example of a playback mode of the LED animation when “ODONLY” is designated as the second playback channel will be described with reference to FIGS. 66A and 66B. FIG. 66A is a table in which information on reproduction specifications of each reproduction channel included in data table information acquired when a lamp request is input to the audio / LED control circuit 220. FIG. 66B is a diagram showing a state when an LED animation is generated based on the information on the reproduction specification of each reproduction channel in FIG. 66A.

  In this case, since the second reproduction channel has a higher execution priority than the first reproduction channel, the LED data in the control part of the second reproduction channel is replaced by the LED data of the corresponding LED 281 in the control part of the first reproduction channel. Overwritten on top. However, at this time, since “ODONLY” is specified as the reproduction method for the second reproduction channel, the LED data is overwritten only on the port having the output data (LED data) other than the turn-off data, and the port having no output data is output. At (the port where the light-off data is set), the LED data is not overwritten, and the LED data of the first reproduction channel is maintained. Therefore, when “ODONLY” is specified as the second reproduction channel, as shown in FIG. 66B, in the LED animation after the combination, the LED data of blue lighting among the plurality of LEDs 281 arranged on the side Only the LED 281 in which is set is lit in blue, and the other LEDs 281 are lit in red.

[Data table information]
As described above, in the present embodiment, when the audio / LED control circuit 220 generates and reproduces an LED animation based on a lamp request (LED control request), not only the LED data output to each LED 281 but also each LED 281 Various information such as a control part of a channel and a reproduction method is also required. The data table information is a collection of such information, and this data table information is stored in the CGROM 206 in the same manner as the LED data.

  The data table information is acquired together with various LED data based on the LED animation ID (LED animation pattern) specified by the lamp request when the lamp request is input to the audio / LED control circuit 220. Then, the acquired data table information and various LED data are stored in the registration buffer of the reproduction channel specified by the data table information.

Here, the contents of various information included in the data table information will be described. In the present embodiment, the following six pieces of information are mainly registered in the data table information.
(1) Reproduction method (2) Reproduction channel (3) Extension channel (4) Off data identification (5) Control part (6) LED data name

  As the reproduction method information (reproduction method information), the above-described 12 types of reproduction methods are registered. As the reproduction channel information, the type (channel number) of the reproduction channel to be used is registered.

  As the information of the extension channel, whether or not the extension channel is used is registered. For example, “0” is registered when the extension channel is not used, and “1” is registered when the extension channel is used. When “1” is registered as the information of the extension channel, the extension channel of the channel including the designated reproduction channel is used.

  As the information of the light-off data identification, information for identifying to which channel the light-out data prepared in advance when using the extension channel is registered is registered. When the extension channel is not used, the information of the turn-off data identification is not registered.

  As information of the control part (output destination information), information of the SPI channel (physical system) used in the control part of the reproduction channel (information of the communication path), and port information controlled by the reproduction channel (designation information of the light emitting means) ) Is registered. The port information includes a port number preset for the port and information on the type of the LED 281 connected to the port. As the information of the type of the LED 281, for example, information for identifying a static LED for a red component, a static LED for a green component, a static LED for a blue component, an LED for monochromatic emission, and the like is registered.

  When the extended channel is used, information that defines the boundary between the control part of the reproduction channel and the control part of the extension channel in the designated channel is also registered as the information of the control part. The information of the control part may be included in the LED data or the lamp request instead of the data table information. The information of the LED data name is a data name used when displaying the reproduction history of the LED animation in the debugging process.

[Various effects obtained by the lamp (LED) control method of the present embodiment]
Here, various effects obtained by the lamp (LED) control method executed in the above-described pachinko gaming machine 1 of the present embodiment will be described together.

  In the lamp (LED) control method of the present embodiment, as described above, each time a lamp request is input to the audio / LED control circuit 220 (for each frame of the LED animation), the LED animation reproduction method is designated. Then, the reproduction of the LED animation is executed according to the specified reproduction method. In this case, for example, the output count (reuse count) of the LED data (output data) output to the LED 281 is set for each frame of the LED animation, and the LED data is output (set) at the timing (stored first). Discarded LED data and set new LED data, or set new LED data after previously stored LED data is output). In this case, the following effects can be obtained.

  For example, when the host control circuit 210 or the audio / LED control circuit 220 directly controls the LED 281 by designating the LED data, the number of outputs of each LED data and the timing of outputting (setting) the LED data are set. It must be determined in advance. When output control of a plurality of LED data is performed, it is necessary to set in advance all complicated output control forms such as whether or not the same LED 281 is controlled by each LED data. Therefore, in this case, not only a problem that the development period of the pachinko gaming machine 1 is extended, but also a problem that it becomes difficult to increase the variation of the effect occurs.

  However, in the present embodiment, based on the lamp request input from the host control circuit 210, the audio / LED control circuit 220 specifies a reproduction method of the LED data (LED animation), and based on the reproduction method, Controls output of LED data. At this time, in the present embodiment, by specifying “SHOT” or “LOOP” as the reproduction method, the number of output times of the LED data can be easily controlled, and depending on whether or not “NEXT” is specified as the reproduction method. Also, the timing of outputting (setting) the LED data can be easily controlled. Therefore, in the present embodiment, it is possible to easily manage the LED output control by the host control circuit 210 and the audio / LED control circuit 220, and to increase the types of effect patterns by turning on the LED (lamp). It is possible to smoothly control the produced effect pattern and enhance the effect (entertainment of the game).

  In this embodiment, as described above, a plurality of reproduction channels are provided for each LED 281 (for each port), and the execution priority of LED data is set in advance for each reproduction channel. Further, the determination of overwriting or adding the above-described LED data to the LED data being reproduced is performed individually for each reproduction channel according to the specified reproduction method.

  Therefore, in the present embodiment, for example, even under a situation in which a plurality of reproduction channels are executed, storage control of the LED data in the registration buffer of each reproduction channel can be facilitated. As a result, it is possible to execute the process of combining the effect patterns by the LED 281 using the plurality of reproduction channels, so that it is possible to generate a more complicated effect pattern of the LED animation, and to further enhance the effect of the effect. be able to.

  Further, in the present embodiment, even if a plurality of ramp requests are generated for a standby (playing) playback channel, data switching playback control is performed based on the playback method. A more complicated effect can be executed as compared to a gaming machine that performs such an effect. Therefore, in the present embodiment, it is possible to further enhance the effect.

  Further, in the lamp (LED) control method of the present embodiment, as described above, a reproduction channel and an extension channel can be provided for each channel. At this time, the range of the control portion of the reproduction channel and the control of the extension channel are controlled. The channel is divided so that the region ranges do not overlap each other, and a reproduction channel and an extension channel are set. The sequencer for controlling the operation of the extension channel is provided separately from the sequencer for controlling the operation of the reproduction channel.

  By providing such a configuration, in the present embodiment, two channels of LED animation can be reproduced simultaneously in one channel, and each LED animation can be controlled independently. Therefore, in the present embodiment, when the extended channel is used, more complicated LED animation (lamp lighting pattern) is reproduced by using more LEDs 281 than when the LED animation is reproduced only by the reproduction channel. It becomes possible, and the interest of the player in the game can be increased.

  Further, in the lamp (LED) control method of the present embodiment, as described above, a plurality of LEDs 281 (producing devices) can be controlled by one LED driver 280. In addition, each LED driver 280 determines whether or not the LED data transmitted from the audio / LED control circuit 220 can be received by the device address set in its own device address selection terminal (DA0 to DA5). It can be determined based on this. Therefore, in the present embodiment, the audio / LED control circuit 220 only needs to perform a process of transmitting data to each LED driver 280 via the SPI bus. And the processing load of the audio / LED control circuit 220 can be reduced.

  In the present embodiment, each LED driver 280 specifies the LED 281 that transmits a signal (brightness value) related to the effect based on the information of the control part included in the data table information, and also transmits the signal transmitted to the LED 281. Can also be specified. In this case, the processing of the audio / LED control circuit 220 in the data communication between the audio / LED control circuit 220 and each LED driver 280 is only the data transmission processing, and the data transmission speed can be increased. As a result, when the data transmission speed between the audio / LED control circuit 220 and each LED driver 280 increases, the rise of the LED driver 280 also increases, so that the effect control processing can be speeded up.

  Further, in the present embodiment, as described above, when receiving the serial data, each of the LED drivers 280 detects the reception of “1” continuously 16 times or more (after rising from the sleep mode state), By detecting the reception of "0", a device address standby state is set. Therefore, each LED driver 280 can prevent the effect control from being executed even if the device address is erroneously received at a timing other than the timing at which the LED 281 is controlled, and can control the LED 281 more accurately. .

<Overview of the control method of character objects>
Next, an outline of a drive control method of the accessory 20 provided in the pachinko gaming machine 1 will be described with reference to FIG. FIG. 67 is a data flow diagram when the accessory 20 is driven.

  In this embodiment, when the accessory request is generated (acquired) in the host control circuit 210, the host control circuit 210, as shown in FIG. 67, drives the motor 272 (stepping motor) for driving the accessory 20. ) Is transmitted to the motor driver 271 (drive control means) in the motor controller 270 via the I2C controller 261. Then, the motor driver 271 outputs the received excitation data to the connected motor 272 (driving means). Thereby, the effect operation by the accessory 20 is started. When the accessory 20 is driven by a plurality of motors 272 or when there are a plurality of accessories 20, a motor driver 271 corresponding to each motor 272 is provided.

  Further, since the host control circuit 210 and the motor controller 270 (motor driver 271) are connected by an I2C bus, signals (excitation data) are transmitted and received between them using the I2C method.

  Here, the connection configuration between the host control circuit 210 and the motor driver 271 will be described in more detail with reference to FIG. FIG. 68 is a connection configuration diagram between the host control circuit 210 and the motor driver 271. FIG. 68 shows an example in which a plurality of motor drivers 271 are provided. That is, FIG. 68 illustrates a connection configuration example in the case where the drive of the accessory 20 is controlled by the plurality of motors 272 or the case where the drive of the accessory 20 is controlled.

  Since the host control circuit 210 and the plurality of motor drivers 271 are connected by the I2C bus as described above, the signal wiring for the serial clock (SCL) and the signal wiring for the serial data (SDA) are separate. It is provided by wiring. The output terminal (SCL) of the serial clock signal of the host control circuit 210 (master) is connected to the input terminal (SCL) of the serial clock signal of each motor driver 271 (slave). The data input / output terminal (SDA) is connected to the serial data input / output terminal (SDA) of each motor driver 271. That is, in the present embodiment, a plurality of motor drivers 271 (slaves) are connected in parallel to the host control circuit 210 (master).

  In the present embodiment, the communication mode of the serial clock signal between the host control circuit 210 and each motor driver 271 is one-way communication in which the host control circuit 210 unidirectionally transmits the signal to each motor driver 271. On the other hand, the communication form of the serial data is bidirectional communication in which serial data can be input and output between the host control circuit 210 and each motor driver 271.

  Each motor driver 271 (slave) controls input / output of serial data based on a serial clock signal input from the host control circuit 210 (master). Each motor driver 271 (slave) is assigned a unique address, and the host control circuit 210 (master) transmits the serial data by designating the address of the motor driver 271 to which the serial data is to be transmitted. I do.

<Description of operation of main control circuit>
Next, the contents of various processes executed by the main CPU 71 of the main control circuit 70 will be described with reference to FIGS.

[Main control main processing]
First, the main control main process under the control of the main CPU 71 will be described with reference to FIG. FIG. 69 is a flowchart showing the procedure of the main control main process in this embodiment.

  When the pachinko gaming machine 1 is powered on, first, the main CPU 71 performs an initial setting process (S1). In this process, the main CPU 71 performs, for example, a process of permitting access to the main RAM 73, restoring a backup, and initializing a work area. Next, the main CPU 71 performs an update process of the initial value random number (S2). In this process, the main CPU 71 updates the initial random number counter value.

  Next, the main CPU 71 performs a special symbol control process (S3). In this process, the main CPU 71 performs a predetermined control process relating to the progress of the special symbol game and the special symbols (first special symbol and second special symbol) displayed on the special symbol display device 61. The details of the special symbol control process will be described later with reference to FIG. 70 described later.

  Next, the main CPU 71 performs a normal symbol control process (S4). In this process, the main CPU 71 performs a predetermined control process relating to the progress of the ordinary symbol game and the ordinary symbols displayed on the ordinary symbol display device 62. The details of the ordinary symbol control process will be described later with reference to FIG. 74 described later.

  Next, the main CPU 71 performs control processing of the symbol display device (S5). In this process, the main CPU 71 changes the special symbol (the first special symbol and the second special symbol) and the normal symbol based on the execution results of the special symbol control process (S3) and the normal symbol control process (S4). Controls display.

  Next, the main CPU 71 performs a game information data generation process (S6). In this process, the main CPU 71 generates game information data to be transmitted to the payout / launch control circuit 123, the sub control circuit 200, the hall computer of the game store, and the like, and stores the game information data in the main RAM 73.

  Next, the main CPU 71 performs a storage / game state data generation process (S7). In this process, the main CPU 71 generates storage / game state data to be transmitted to the sub control circuit 200 based on the value of the probable change flag and the value of the time saving flag, and stores the storage / game state data in the main RAM 73.

  Then, after the processing of S7, the main CPU 71 returns the processing to the processing of S2, and repeats the processing of S2 and thereafter.

[Special symbol control processing]
Next, the special symbol control process performed in S3 in the main control main process (see FIG. 69) will be described with reference to FIG. FIG. 70 is a flowchart showing the procedure of the special symbol control process in this embodiment. Note that the numerical values in parentheses (“00” to “08”) written next to the reference numerals of the respective processing steps shown in FIG. 70 indicate the values of the control state flags. Stored in the area. The main CPU 71 advances the special symbol game by executing each processing step corresponding to the numerical value of the control state flag.

  First, the main CPU 71 loads a control state flag (S11). In this process, the main CPU 71 reads the value of the control state flag stored in the main RAM 73.

  The main CPU 71 determines, based on the value of the control state flag loaded in S11, whether to execute various processes in S12 to S20 described below. This control state flag indicates the state of the game of the special symbol game, and enables execution of any one of S12 to S20.

  Further, the main CPU 71 executes the processing of each step at a predetermined timing determined according to the waiting time set for each processing of S12 to S20. In the period before reaching the predetermined timing, other subroutine processing is executed without executing the processing of each step. Further, a system timer interrupt process described later (see FIG. 76 described later) is also executed at a predetermined cycle.

  Then, when the processing of S11 ends, the main CPU 71 performs a special symbol storage check processing (S12).

  In this process, when the control state flag is a value (“00”) indicating the special symbol storage check process, the main CPU 71 checks the number of held special display variable displays, and if the number of held symbols is not “0”. In the case where there is a reserved ball, processing such as hit determination, determination of a special symbol, and determination of a variation pattern of the special symbol are performed. In this process, the main CPU 71 sets the control state flag to a value (“01”) indicating a special symbol variation time management process (S13) described later, and corresponds to the variation pattern determined in the current process. Set the fluctuation time of the special symbol in the waiting time timer. That is, by this processing, after the fluctuation time of the special symbol corresponding to the fluctuation pattern determined in the processing of S12 is set, the special symbol fluctuation time management processing described later is executed.

  On the other hand, when the reserved number is “0” (when there is no reserved ball), the main CPU 71 performs a demonstration display process for displaying a demonstration screen. The details of the special symbol storage check process will be described later with reference to FIG. 71 described later.

  Next, the main CPU 71 performs a special symbol variation time management process (S13). In this process, the main CPU 71 sets the control state flag to a value (“01”) indicating the special symbol variation time management process, and when the variation time of the special symbol has elapsed, displays the special symbol display described later in the control status flag. A value ("02") indicating the time management process (S14) is set, and the wait time after determination is set in the wait time timer. That is, this process is set so that the special symbol display time management process, which will be described later, is executed after the elapse of the wait time after determination set in the process of S13.

  Next, the main CPU 71 performs a special symbol display time management process (S14). In this processing, the main CPU 71 determines that the control state flag is a value (“02”) indicating the special symbol display time management processing, and that if the waiting time after determination set in the processing of S13 has elapsed, the result of the hit determination is determined. Is "big hit" or "small hit". When the result of the hit determination is “big hit” or “small hit”, the main CPU 71 sets a value (“03”) indicating a big hit start interval management process (S15) described later in the control state flag, The time corresponding to the big hit start interval is set in the waiting time timer. That is, by this process, after the time corresponding to the jackpot start interval set in the process of S14 has elapsed, the jackpot start interval management process described later is set to be executed.

  On the other hand, if the result of the hit determination is not “big hit” or “small hit”, the main CPU 71 sets a value (“08”) indicating a special symbol game end process (S20) described later in the control state flag. That is, in this case, it is set so that a special symbol game ending process described later is executed. The details of the special symbol display time management processing will be described later with reference to FIG. 72 described later.

  Next, when it is determined in S14 that the result of the hit determination is “big hit” or “small hit”, the main CPU 71 performs a big hit start interval management process (S15). In this process, the main CPU 71 sets the control state flag to the value (“03”) indicating the big hit start interval management process, and if the time corresponding to the big hit start interval set in the process of S14 has elapsed, the main CPU 71 executes the first process. In order to open the special winning opening 53 or the second special winning opening 54, the variables located in the main RAM 73 are updated based on the data read from the main ROM 72.

  In this process, the main CPU 71 sets the control state flag to a value (“04”) indicating the special winning opening process (S16) described later, and sets the maximum opening time of the special winning opening (for example, 30 seconds). Is set to the special winning opening time timer. In other words, this process is set so that a process during opening of the special winning opening described later is executed.

  Next, the main CPU 71 performs a special winning opening opening process (S16). In this processing, first, when the control state flag is a value (“04”) indicating the special winning opening processing, the condition that the special winning opening winning 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 special winning opening time timer is “0”) is satisfied (a predetermined closing condition is satisfied).

  In S16, when one of the conditions is satisfied, the main CPU 71 updates the variable positioned in the main RAM 73 in order to close the predetermined special winning opening (the first special winning opening or the second special winning opening). I do. Then, the main CPU 71 sets a value (“05”) indicating a large winning prize opening remaining ball monitoring process (S17) to be described later in the control state flag, and sets a monitoring time of the remaining sphere in the special winning opening to a waiting time timer. . That is, by this processing, after the prize-winning-port remaining ball monitoring time set in S17 elapses, it is set so that the after-mentioned winning prize opening residual ball monitoring processing is executed.

  In S16, the main CPU 71 transmits an inter-round display command to the sub control circuit 200 immediately before the end of the special winning opening processing.

  Next, the main CPU 71 performs a process for monitoring the remaining balls in the special winning opening (S17). In this process, the main CPU 71 determines that the control state flag is a value indicating the monitoring process of the remaining sphere in the special winning opening (“05”). It is determined whether or not the condition that the value is equal to or more than the maximum winning opening number (the last round) is satisfied.

  In S17, when the main CPU 71 determines that the above condition is not satisfied, the main CPU 71 sets a value ("06") indicating the special winning opening reopening waiting time management process in the control state flag. Further, the main CPU 71 sets a time corresponding to the interval between rounds in the waiting time timer. That is, by this processing, after the time corresponding to the interval between rounds elapses, the waiting time management processing before reopening of the special winning opening described later is set to be executed.

  On the other hand, when the main CPU 71 determines in S17 that the above condition is satisfied, the main CPU 71 sets a value indicating the big hit end interval processing (“07”) in the control state flag, and sets the time corresponding to the big hit end interval. (Big hit end interval time) is set in the waiting time timer. That is, by this processing, after the time corresponding to the big hit end interval set in S17 elapses, the big hit end interval processing described later is set to be executed.

  Next, in S17, when the main CPU 71 determines that the value of the special winning opening release frequency counter is not equal to or greater than the maximum value of the special winning opening number, the main CPU 71 performs a waiting time management process before reopening the special winning opening (S17). S18). In this process, the main CPU 71 sets the control state flag to a value ("06") indicating the waiting time management process before reopening the special winning opening, and when the time corresponding to the interval between rounds has elapsed, the main CPU 71 opens the special winning opening. The value of the number-of-times counter is stored and updated so as to increase by "1". Further, the main CPU 71 sets a value (“04”) indicating the processing during opening of the special winning opening in the control state flag. Then, the main CPU 71 sets the opening upper limit time (for example, 30 seconds) in the special winning opening time timer. That is, by this processing, the setting is made so that the above-described large winning opening processing (S16) is executed again after the processing of S18.

  Further, the main CPU 71 transmits a special winning opening opening command to the sub control circuit 200 immediately before the end of the special winning opening re-opening waiting time management process in S18.

  In S17, when the main CPU 71 determines that the value of the special winning opening number counter is equal to or more than the maximum value of the special opening opening number, the main CPU 71 performs a big hit end interval process (S19). In this process, the main CPU 71 determines that the control state flag is a value indicating the big hit end interval processing (“07”), and when the time corresponding to the big hit end interval elapses, the value indicating the special symbol game end processing (““ 08 ”) is set in the control state flag. That is, by this processing, it is set so that the special symbol game ending processing described later is executed after the processing of S19. The details of the big hit end interval processing will be described later with reference to FIG. 73 described later.

  Then, the main CPU 71 performs control to shift the gaming state to the probable variable gaming state when the big hit symbol is the positive variable symbol, and shifts the gaming state to the normal gaming state when the big hit symbol is the non-positive variable symbol. Is performed. When the big hit symbol is a symbol corresponding to the "small hit", the main CPU 71 determines that the game state after the "small hit" game is over from the gaming state controlled when the "small hit" is won. Is also controlled so as not to shift to an advantageous game state.

  Next, when the big hitting game state or the small hitting game state ends, or when "losing" is won, the main CPU 71 performs a special symbol game ending process (S20).

  In this process, when the control state flag is a value (“08”) indicating the special symbol game ending process, the main CPU 71 updates the data indicating the number of held items (starting storage information) by “1”. I do. Further, the main CPU 71 updates the special symbol storage area in order to perform the next special symbol change display. Further, the main CPU 71 sets a value (“00”) indicating the special symbol storage check process in the control state flag. That is, this process is set so that the special symbol storage check process (S12) described above is executed after the process of S20.

  Then, after the processing of S20, the main CPU 71 ends the special symbol control processing, and shifts the processing to S4 of the main control main processing (see FIG. 69).

  As described above, in the pachinko gaming machine 1 of the present embodiment, the special symbol game is advanced by sequentially setting various values in the control state flag. Specifically, when the gaming state is neither the big hitting gaming state nor the small hitting gaming state and the result of the hit determination is “losing”, the main CPU 71 sets the control state flags to “00”, “01”. , "02", and "08". Accordingly, the main CPU 71 performs the special symbol memory check process (S12), the special symbol variation time management process (S13), the special symbol display time management process (S14), and the special symbol game end process (S20) in this order. Execute at a predetermined timing.

  The main CPU 71 sets the control state flag to “00” or “00” if the gaming state is neither the big hitting gaming state nor the small hitting gaming state and the result of the hit determination is “big hit” or “small hit”. 01, 02, and 03. Accordingly, the main CPU 71 performs the special symbol storage check process (S12), the special symbol variation time management process (S13), the special symbol display time management process (S14), and the big hit start interval management process (S15) in this order. The control is executed at a predetermined timing, and the transition control to the big hit game state or the small hit game state is executed.

  Further, when the transition control to the big hitting game state or the small hitting game state is executed, the main CPU 71 sets the control state flags in the order of “04”, “05”, “06”. Accordingly, the main CPU 71 performs the above-described processing during opening of the special winning opening (S16), the processing for monitoring the remaining balls in the special winning opening (S17), and the waiting time management processing before reopening of the special winning opening (S18) in this order at a predetermined timing. To execute a big hit game or a small hit game.

  When the big hit game end condition is satisfied during the big hit game, the main CPU 71 sets the control state flags in the order of "04", "05", "07", and "08". Accordingly, the main CPU 71 executes the above-described processing during opening of the special winning opening (S16), the processing for monitoring the remaining balls in the special winning opening (S17), the processing for ending the big hit (S19), and the processing for ending the special symbol game (S20) in this order. The game is executed at a predetermined timing, and the big hit game state ends.

  As described above, in the special symbol control processing, the processing flow is branched according to the status. Also, in the normal symbol control process of S4 in the main control main process shown in FIG. 69 (see FIG. 74 described later), the process flow is branched according to the status, similarly to the special symbol control process, as described later. .

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

[Special design memory check process]
Next, the special symbol storage check process performed in S12 during the special symbol control process (see FIG. 70) will be described with reference to FIG. FIG. 71 is a flowchart showing the procedure of the special symbol storage check process in this embodiment.

  First, the main CPU 71 loads a control state flag (S31). In this process, the main CPU 71 reads the value of the control state flag stored in the main RAM 73.

  Next, the main CPU 71 determines whether or not the control state flag is a value ("00") indicating the special symbol storage check process (S32). In S32, if the main CPU 71 determines that the control state flag is not “00” (if S32 is NO), the main CPU 71 ends the special symbol storage check process, and executes the special symbol control process (FIG. 70). Back to see).

  On the other hand, in S32, when the main CPU 71 determines that the control state flag is “00” (in the case of YES determination in S32), the main CPU 71 determines whether or not the second starting opening winning (variable display of the second special symbol) is to be performed. It is determined whether or not the suspended number (the second start storage number) is “0” (S33).

  In S33, when the main CPU 71 determines that the number of held second starting opening winnings is not “0” (NO in S33), the main CPU 71 sets the second starting opening corresponding to the number of held second starting opening winning. “1” is subtracted from the value of the start storage number (S34).

  In the present embodiment, the main CPU 71 determines whether data is stored in the second special symbol start storage area (0) to the second special symbol start storage area (4) provided in the main RAM 73, It is determined whether or not there is a memory for starting the special symbol game corresponding to the variable display of the second special symbol being changed or being held. In the second special symbol start storage area (0), data (information) of the special symbol game corresponding to the variable display of the changing second special symbol is stored as start memory. In the second special symbol start storage area (1) to the second special symbol start storage area (4), a special symbol game corresponding to the variable display (holding ball) of the second special symbol held for four times. Is stored as start-up memory. The data included in the start memory stored in each second special symbol start storage area is, for example, data such as a random number for a jackpot determination and a random number for a jackpot symbol acquired at the time of winning the second starting port 45. .

  After the process of S34, the main CPU 71 performs a special symbol storage transfer process based on the second winning opening winning (S35). In this process, the main CPU 71 transfers (stores) the data in the second special symbol start storage areas (1) to (4) to the second special symbol start storage areas (0) to (3), respectively. Then, after the processing in S35, the main CPU 71 performs the processing in S40 described later.

  Here, returning to the process of S33 again, in S33, when the main CPU 71 determines that the number of held second winning opening winnings is “0” (if S33 is YES), the main CPU 71 It is determined whether or not the number of retained first winning openings (variable display of the first special symbol) (the first number of stored starts) is "0" (S36).

  In S36, when the main CPU 71 determines that the number of pending first opening winnings is “0” (YES in S36), the main CPU 71 performs a demo display process (S37). Then, after the process of S37, the main CPU 71 ends the special symbol storage check process, and returns the process to the special symbol control process (see FIG. 70).

  In the demonstration display process of S37, the main CPU 71 sets a demonstration display permission value in the main RAM 73. In other words, the main CPU 71 determines that the state in which the number of retained first start-port winning and the second starting-port winning is “0” (the state in which the start memory of the special symbol game is “0”) is a predetermined time (for example, If it is maintained for 30 seconds, a predetermined value is set as the demonstration display permission value. When the demonstration display permission value is the predetermined value in the demonstration display process of S37, the main CPU 71 sets the demonstration display command data in the main RAM 73. Then, the demonstration display command data is transmitted from the main CPU 71 of the main control circuit 70 to the host control circuit 210 in the sub control circuit 200. When receiving the demonstration display command data, the sub-control circuit 200 causes the display area 13 a of the display device 13 to display a demonstration screen.

  On the other hand, in S36, when the main CPU 71 determines that the number of retained first opening winnings is not “0” (if S36 is NO), the main CPU 71 corresponds to the number of retained first winning opening. "1" is subtracted from the value of the first start storage number (S38).

  In the present embodiment, the main CPU 71 determines whether data is stored in the first special symbol start storage area (0) to the first special symbol start storage area (4) provided in the main RAM 73, It is determined whether or not there is a start memory of a special symbol game corresponding to the variable display of the first special symbol being changed or being held. In the first special symbol start storage area (0), data (information) of the special symbol game corresponding to the variable display of the changing first special symbol is stored as start memory. In the first special symbol start storage area (1) to the first special symbol start storage area (4), a special symbol game corresponding to the variable display (reserved ball) of the first four special symbols held for four times. Is stored as start-up memory. The data included in the start memory stored in each of the first special symbol start storage areas is, for example, data such as a random number for jackpot determination and a random number for the jackpot symbol acquired at the time of winning the first starting port 44. .

  After the process in S38, the main CPU 71 performs a special symbol storage transfer process based on the winning in the first opening (S39). In this process, the main CPU 71 transfers (stores) the data in the first special symbol start storage areas (1) to (4) to the first special symbol start storage areas (0) to (3), respectively. Then, after the processing of S39, the main CPU 71 performs the processing of S40 described later.

  Next, after the processing of S35 or S39, the main CPU 71 determines whether or not the value of the time saving state change frequency counter is “0” (S40).

  In S40, when the main CPU 71 determines that the value of the number-of-time-shorted-state variation counter is “0” (YES in S40), the main CPU 71 performs the process of S44 described later. On the other hand, in S40, when the main CPU 71 determines that the value of the time reduction state change frequency counter is not “0” (NO in S40), the main CPU 71 subtracts “1” from the value of the time reduction state change frequency counter. (S41).

  After the processing in S41, the main CPU 71 determines whether or not the value of the number-of-time-save-state-change number counter is “0” (S42).

  In S42, when the main CPU 71 determines that the value of the number-of-time-shorted-state variation counter is not “0” (NO in S42), the main CPU 71 performs the processing of S44 described later. On the other hand, in S42, when the main CPU 71 determines that the value of the number-of-time-save-state-change counter is “0” (if S42 is YES), the main CPU 71 sets the time-saving flag to “0” (S43). ).

  After S43, if S40 is YES or S42 is NO, the main CPU 71 sets the control state flag to a value ("01") indicating the special symbol variation time management process (S44). In this process, the main CPU 71 transmits a hold subtraction command and a special symbol effect start command to the sub control circuit 200.

  Next, the main CPU 71 performs a big hit determination process (S45). In this process, the main CPU 71 determines (determines) which one of "big hit", "small hit" and "losing" has been won by lottery, based on the random number for jackpot determination acquired at the time of winning the starting opening.

  Next, the main CPU 71 clears information (data) of the storage area used for the previous variable display (S46). Next, the main CPU 71 sets the fluctuation time corresponding to the determined special pattern fluctuation pattern in the waiting time timer (S47). Then, after the processing of S47, the main CPU 71 ends the special symbol storage check processing, and returns the processing to the special symbol control processing (see FIG. 70).

[Special symbol display time management processing]
Next, the special symbol display time management process performed in S14 during the special symbol control process (see FIG. 70) will be described with reference to FIG. FIG. 72 is a flowchart showing the procedure of the special symbol display time management processing in this embodiment.

  First, the main CPU 71 determines whether or not the control state flag is a value (“02”) indicating the special symbol display time management processing (S51). In S51, when the main CPU 71 determines that the control state flag is not the value (“02”) indicating the special symbol display time management processing (if S51 is NO), the main CPU 71 executes the special symbol display time management processing. The process ends, and the process returns to the special symbol control process (see FIG. 70).

  On the other hand, in S51, when the main CPU 71 determines that the control state flag is a value (“02”) indicating the special symbol display time management processing (if S51 is YES), the main CPU 71 sets the waiting time timer to It is determined whether or not the value (waiting time) is “0” (S52). In this process, the main CPU 71 determines whether or not the waiting time after the change set in the waiting time timer (change starting waiting time) has been consumed.

  In S52, if the main CPU 71 determines that the value of the waiting time timer is not “0” (if S52 is NO), the main CPU 71 ends the special symbol display time management process, and executes the special symbol control process. (See FIG. 70). On the other hand, in S52, if the main CPU 71 determines that the value of the waiting time timer is “0” (if S52 is YES), the main CPU 71 determines whether or not the special symbol game is “big hit”. It is determined (S53). In this process, the main CPU 71 simultaneously transmits a special effect stop command to the sub control circuit 200.

  In S53, when the main CPU 71 determines that the special symbol game is not “big hit” (NO in S53), the main CPU 71 sets a value (“08”) indicating the special symbol game end process in the control state flag. It is set (S54). Then, after the processing of S54, the main CPU 71 ends the special symbol display time management processing, and returns the processing to the special symbol control processing (see FIG. 70).

  On the other hand, in S53, when the main CPU 71 determines that the special symbol game is "big hit" (if S53 is YES), the main CPU 71 sets the big hit flag to ON state (S55). The big hit flag is a flag indicating whether or not to play a big hit game.

  Next, the main CPU 71 clears the value of the time saving state change frequency counter, the value of the time saving flag, and the value of the probability change flag (S56). Next, the main CPU 71 sets a value ("03") indicating the big hit start interval management process in the control status flag (S57).

  Next, the main CPU 71 sets the big hit start interval time (for example, 5000 msec) corresponding to the special symbol (the first special symbol or the second special symbol) in the waiting time timer (S58). Next, the main CPU 71 sets a big hit start command (special symbol hit start display command) corresponding to the special symbol in the main RAM 73 (S59). In this process, the main CPU 71 simultaneously transmits a special symbol hit start display command to the sub control circuit 200.

  Next, the main CPU 71 sets the round number display LED pattern flag to the ON state (S60). The round number display LED pattern flag is a flag indicating whether or not the remaining round number is displayed in a predetermined pattern. After the processing of S60, the main CPU 71 ends the special symbol display time management processing, and returns the processing to the special symbol control processing (see FIG. 70).

[Big hit end interval processing]
Next, with reference to FIG. 73, the big hit end interval processing performed in S19 in the special symbol control processing (see FIG. 70) will be described. FIG. 73 is a flowchart showing the procedure of the big hit end interval process in this embodiment.

  First, the main CPU 71 determines whether or not the control state flag is a value ("07") indicating the big hit end interval processing (S71).

  In S71, when the main CPU 71 determines that the control state flag is not the value indicating the big hit end interval processing (“07”) (NO in S71), the main CPU 71 ends the big hit end interval processing, and Is returned to the special symbol control process (see FIG. 70). On the other hand, in S71, when the main CPU 71 determines that the control state flag is a value indicating the jackpot end interval processing (“07”) (if S71 is YES), the main CPU 71 determines that the value of the waiting time timer is It is determined whether it is "0" (S72). In this processing, the main CPU 71 determines whether or not the big hit end interval time set in the waiting time timer has been exhausted.

  In S72, when the main CPU 71 determines that the value of the waiting time timer is not "0" (NO in S72), the main CPU 71 ends the big hit end interval process, and executes the special symbol control process (FIG. 70). On the other hand, in S72, when the main CPU 71 determines that the value of the waiting time timer is “0” (YES in S72), the main CPU 71 clears the large winning opening opening number display LED pattern flag (S72). S73).

  Next, the main CPU 71 clears the round number distribution flag (sets it to “0”) (S74).

  Next, the main CPU 71 sets a value ("08") indicating the special symbol game end processing in the control state flag (S75). In this process, the main CPU 71 simultaneously transmits a special symbol hit end display command to the sub control circuit 200. Next, the main CPU 71 clears the big hit flag (S76).

  Next, the main CPU 71 refers to the big hit type determination table (see FIGS. 20 to 23), and sets the value of the probability change flag based on the gaming state at the time of the big hit and the type of the big hit selected symbol command (S77). . Next, the main CPU 71 refers to the big hit type determination table (see FIGS. 20 to 23) and sets the value of the time reduction flag based on the gaming state at the time of the big hit and the type of the big hit selected symbol command (S78). .

  Next, the main CPU 71 determines whether or not the value of the time reduction flag is “1” (whether the time reduction flag is on) (S79). In S79, when the main CPU 71 determines that the value of the time reduction flag is not “1” (NO in S79), the main CPU 71 ends the big hit end interval processing, and executes the special symbol control processing (FIG. 70). Back to see).

  On the other hand, in S79, when the main CPU 71 determines that the value of the time reduction flag is “1” (if S79 is YES), the main CPU 71 refers to the big hit type determination table (see FIGS. 20 to 23). Then, based on the gaming state at the time of the big hit winning and the type of the big hit selection symbol command, the value of the corresponding time saving number is set in the time saving state change number counter (S80). Then, after the processing of S80, the main CPU 71 ends the big hit end interval processing, and returns the processing to the special symbol control processing (see FIG. 70).

[Normal symbol control processing]
Next, with reference to FIG. 74, the ordinary symbol control process performed in S4 in the main control main process (see FIG. 69) will be described. FIG. 74 is a flowchart showing the procedure of the ordinary symbol control process in this embodiment.

  Numerical values in parentheses (“00” to “04”) written next to the reference numerals of the respective processing steps in the flowchart shown in FIG. 74 indicate a normal symbol control state flag. Is stored in a predetermined storage area. The main CPU 71 advances the normal symbol game by executing each processing step corresponding to the numerical value of the normal symbol control state flag.

  First, the main CPU 71 loads a normal symbol control state flag (S91). In this process, the main CPU 71 reads out the ordinary symbol control state flag stored in the main RAM 73. The main CPU 71 determines, based on the value of the ordinary symbol control state flag loaded in S91, whether to execute various processes in S92 to S96 described below. The normal control control state flag indicates the state of the game of the normal symbol game, and enables execution of any one of S92 to S96.

  Further, the main CPU 71 executes the processing of each step at a predetermined timing determined according to a waiting time set for each processing of S92 to S96. In the period before reaching the predetermined timing, other subroutine processing is executed without executing the processing of each step. Further, a system timer interrupt process described later (see FIG. 76 described later) is also executed at a predetermined cycle.

  Then, when the processing of S91 ends, the main CPU 71 performs a normal symbol storage check processing (S92).

  In this process, when the ordinary symbol control state flag is a value (“00”) indicating the ordinary symbol memory check process, the main CPU 71 checks the number of suspended symbols for variable display of ordinary symbols, and the number of symbols retained is “0”. If not, a process such as a hit determination is performed. Further, in this processing, the main CPU 71 sets a value (“01”) indicating the later-described ordinary symbol variation time monitoring process (S93) in the ordinary symbol control state flag, and sets the variation time determined in the current process. Set the wait time timer. That is, by this processing, after the fluctuation time of the ordinary symbol determined in the processing of S92 elapses, the normal symbol fluctuation time monitoring processing described later is set to be executed.

  Next, the main CPU 71 performs a normal symbol variation time monitoring process (S93). In this processing, the main CPU 71 sets the ordinary symbol control status flag to a value (“01”) indicating the ordinary symbol variation time monitoring process, and sets the ordinary symbol control status flag to the later-described symbol when the variation time of the ordinary symbol has elapsed. The value ("02") indicating the normal symbol display time monitoring process (S94) is set, and the wait time after confirmation (for example, 0.5 sec) is set in the wait time timer. That is, by this processing, after the waiting time after determination set in the processing of S93 has elapsed, it is set so that the later-described ordinary symbol display time monitoring processing is executed.

  Next, the main CPU 71 performs a normal symbol display time monitoring process (S94). In this process, the main CPU 71 determines that the normal symbol control state flag is a value (“02”) indicating the normal symbol display time monitoring process, and determines whether a hit has occurred if the waiting time after determination set in the process of S93 has elapsed. It is determined whether or not the result is “hit”. When the result of the hit determination is “hit”, the main CPU 71 performs a normal electric accessory opening setting process, and sets a value (step S95) indicating a normal electric accessory opening process (S95) described later in the normal symbol control state flag. "03") is set. That is, the processing is set so that the ordinary electric accessory opening processing described later is executed by this processing.

  On the other hand, if the result of the hit determination is not “hit”, the main CPU 71 sets a value (“04”) indicating a normal symbol game end process (S96) described later in the ordinary symbol control state flag. That is, in this case, it is set so that a later-described ordinary symbol game ending process is executed.

  Next, when the result of the hit determination is determined to be "hit" in S94, the main CPU 71 performs a normal electric accessory opening process (S95). In this process, when the normal symbol control state flag has the value (“03”) indicating the normal electric accessory opening process, the main CPU 71 has received a predetermined number of start winnings while the ordinary electric accessory 46 is being opened. It is determined whether one of the following condition and the condition that the opening upper limit time of the ordinary electric accessory 46 has elapsed (the ordinary electric opening time timer is “0”) are satisfied.

  In S95, when one of the above conditions is satisfied, the main CPU 71 updates a variable positioned in the main RAM 73 in order to close the blade member, which is the ordinary electric accessory 46. Then, the main CPU 71 sets a value (“04”) indicating a later-described ordinary symbol game end process (S96) in the ordinary symbol control state flag. That is, this process is set so that a later-described ordinary symbol game end process is executed.

  Next, the main CPU 71 performs a normal symbol game end process (S96). In this process, when the normal symbol control state flag is a value (“04”) indicating the normal symbol game end process, the main CPU 71 reduces the data indicating the number of suspended variable symbols of the ordinary symbol by “1”. Is updated. Further, the main CPU 71 updates the ordinary symbol storage area in order to perform the next variation display of the ordinary symbol. Further, the main CPU 71 sets a value (“00”) indicating the normal symbol storage check process in the ordinary symbol control state flag. That is, this process is set so that the above-described ordinary symbol storage check process (S92) is executed after the process of S96.

  Then, after the processing of S96, the main CPU 71 ends the ordinary symbol control processing, and moves the processing to S5 of the main control main processing (see FIG. 69).

[Power-on processing]
Next, the power-on processing executed by the main CPU 71 will be described with reference to FIG. FIG. 75 is a flowchart showing the procedure of the power-on processing in the present embodiment.

  First, the main CPU 71 sets a predetermined initial value in the stack pointer (S101). Next, the main CPU 71 determines whether or not the power interruption detection signal is in an off state (LOW level) (S102). In this determination process, the case where the power interruption detection signal is in the OFF state corresponds to the case where the power interruption detection process is not in an executable state. That is, in a state where the power interruption can be detected, the power interruption detection signal is turned on.

  In S102, when the main CPU 71 determines that the power interruption detection signal is in the OFF state (LOW level) (in the case of YES determination in S102), the main CPU 71 sets the power interruption detection signal to the ON state (HIGH level). Until the determination process of S102 is repeated. On the other hand, in S102, when the main CPU 71 determines that the power interruption detection signal is not in the OFF state (LOW level) (NO in S102), the main CPU 71 executes the built-in RWM (Read Write Memory), An access permission process to the RAM 73 is performed (S103). In this process, the main CPU 71 performs various initialization processes such as a process of initializing a work area of the main RAM 73, for example.

  Next, the main CPU 71 performs a sub-control reception acceptance wait process (S104). In this process, the main CPU 71 waits until the operation state of the sub-control circuit 200 becomes a state in which data such as command data can be accepted. Next, the main CPU 71 performs an initialization process of a device incorporating the CPU (S105).

  Next, the main CPU 71 determines whether or not the backup clear signal is in the ON state (HIGH level) (S106). Specifically, the main CPU 71 determines whether or not the backup clear switch 121 (see FIG. 5) is on.

  In S106, when the main CPU 71 determines that the backup clear signal is in the ON state (when S106 is determined to be YES), the main CPU 71 performs the process of S113 described later. On the other hand, in S106, when the main CPU 71 determines that the backup clear signal is not in the ON state (NO in S106), the main CPU 71 sets the power interruption detection flag (when the value of the power interruption detection flag is It is determined whether it is "1") (S107).

  In S107, if the main CPU 71 determines that the power interruption detection flag is not set (if S107 is NO), the main CPU 71 performs the process of S113 described later. On the other hand, in S107, when the main CPU 71 determines that the power interruption detection flag is set (in the case of YES determination in S107), the main CPU 71 performs a work area damage check process (S108). In this process, the main CPU 71 checks whether or not the work area is damaged based on the checksum value or the like.

  After the processing in S108, the main CPU 71 determines whether or not the work area is normal based on the result of the damage check processing for the work area in S108 (S109). In S109, when the main CPU 71 determines that the work area is not normal (NO in S109), the main CPU 71 performs the process of S113 described later.

  On the other hand, in S109, when the main CPU 71 determines that the work area is normal (YES in S109), the main CPU 71 performs a work area initial setting process that requires an initial value to be set when power is restored. Is performed (S110). Next, the main CPU 71 performs a notification setting process of the high-probability gaming state at the time of power-off recovery (S111).

  After the processing in S111, the main CPU 71 transmits a power-off recovery command to the sub control circuit 200 (S112). In this process, the main CPU 71 transmits the above-described first and second power interruption recovery commands (see FIGS. 32 and 33) to the sub control circuit 200. After the processing of S112, the main CPU 71 ends the power-on processing.

  Here, returning to the processing of S106, S107 or S109 again, if S106 is determined to be YES, or if S107 or S109 is determined to be NO, that is, the pachinko gaming machine 1 is returned to the state before the power failure detection. If not, the main CPU 71 clears all the work areas (S113).

  Next, the main CPU 71 performs an initial setting process of a work area that requires an initial value to be set when the main RAM 73 is initialized (S114). Next, the main CPU 71 transmits an initialization command for the main RAM 73 to the sub control circuit 200 (S115). Then, after the processing of S115, the main CPU 71 ends the power-on processing.

[System timer interrupt processing]
In the pachinko gaming machine 1 of the present embodiment, the main CPU 71 interrupts the main process at a predetermined cycle and executes a system timer interrupt process even during the execution of the main process. Specifically, the main CPU 71 executes a system timer interrupt process in response to a clock pulse generated from the clock generation circuit 74 at a predetermined cycle (for example, 2 msec). Here, the system timer interrupt processing executed by the main CPU 71 will be described with reference to FIG. FIG. 76 is a flowchart showing the procedure of the system timer interrupt processing in the present embodiment.

  First, the main CPU 71 saves the data (information) of each register (S121). Next, the main CPU 71 performs a random number update process (S122). In this process, the main CPU 71 updates various random numbers extracted from the big hit determination counter, the symbol determination counter, the hit determination counter, the fall determination counter, the variation pattern determination counter, the effect pattern determination counter, and the like. . Note that the jackpot determination counter and the symbol determination counter lack fairness if the counter value update timing is undefined. Therefore, the big hit determination counter and the symbol determination counter are updated at a fixed timing in a cycle of 2 msec in order to ensure fairness.

  Next, the main CPU 71 performs a switch input detection process (S123). In this process, the main CPU 71 detects a winning or passing to various starting ports, various winning ports, and the ball passing detector 43. The details of the switch input detection process will be described later with reference to FIG. 77 described later.

  Next, the main CPU 71 performs a timer update process (S124). Specifically, the main CPU 71 includes various timers such as a waiting time timer for synchronizing the main control circuit 70 and the sub control circuit 200, and a special winning opening time timer for measuring the opening time of the special winning opening. Update processing.

  Next, the main CPU 71 performs a command output process (S125). In this process, the main CPU 71 outputs, to the host control circuit 210 of the sub-control circuit 200, various commands (see FIGS. 29 to 34) such as a winning command and a fluctuation command, for example.

  Next, the main CPU 71 performs a game information output process (S126). In this process, the main CPU 71 outputs various information related to the game processed by the main control circuit 70, the sub control circuit 200, the payout / firing control circuit 123, and the like to the hall computer of the game store.

  Next, the main CPU 71 restores the data of each register saved in S121 (S127). Then, after the processing of S127, the main CPU 71 ends the system timer interrupt processing.

[Switch input detection processing]
Next, the switch input detection process performed in S123 during the system timer interrupt process (see FIG. 76) will be described with reference to FIG. FIG. 77 is a flowchart illustrating the procedure of the switch input detection process according to the present embodiment.

  First, the main CPU 71 performs a winning opening winning detection process (S131). In this process, the main CPU 71 determines whether or not a game ball has entered (passed) the first starting port 44 or the second starting port 45. That is, the main CPU 71 detects whether or not the winning of the game ball is detected by the first starting opening winning ball sensor 44a or the second starting opening winning ball sensor 45a. The details of the start-up winning detection processing will be described later with reference to FIG. 78 described later.

  Next, the main CPU 71 performs a general winning opening passage detection process (S132). In this process, the main CPU 71 determines whether or not a game ball has entered the general winning opening 51 or 52. That is, the main CPU 71 detects whether or not the winning of the game ball is detected by the general winning ball sensor 51a or 52a. Then, when a winning of a game ball to the general winning opening 51 or 52 is detected, the main CPU 71 performs various predetermined processes corresponding to the winning.

  Next, the main CPU 71 performs a special winning opening passage detection process (S133). In this process, the main CPU 71 determines whether or not a game ball has entered the first special winning opening 53 or the second special winning opening 54. That is, the main CPU 71 detects whether or not the winning of the game ball is detected by the first winning port solenoid 53b or the second winning port solenoid 54b. Then, when a winning of the game ball to the first big winning opening 53 or the second big winning opening 54 is detected, the main CPU 71 performs various predetermined processes corresponding to the winning.

  Next, the main CPU 71 performs a gate passage detection process (S134). In this process, the main CPU 71 determines whether the game ball has passed the ball passage detector 43 or not. That is, the main CPU 71 detects whether or not the passing of the game ball is detected by the passing ball sensor 43a. Next, when it is detected that the game ball has passed the ball passage detector 43, the main CPU 71 performs various predetermined processes corresponding to the passage. Then, after the processing of S134, the main CPU 71 ends the switch input detection processing, and moves the processing to S124 of the system timer interrupt processing (see FIG. 76).

[Start opening winning detection process]
Next, with reference to FIG. 78, a description will be given of the starting port winning detection processing performed in S131 in the switch input detection processing (see FIG. 77). FIG. 77 is a flowchart illustrating the procedure of the start-up winning detection processing in the present embodiment.

  First, the main CPU 71 determines whether or not a winning of a game ball to the first starting port 44 is detected based on an output signal of the first starting port winning ball sensor 44a (S141).

  In S141, when the main CPU 71 determines that the winning of the game ball to the first starting port 44 has not been detected (NO in S141), the main CPU 71 performs the process of S149 described later. On the other hand, in S141, when the main CPU 71 determines that the winning of the game ball to the first starting port 44 has been detected (if S141 is YES), the main CPU 71 determines the payout information corresponding to the first starting port winning. Is set in the main RAM 73 (S142). In the present embodiment, when a game ball wins the first starting port 44, a predetermined number of game balls are paid out. Therefore, in the process of S142, payout information of a predetermined number of game balls is set.

  After the processing of S142, the main CPU 71 determines whether or not the number of reserves (the number of reserved balls) of the first starting opening winning (variable display of the first special symbol) is less than “4” (S143).

  In S143, when the main CPU 71 determines that the number of retained first opening winnings is not less than “4” (NO in S143), the main CPU 71 performs the process of S149 described later. On the other hand, in S143, when the main CPU 71 determines that the number of pending first opening openings is less than “4” (YES in S143), the main CPU 71 determines the number of retained first opening openings. A process of adding "1" is performed (S144).

  After the process of S144, the main CPU 71 acquires various random numbers used for the lottery, and stores the acquired various random values in a predetermined area of the main RAM 73 (S145). Specifically, the main CPU 71 obtains various random numbers such as a big hit determination random number, a symbol random number, and a fall determination random number.

  Next, the main CPU 71 performs a first special stop symbol determination process (S146). In this process, the main CPU 71 refers to the big hit random number determination table (first starting port) (see FIG. 16) and the symbol determination table (first starting port) (see FIG. 18), and obtains the big hit determination randomness acquired in S145. Based on the numerical value and the symbol random number value, it is determined whether or not a “big hit”. In the case of a “big hit”, a big hit symbol (effect identification symbol) to be displayed on the display screen of the display device 13 is determined. Make a selection (judgment).

  Next, the main CPU 71 performs a process of determining whether there is a fall (S147). In this process, the main CPU 71 performs a drop lottery based on the random number for fall determination acquired in S145, and determines whether or not a fall has occurred. Thereby, the main CPU 71 acquires the drop lottery information (“0”: no fall, or “1”: there is a fall).

  Next, the main CPU 71 sets the hold addition command data at the time of winning the first starting opening in the main RAM 73 (S148).

  In this process, the main CPU 71 determines the big hit random number determination table (first starting port) (see FIG. 16), the symbol judgment table (first starting port) (see FIG. 18), and the big hit type determination table (see FIGS. 20 to 23). ) And the winning effect information determination table (see FIG. 24), which are obtained by referring to the gaming state ("normal", "probable change", "time saving"), and the winning type ("big hit", "small hit", "losing"). )), A storage addition command based on information such as the starting storage number (the number of holdings of the first special symbol), a symbol designating command, a big hit selection symbol command, a winning effect information, a big hit determination result information, and a fall lottery information. The information (transmission contents) to be included in is determined.

  At this time, the gaming state is acquired by referring to the values of the probability change flag and the time saving flag, and the winning type is acquired by referring to the jackpot random number determination table (first starting port) (see FIG. 16). The symbol designation command and the big hit selection symbol command are obtained by referring to the symbol determination table (first starting port) (see FIG. 18), and the winning effect information is a winning effect information determination table (see FIG. 24). Is obtained by referring to. In addition, the result information of the big hit determination is obtained in the process of S146, and the fall lottery information is obtained in the process of S147.

  Further, in the present embodiment, in the process of S148, the hold addition command at the time of winning the first starting opening is transmitted from the main CPU 71 to the sub control circuit 200 (host control circuit 210). Then, based on the hold addition command at the time of winning the first starting opening, the sub-control circuit 200 selects an effect pattern of the hold effect and the look-ahead effect.

  After the process of S148, or in the case of NO determination in S141 or S143, the main CPU 71 determines whether or not winning of a game ball to the second starting port 45 is detected based on the output signal of the second starting port winning ball sensor 45a. It is determined whether or not it is (S149).

  In S149, when the main CPU 71 determines that the winning of the game ball to the second starting opening 45 has not been detected (NO in S149), the main CPU 71 ends the starting opening winning detection process, and executes the processing. To S132 of the switch input detection process (see FIG. 77). On the other hand, in S149, when the main CPU 71 determines that the winning of the game ball to the second starting port 45 has been detected (YES in S149), the main CPU 71 determines the payout information corresponding to the second starting port winning. Is set in the main RAM 73 (S150). In the present embodiment, when a game ball wins in the second starting port 45, a predetermined number of game balls are paid out. Therefore, in the process of S150, the payout information of a predetermined number of game balls is set.

  After the processing of S150, the main CPU 71 determines whether or not the number of reserves (the number of reserved balls) of the second starting opening winning (variable display of the second special symbol) is less than “4” (S151).

  In S151, if the main CPU 71 determines that the number of retained second starting opening winnings is not less than "4" (NO in S151), the main CPU 71 ends the starting opening winning detection process and switches the process. The process moves to S132 of the input detection process (see FIG. 77). On the other hand, in S151, when the main CPU 71 determines that the number of retained second winning opening prizes is less than “4” (if S151 is YES), the main CPU 71 determines the number of retained second winning opening prizes. A process of adding “1” is performed (S152). After the processing of S152, the main CPU 71 acquires various random numbers used for the lottery, and stores the acquired various random values in a predetermined area of the main RAM 73 (S153). Specifically, the main CPU 71 obtains various random numbers such as a big hit determination random number, a symbol random number, and a fall determination random number.

  Next, the main CPU 71 performs a second special stop symbol determination process (S154). In this process, the main CPU 71 refers to the big hit random number determination table (second starting port) (see FIG. 17) and the symbol determination table (second starting port) (see FIG. 19), and obtains the big hit determination randomness acquired in S153. Based on the numerical value and the symbol random number value, it is determined whether or not it is a "big hit". In the case of a big hit, selection of a big hit symbol (effect identification symbol) to be displayed on the display screen of the display device 13 ( Judgment).

  Next, the main CPU 71 performs a process of determining the presence or absence of a fall (S155). In this process, the main CPU 71 performs a drop lottery based on the random number for fall determination acquired in S153, and determines whether or not a fall has occurred. Thereby, the main CPU 71 acquires the drop lottery information (“0”: no fall, or “1”: there is a fall).

  Next, the main CPU 71 sets the hold addition command data at the time of winning the second starting opening in the main RAM 73 (S156).

  In this process, the main CPU 71 determines the big hit random number determination table (second starting port) (see FIG. 17), the symbol judgment table (second starting port) (see FIG. 19), and the big hit type determination table (see FIGS. 20 to 23). ) And the winning-state effect information determination table (see FIG. 24), the gaming state ("normal", "probable change", "time saving"), the winning type ("big hit", "losing"), and the starting memory. Information to be included in the hold addition command based on information such as the number (holding number of the second special symbol), the symbol designation command, the big hit selection symbol command, the winning effect information, the big hit determination result information, the fall lottery information, and the like ( Transmission contents).

  At this time, the gaming state is acquired by referring to the values of the probability change flag and the time saving flag, and the winning type is acquired by referring to the jackpot random number determination table (second starting port) (see FIG. 17). The symbol designation command and the big hit selection symbol command are obtained by referring to the symbol determination table (second starting opening) (see FIG. 19), and the winning effect information is a winning effect information determining table (see FIG. 24). Is obtained by referring to. In addition, the information on the result of the jackpot determination is obtained in the process of S154, and the fall lottery information is obtained in the process of S155.

  Further, in the present embodiment, in the process of S156, the hold addition command at the time of winning the second starting opening is transmitted from the main CPU 71 to the sub control circuit 200 (host control circuit 210). The sub-control circuit 200 selects an effect pattern of the hold effect and the look-ahead effect based on the hold addition command at the time of winning the second starting opening. Then, after the processing of S156, the main CPU 71 ends the start-up winning detection processing, and moves the processing to S132 of the switch input detection processing (see FIG. 77).

<Description of operation of sub-control circuit>
Next, contents of various processes executed by various control circuits in the sub-board 202 of the sub-control circuit 200 will be described with reference to FIGS. The sub control circuit 200 receives various commands transmitted from the main control circuit 70 and performs various processes based on the various commands.

[Sub-control main processing]
First, the sub-control main processing executed by the host control circuit 210 will be described with reference to FIG. FIG. 79 is a flowchart showing the procedure of the sub-control main process in this embodiment. The sub-control main process is a process that is started when the power is turned on.

  First, the host control circuit 210 performs an initialization process (S201). In this process, the host control circuit 210 performs various initialization processes such as hardware initialization, device initialization, application (various processes) initialization, and backup data restoration initialization. The details of the initialization process will be described later with reference to FIGS. 80 and 81 described later.

  Next, the host control circuit 210 clears the counter of the watchdog timer (S202). At the time of activation, a reset time (for example, 200 msec) of the watchdog timer is set, and thereafter, when the writing of the service pulse is not performed (at the time of timeout), the power interruption processing is started. The watchdog timer counter is cleared at the start of the main loop process (the processes of S202 to S212) in the sub-control main process, at the start of the device initialization process, at the start of the application initialization process, and at the time of power interruption. It is at the start of processing.

  Next, the host control circuit 210 performs an operation means input process (S203). In this process, the host control circuit 210 performs a process of determining whether or not the player has operated an operation unit such as a button or a jog dial, and a process of acquiring information on the operation content. The details of the operation means input processing will be described later with reference to FIGS.

  Next, the host control circuit 210 performs a main / sub command control process (S204). In this process, the host control circuit 210 performs a process of reading command data when receiving command data from the main CPU 71 (command reception process) and a process of storing command data in the subwork RAM 210a (reception data storage process). The details of the main / sub command control process will be described later with reference to FIGS. 88 and 89 described later.

  Next, the host control circuit 210 performs a command analysis process (S205). In this process, the host control circuit 210 analyzes the contents of the command stored in the subwork RAM 210a and acquires various information included in the command. The details of the command analysis process will be described later with reference to FIG.

  Next, the host control circuit 210 performs an animation request construction process (S206). In this process, the host control circuit 210 generates an animation request necessary for performing the effect control using the display device 13, and based on the animation request (in response to the animation request, Various requests (sound requests, lamp requests, and accessories) for operating various effect devices (which can be expressed as corresponding to the effect control (display) on the display device 13 executed based on the animation request). Request). The details of the animation request construction process will be described later with reference to FIG. 92 described later.

  In the present embodiment, as described above, the number of packets (the number of bytes) of the command differs depending on the type of the command. When the host control circuit 210 receives a plurality of command data and the total number of packets of all the command data is equal to or less than the predetermined maximum number of packets, the above-described command analysis processing (S205) and animation The request construction process (S206) is performed on a plurality of received command data in the same frame. However, if the total number of packets of the plurality of received command data exceeds the predetermined maximum number of packets, the command data of the predetermined maximum number of packets among the plurality of received command data is transmitted in the same frame. The analysis processing (S205) and the animation request construction processing (S206) are performed, and the command analysis processing (S205) and the animation request construction processing (S206) for the command data of the remaining number of packets are performed in the next frame.

  Next, the host control circuit 210 determines whether or not the processes of S204 to S206 have been performed for the number of received commands (S207).

  In S207, when the host control circuit 210 determines that the processing of S204 to S206 has not been performed for the number of received commands (NO in S207), the host control circuit 210 returns the processing to S204, and returns to S204. The subsequent processing is repeated.

  On the other hand, in S207, when the host control circuit 210 determines that the processes of S204 to S206 have been performed for the number of received commands (when S207 is YES), the host control circuit 210 performs a drawing control process (S208). ). In this processing, the host control circuit 210 generates a moving image command and a drawing request based on the animation request, and transmits the generated moving image command and the drawing request generated in the previous frame to the display control circuit 230. At this time, the display control circuit 230 performs various processes for displaying (drawing) the effect image on the display device 13 based on the received moving image command and drawing request. The details of the drawing control process will be described later with reference to FIGS. 93A and 93B described later.

  Next, the host control circuit 210 performs a voice control process (S209). In this process, the host control circuit 210 transmits a sound request (command) to the audio / LED control circuit 220. At this time, the audio / LED control circuit 220 performs control processing of audio reproduction by the speaker 11 based on the received sound request. The details of the voice control process will be described later with reference to FIGS. 100A and 100B described later.

  Next, the host control circuit 210 performs a lamp control process (S210). In this process, the host control circuit 210 transmits a lamp request (command) to the audio / LED control circuit 220. At this time, the audio / LED control circuit 220 controls the light emission of the lamp group 18 based on the received lamp request. The details of the ramp control process will be described later with reference to FIGS. 101A and 101B described later.

  Next, the host control circuit 210 performs an accessory control process (S211). In this process, the host control circuit 210 transmits excitation data for driving the accessory 20 to the motor controller 270 (motor driver 271) via the I2C controller 261 based on the generated accessory request. Further, the motor driver 271 outputs the received excitation data to the corresponding motor 272 to drive the accessory 20. The details of the accessory control process will be described later with reference to FIG.

  Next, the host control circuit 210 determines whether or not the elapsed time from the start of the processing in S202 is equal to or longer than the predetermined FPS cycle time (S212). In the present embodiment, the host control circuit 210 executes the above-described series of processing (main loop processing) of S202 to S211 at a predetermined FPS cycle. The FPS cycle is set to, for example, about 16.7 msec (60 FPS), about 33.3 msec (30 FPS), or the like.

  In S212, when the host control circuit 210 determines that the elapsed time from the start of the processing of S202 is not equal to or longer than the predetermined FPS cycle time (when S212 is NO), the host control circuit 210 performs the determination processing of S212. repeat. On the other hand, in S212, when the host control circuit 210 determines that the elapsed time from the start of the processing in S202 is equal to or longer than the predetermined FPS cycle time (when S212 is YES), the host control circuit 210 performs the processing. The process returns to S202, and the processes from S202 onward are repeated.

[Initialization process]
Next, with reference to FIG. 80 and FIG. 81, the initialization processing performed in S201 in the sub-control main processing (see FIG. 79) will be described. FIG. 80 is a diagram showing the outline of the operation of the initialization processing in the present embodiment, and FIG. 81 is a flowchart showing the procedure of the initialization processing in the present embodiment.

  When the pachinko gaming machine 1 is turned on, in the initialization process, the host control circuit 210 performs not only the host control circuit 210 but also various control circuits and controller hardware connected to the host control circuit 210 as shown in FIG. Performs hardware initialization processing. Next, each control circuit or controller performs initialization processing of the corresponding device (the lamp group 18, the speaker 11, the display device 13, and the accessory 20). Hereinafter, a specific procedure of the initialization processing will be described with reference to a flowchart of FIG.

  First, the host control circuit 210 determines whether or not power-on is detected (S221). In S221, when the host control circuit 210 determines that the power-on has not been detected (NO in S221), the host control circuit 210 repeats the determination processing in S221. In the power-on detection processing, it is determined whether or not the power supply voltage supplied to the host control circuit 210 is stable. This indicates that the power supply voltage supplied to the host control circuit 210 is not stable. Therefore, the power-on state detection processing that is repeatedly performed in S221 is a standby processing until the power supply voltage supplied to the host control circuit 210 is stabilized.

  On the other hand, in S221, when the host control circuit 210 determines that the power is turned on (YES in S221), the host control circuit 210 performs hardware initialization processing (S222). In this process, the host control circuit 210 includes various control circuits (own circuits, an audio / LED control circuit 220 and a display control circuit 230) provided in the sub-board 202, and a motor connected to the host control circuit 210. The hardware of the controller 270 is initialized. More specifically, initialization processing of registers, setting processing of a control ROM, and the like in each control circuit and the motor controller 270 are performed.

  Next, the host control circuit 210 clears the counter of the watchdog timer (S223).

  Next, the various control circuits provided in the sub-substrate 202 and the motor controller 270 perform initialization processing of the corresponding devices (S224). In this process, the audio / LED control circuit 220 performs initialization (including ROM access setting) of the driver (control program) for the lamp group 18 and the speaker 11. Further, the display control circuit 230 performs processing for initializing and setting the driver of the display device 13 (including processing for setting ROM access, etc.). Further, the motor controller 270 performs initialization / setting processing (including ROM access setting processing) of the motor driver 271 for driving the accessory 20. Further, in the present embodiment, in this process, the host control circuit 210 also performs a driver initialization / setting process (including a ROM access setting process, etc.) of a not-shown operation unit.

  Next, the host control circuit 210 clears the counter of the watchdog timer (S225).

  Next, the host control circuit 210 performs an application initialization process (S226). In this processing, the host control circuit 210 performs initialization processing of various setting values used in various processing performed in the main loop processing in the sub-control main processing described with reference to FIG. Specifically, the host control circuit 210 performs an operation means input process (S203), a main / sub command control process (S204), an animation request construction process (S206), a drawing control process (S208), and a voice control process (S209). ) And the lamp control processing (S210) are initialized.

  Next, the host control circuit 210 performs other various initialization processing (S227). In this process, the host control circuit 210 performs the backup restoration initialization process, the accessory control initialization process, and the LED registration process. Note that details of the backup restoration initialization processing will be described later with reference to FIG. 82 described later, and details of the accessory control initialization processing will be described later with reference to FIG. 83 described later. Details of the registration process will be described later with reference to FIG. 84 described later.

  Then, after the processing of S227, the host control circuit 210 ends the initialization processing, and moves the processing to S202 of the sub-control main processing (see FIG. 79).

[Backup restoration initialization processing]
Next, the backup restoration initialization process performed in S227 during the initialization process (see FIG. 81) will be described with reference to FIG. FIG. 82 is a flowchart showing the procedure of the backup restoration initialization process in this embodiment.

  First, the host control circuit 210 performs a consistency check process of the game data stored in the backup area of the SRAM 210b (S231). In the game data consistency check processing, processing such as determination of a sum value of game data, check of a program version and a magic code (generally called a magic number), sum check, and the like are performed. The “game data” includes information on parameters in the command and the like, and is referred to in various lottery processes and animation request construction processes performed by the host control circuit 210 and the like. (Aggregate). Further, as will be described later, information (for example, effect patterns, etc.) of the lottery results of various lottery processes is also registered in the “game data”.

  Next, the host control circuit 210 determines whether or not the game data stored in the backup area of the SRAM 210b is consistent (S232). In this process, the host control circuit 210 determines whether or not the game data has been damaged.

  In S232, if the host control circuit 210 determines that the game data is consistent (if S232 is YES), the host control circuit 210 performs the processing of S236 described below.

  On the other hand, in S232, if the host control circuit 210 determines that the game data is not consistent (if S232 is NO), the host control circuit 210 determines whether the game data stored in the mirroring area in the SRAM 210b is consistent. A sex check process is performed (S233). Next, the host control circuit 210 determines whether or not the game data stored in the mirroring area in the SRAM 210b has consistency (S234).

  In S234, if the host control circuit 210 determines that the game data is consistent (if S234 is YES), the host control circuit 210 performs the processing of S236 described later.

  On the other hand, in S234, when the host control circuit 210 determines that the game data is not consistent (NO in S234), the host control circuit 210 performs a game data initialization process (when clearing the RAM) ( S235). In this process, the host control circuit 210 performs an initialization process when clearing the RAM area where the game data is stored. Specifically, the host control circuit 210 initializes variables and the like and returns game data to initial values (completely initializes game data).

  After the process of S235, or when S232 or S234 is YES, the host control circuit 210 performs a game data initialization process (when the power is turned on) (S236).

  At this time, if the process of S236 is performed after the process of S232, the host control circuit 210 performs a process of restoring the game data stored in the backup area of the SRAM 210b. When the process of S236 is performed after the process of S234, the host control circuit 210 performs a process of restoring the game data stored in the mirroring area in the SRAM 210b. When the process of S236 is performed after the process of S235, the host control circuit 210 performs a process of restoring completely initialized game data (initial value).

  Next, the host control circuit 210 backs up the game data restored by the processing of S236 in the SRAM 210b (S237). Then, after the processing of S237, the host control circuit 210 ends the backup restoration initialization processing.

[Accessory control initialization processing]
Next, the accessory control initialization process performed in S227 during the initialization process (see FIG. 81) will be described with reference to FIG. FIG. 83 is a flowchart illustrating the procedure of the accessory control initialization process according to the present embodiment. In this processing, initialization processing of various settings used in the accessory control processing (S211) in the sub-control main processing described with reference to FIG. 79 is performed.

  First, the host control circuit 210 sets “0” to the number of operations of the accessory 20 (S241). Next, the host control circuit 210 determines whether the motor 272 for driving the accessory 20 is at the initial position (S242). This determination process is performed based on the detection result of a sensor (not shown) provided for determining whether the motor 272 is at the initial position.

  In S242, when the host control circuit 210 determines that the motor 272 is at the initial position (when S242 is YES), the host control circuit 210 performs the determination processing of S242 for all the motors 272 to be used. It is determined whether or not it has been touched (S243).

  In S243, when the host control circuit 210 determines that the determination process of S242 has not been performed for all the motors 272 to be used (when S243 is NO), the host control circuit 210 proceeds to S241. Then, the process from S241 onward is repeated.

  On the other hand, in S243, when the host control circuit 210 determines that the determination process of S242 has been performed for all the motors 272 to be used (when S243 is YES), the host control circuit 210 executes the power-on process. Is performed (S244). In the process of S244, the host control circuit 210 performs an operation check process of the accessory 20 when the power is turned on. Specifically, the host control circuit 210 moves the accessory 20 to the maximum movable range or a predetermined movable range, and thereafter returns the accessory 20 to the initial position. Then, after the processing of S244, the host control circuit 210 performs the processing of S249 described later.

  Here, returning to the process of S242 again, in S242, when the host control circuit 210 determines that the motor 272 is not at the initial position (when S242 is NO), the host control circuit 210 It is determined whether or not the number is 10 or more (S245). In this process, it is determined whether or not an abnormality (error) has occurred enough to stop the operation of the motor 272 to be inspected. However, the number of operations serving as a threshold value for this error determination is not limited to ten. It can be set arbitrarily.

  In S245, if the host control circuit 210 determines that the number of operations is 10 or more (if S245 is YES), the host control circuit 210 stops the operation of the motor 272 (error motor) in which the error has occurred. It is set (S246). Then, after the processing of S246, the host control circuit 210 performs the processing of S249 described later.

  On the other hand, in S245, when the host control circuit 210 determines that the number of operations is not 10 or more (when S245 is NO), the host control circuit 210 drives the motor 272 to be inspected and moves to the initial position. (S247). Next, the host control circuit 210 adds “1” to the number of operations (S248). Then, after the processing in S248, the host control circuit 210 returns the processing to S242, and repeats the processing from S242.

  After the processing of S244 or S246, the host control circuit 210 determines whether or not the operation stop of the error motor is detected (S249).

  In S249, if the host control circuit 210 determines that the operation stop of the error motor has not been detected (NO in S249), the host control circuit 210 shifts the operation state to the command reception standby state (S250). ). Then, after the processing of S250, the host control circuit 210 ends the accessory control initialization processing.

  On the other hand, if the host control circuit 210 determines in S249 that the operation stop of the error motor has been detected (YES in S249), the host control circuit 210 sets a state in which the handing-over request cannot be passed ( S251). In the present embodiment, the accessory request is transferred between processes related to the accessory control executed by the host control circuit 210.

  Next, the host control circuit 210 sets a state in which the motor is stopped until the power is turned on again and the initialization processing of the accessory 20 is performed (S252). Then, after the processing of S252, the host control circuit 210 ends the accessory control initialization processing.

[LED registration process]
Next, the LED registration process performed in S227 during the initialization process (see FIG. 81) will be described with reference to FIG. FIG. 84 is a flowchart showing the procedure of the LED registration process in this embodiment.

  First, the host control circuit 210 registers the hardware information of the channel of the LED 281 to be used (S261). Specifically, the host control circuit 210 sets a channel start port number, a channel end port number, and a channel start address of each SPI to be used.

  Next, the host control circuit 210 performs information setting of the LED driver 280 to be used (S262). Specifically, the host control circuit 210 registers a data table (eg, an information table corresponding to the total number of lighting patterns of the LED 281 and a luminance value output to the LED driver 280) in the LED driver 280. Then, after the processing of S262, the host control circuit 210 ends the LED registration processing.

[Operation means input processing]
Next, with reference to FIG. 85 to FIG. 87, the operation means input processing performed in S203 in the sub control main processing (see FIG. 79) will be described. FIG. 85 is a diagram showing an outline of the operation of the operation means input processing in the present embodiment. FIG. 86 is a flowchart showing a procedure of an operation input timer interruption process performed in the operation unit input process of the present embodiment, and FIG. 87 is a flowchart of an operation input information acquisition process performed in the operation unit input process. It is a flowchart which shows a procedure.

  In the operation means input processing of the present embodiment, when a predetermined operation related to the effect is performed by the player on various operation means (for example, buttons, a jog dial, etc.) provided in the pachinko gaming machine 1 (not shown), FIG. As shown, a signal (input signal in FIG. 85) corresponding to the predetermined operation is output from the driver of the operation means to the host control circuit 210. Then, based on the input signal, the host control circuit 210 acquires information on an input state by a predetermined operation of the player.

  In the operation means input processing, an operation input timer interrupt processing performed as a 1 msec timer interrupt processing (measurement timer update processing) and a preset FPS cycle (for example, 16.7 msec or 33.3 msec). The operation input information acquisition process to be performed is performed. Hereinafter, specific procedures of the operation input timer interrupt processing and the operation input information acquisition processing will be described with reference to the flowcharts of FIGS. 86 and 87, respectively.

(1) Operation input timer interrupt processing In the operation input timer interrupt processing, first, as shown in FIG. 86, the host control circuit 210 determines whether or not an operation input signal is input from the driver of the operation means. (S271).

  In S271, when the host control circuit 210 determines that the operation input signal has not been input (NO in S271), the host control circuit 210 ends the operation input timer interrupt processing.

  On the other hand, in S271, if the host control circuit 210 determines that an operation input signal has been input (if S271 is YES), the host control circuit 210 determines an operation input state based on the operation input signal. Then, the information of the operation input state is stored in the subwork RAM 210a (S272). Then, after the processing of S272, the host control circuit 210 ends the operation input timer interrupt processing.

(2) Operation Input Information Acquisition Processing In the operation input information acquisition processing, as shown in FIG. 87, the host control circuit 210 refers to the subwork RAM 210a, and if the operation input state information is stored in the subwork RAM 210a. Then, information on the operation input state is acquired (S281). Then, after the processing of S281, the host control circuit 210 ends the operation input information acquisition processing.

  In the process of S281, for example, when the operation input is an operation input for a button, information such as the type of the operated button and the number of times of pressing is acquired as information of the operation input state. Further, for example, when the operation input is an operation input to the jog dial, information such as a rotation direction, a rotation angle, and a rotation speed of the jog dial is acquired as information of the operation input state. Then, the information on the operation input state acquired in S281 is used when determining (setting) the contents of the effect (effect of the effect and the like) to be executed based on the player's operation input to the operation means.

[Main / Sub command control processing]
Next, with reference to FIG. 88 and FIG. 89, a description will be given of the main-sub command control process performed in S204 during the sub-control main process (see FIG. 79). FIG. 88 is a flowchart showing a procedure of a command receiving process performed in the main-sub command control process of the present embodiment. FIG. 89 is a flowchart showing received data storage performed in the main-sub command control process. It is a flowchart which shows the procedure of a process.

  In the present embodiment, when a command is transmitted from the main control circuit 70 (main CPU 71) to the sub control circuit 200 (host control circuit 210), and the command is received by the host control circuit 210, the host control circuit 210 The inter-command control process is performed as an interrupt process. Then, in the main / sub command control process, a command reception process performed as an interrupt process at the time of command reception and a reception data storage process performed after the command reception process are performed. Hereinafter, specific procedures of the command receiving process and the received data storing process will be described with reference to the flowcharts of FIGS. 88 and 89, respectively.

(1) Command reception processing (reception interrupt processing)
In the command receiving process, first, upon receiving the command transmitted from the main control circuit 70, the host control circuit 210 determines whether or not a command reception error has occurred, as shown in FIG. 88 (S291).

  In S291, when the host control circuit 210 determines that no command reception error has occurred (NO in S291), the host control circuit 210 performs the process of S293 described later. On the other hand, in S291, when the host control circuit 210 determines that a command reception error has occurred (YES in S291), the host control circuit 210 performs error information setting processing (S292).

  After the process of S292 or when the determination of S291 is NO, the host control circuit 210 performs a command data receiving process (S293). In this process, the host control circuit 210 writes the received command data into a ring buffer (see FIG. 36) in the host control circuit 210. If a command reception error has occurred and the error information has been set in S292, the set information of the received command data and error information is written to the ring buffer. Then, after the processing of S293, the host control circuit 210 ends the command receiving processing.

(2) Received Data Storage Processing In the received data storage processing, the host control circuit 210 stores the received command data written in the ring buffer in the above-described command reception processing in the subwork RAM 210a, as shown in FIG. 89 (S301). ). By this processing, the received command is stored in the subwork RAM 210a. In this process, the received command data is transferred from the ring buffer to the subwork RAM 210a one byte at a time.

  Then, after the processing of S301, the host control circuit 210 ends the reception data storage processing.

[Command analysis processing]
Next, the command analysis processing performed in S205 in the sub-control main processing (see FIG. 79) will be described with reference to FIG. FIG. 90 is a flowchart illustrating the procedure of the command analysis processing according to the present embodiment. The command analysis processing described below is controlled by the host control circuit 210 (sub-control circuit 200). That is, the host control circuit 210 (sub-control circuit 200) also functions as a command analysis unit (command analysis unit).

  First, the host control circuit 210 acquires the received command data stored in the sub work RAM 210a (S311). At this time, if there is error information associated with the received command data, the host control circuit 210 discards the received command data.

  Next, the host control circuit 210 specifies the type of the received command (S312). In this process, the host control circuit 210 stores information on the specified command type in the subwork RAM 210a. As described above, the command type is specified based on the information (preset value) stored in the command type portion (head byte area) of each command (see FIGS. 29 to 34). For example, if the received command is a demonstration display command, the command type “80H” is stored in the subwork RAM 210a in the process of S312.

  Next, when the host control circuit 210 determines that there is no command type corresponding to the command received in the command type specifying process in S312, the host control circuit 210 discards the received command data (S313). Next, the host control circuit 210 checks the number of parameters included in the received command data, and if the number of parameters is different from the number of parameters corresponding to the specified command type, discards the received command data (S314). .

  Next, the host control circuit 210 performs a command parameter check process (S315). In this process, the host control circuit 210 checks the contents of information (hereinafter referred to as command parameters) in various parameters (see FIGS. 30 to 34) set for each command. Specifically, for example, the host control circuit 210 checks the always-zero area provided in a predetermined bit area in the parameter, checks the effective range of each data stored in the parameter, and checks the stored data. Check the combination. The details of the command parameter check process will be described later with reference to FIG.

  Next, the host control circuit 210 determines whether or not the command parameters included in the received command are normal (S316). In this determination process, the host control circuit 210 determines whether the command parameter is normal (the validity of the command) based on the result of the command parameter check process in S315.

  In S316, when the host control circuit 210 determines that the command parameter included in the received command is not normal (NO in S316), the host control circuit 210 discards the data of the received command (S317). Then, after the processing of S317, the host control circuit 210 ends the command analysis processing, and moves the processing to S206 of the sub-control main processing (see FIG. 79).

  On the other hand, in S316, when the host control circuit 210 determines that the command parameter included in the received command is normal (when S316 is YES), the host control circuit 210 returns the command parameter (information such as game status). Is reflected (registered) in the game data (S318). In this process, the game data in which the command parameters are reflected is stored in a predetermined area in the subwork RAM 210a.

  Next, the host control circuit 210 performs a sub-lottery process (S319). In this process, the host control circuit 210 acquires various random numbers for effects, and performs a lottery process for determining the effect contents corresponding to the command type of the received command.

  For example, when the received command is a special symbol effect start command, the host control circuit 210 performs a variable effect pattern (“EN00” to “EN44”) by a lottery process using the variable effect table (see FIG. 26). To determine. Further, for example, when the received command is the hold addition command, the host control circuit 210 performs the lottery process using the hold effect table (see FIG. 27), and performs the effect pattern (color change effect of the hold symbol). “HE00” to “HE19”) are determined, and the effect patterns (“SE00” to “SE19”) related to the prefetch effect are determined by a lottery process using the prefetch effect table (see FIG. 28).

  Further, in the process of S319, the host control circuit 210 stores the lottery result of the sub-lottery process (for example, information of the various effect patterns described above) in a predetermined area in the sub-work RAM 210a.

  Next, the host control circuit 210 reflects (registers) the lottery result obtained by the sub lottery process of S319 on the game data stored in the subwork RAM 210a (S320).

  Next, the host control circuit 210 performs a backup process of the game data stored in the subwork RAM 210a (S321). By this processing, the game data is stored in a predetermined area in the SRAM 210b and its mirroring area. The game data backed up in this process is referred to when the game data is damaged in the above-described backup restoration initialization process (see FIG. 82). Then, after the processing of S321, the host control circuit 210 ends the command analysis processing, and moves the processing to S206 of the sub-control main processing (see FIG. 79).

  In the present embodiment, as described above, the received command may be discarded in the command analysis process, but the command is completely transmitted from the main CPU 71 to the host control circuit 210 before the discarded received command. If not, an animation request is not generated, and a black image is displayed on the display screen of the display device 13. On the other hand, when a command is transmitted from the main CPU 71 to the host control circuit 210 before the discarded received command, an animation request based on the discarded received command is not generated, and the display screen of the display device 13 displays the discarded command. The image generated by the animation request based on the command before the received command is maintained and displayed.

[Command parameter check processing]
Next, the command parameter check process performed in S315 during the command analysis process (see FIG. 90) will be described with reference to FIG. FIG. 91 is a flowchart showing the procedure of the command parameter check process in this embodiment.

  First, the host control circuit 210 acquires the command type stored in the subwork RAM 210a, and sets a check item (masking) corresponding to the command type of the received command (S331).

  Next, the host control circuit 210 checks information of all the always 0 areas included in the received command (S332). In this process, if the host control circuit 210 detects that information other than “0” is stored in one or more always-zero areas, the host control circuit 210 discards the received command. If the received command to be analyzed does not always have the 0 area, the process of S332 is not performed.

  Next, the host control circuit 210 checks whether or not the value of each information included in the received command is within a corresponding predetermined range (S333). In the present embodiment, the value of the information stored in the parameter field of the received command is defined in advance to be a value within a predetermined range (effective range). For example, special stop symbol designation information is stored in a storage area (an 8-bit area of “b0” to “b7”) of the second parameter of the first power-off reset command (see FIG. 32). The valid range of the value of the special stop symbol designation information is set to “0x00” to “0x20”. If the host control circuit 210 determines in one or more pieces of information included in the received command that the value is not a value within the corresponding predetermined range in this process, the host control circuit 210 Discard the command.

  Next, the host control circuit 210 checks a combination of various information included in the received command (S334). In this embodiment, even if the value of each piece of information included in the received command is a value within the corresponding valid range, if a conflict occurs in a combination of various pieces of information included in the command, the host control circuit 210 The received command is discarded. For example, if the received command is a special symbol effect start command, the game status information included in the received command indicates "small hit", and if the information of the symbol designating command is a big hit symbol, a combination of information in the command Therefore, the host control circuit 210 discards the received special symbol effect start command.

  Then, after the processing of S334, the host control circuit 210 ends the command parameter check processing, and moves the processing to S316 of the command analysis processing (see FIG. 90).

  In the present embodiment, as described above, the command parameter check processing is controlled by the host control circuit 210 (sub-control circuit 200). That is, the host control circuit 210 (sub-control circuit 200) performs a check process of the always 0 area in S332 (first command determination unit), and checks the validity of the value of each information included in the received command in S333. (Third command determining means) and means for checking the combination of various information included in the received command in S334 (third command determining means).

[Animation request construction process]
Next, the animation request construction processing performed in S206 in the sub-control main processing (see FIG. 79) will be described with reference to FIG. FIG. 92 is a flowchart showing the procedure of the animation request construction process in the present embodiment.

  First, the host control circuit 210 determines whether a command has been received from the main control circuit 70 (S341).

  In S341, when the host control circuit 210 determines that the command has not been received from the main control circuit 70 (when S341 is NO), the host control circuit 210 performs the processing of S352 described later. On the other hand, in S341, when the host control circuit 210 determines that the command has been received from the main control circuit 70 (in the case of YES determination in S341), the host control circuit 210 executes the power interruption recovery command (the first power interruption recovery command). And a second power interruption recovery command) (S342).

  In S342, when the host control circuit 210 determines that the power-off recovery command has not been received (NO in S342), the host control circuit 210 performs the processing of S346 described later. On the other hand, in S342, when the host control circuit 210 determines that the power-off recovery command has been received (in the case of YES determination in S342), the host control circuit 210 returns to the power-off recovery command (second power-off recovery command). It is determined whether or not the information of the included status (internal control state) is in a fluctuating state (S343). Specifically, the host control circuit 210 determines whether “001” (special symbol variation state) is set in the storage area of the internal control state number included in the second parameter in the second power interruption return command. Determine. In the case where the state at the time of the power failure detection is the variable display of the special symbol, “001” is stored in the storage area of the internal control state number in the second parameter of the second power failure return command at the time of the processing of S343. "(Special symbol fluctuation state) is set.

  In S343, when the host control circuit 210 determines that the status information included in the power interruption recovery command is not in a fluctuating state (NO in S343), the host control circuit 210 performs the processing of S346 described later.

  On the other hand, in S343, when the host control circuit 210 determines that the status information included in the power interruption recovery command is in a fluctuating state (if S343 is YES), the host control circuit 210 generates a simple mode object. The process is reserved (S344). Next, the host control circuit 210 performs termination processing of all objects (including resident objects) other than the simple mode object (S345). After the processing of S345, the host control circuit 210 performs the processing of S350 described later.

  Here, returning to the processing of S342 or S343 again, if the determination of S342 or S343 is NO, the host control circuit 210 determines whether or not the object exists (S346).

  If the host control circuit 210 determines in S346 that the object does not exist (NO in S346), the host control circuit 210 performs the processing of S350 described later. On the other hand, in S346, when the host control circuit 210 determines that an object is present (YES in S346), the host control circuit 210 determines whether a simple mode object is present (S347).

  In S347, when the host control circuit 210 determines that the simple mode object does not exist (when S347 is NO), the host control circuit 210 performs the process of S349 described later. On the other hand, in S347, when the host control circuit 210 determines that the simple mode object is present (in the case of YES determination in S347), the host control circuit 210 issues a command (eg, It is determined whether or not a special effect stop command, a special symbol end display command, etc.) have been received (S348).

  In S348, when the host control circuit 210 determines that the command indicating that the special symbol variation display is to be ended has not been received (NO in S348), the host control circuit 210 executes the processing of S352 described later. Do. On the other hand, if the host control circuit 210 determines in S348 that the command indicating that the special symbol change display is to be ended is received (if S348 is YES), that is, if the simple mode object is to be ended, the host The control circuit 210 performs the process of S349 described later.

  When S347 is determined to be NO or S348 is determined to be YES, the host control circuit 210 performs an end process of the already generated object (S349). By this processing, unnecessary production operations (production of commands indicating production image reproduction, movable character movement, sound reproduction, etc.) are completed. When the already generated object is a simple mode object, the rendering operation by the simple mode object ends by this processing.

  After the processing of S349 or S345, or when S346 is NO, the host control circuit 210 generates an object corresponding to the command type based on the information of the command type stored in the subwork RAM 210a (S350). If this processing is performed after the processing of S345, the host control circuit 210 generates a simple mode object in the processing of S350. When the power is initially turned on or when the simple mode object ends, the host control circuit 210 also generates a resident type object in the process of S350.

  Next, the host control circuit 210 performs an object initialization process (S351). In this process, the host control circuit 210 initializes a storage area used by the object.

  After the processing of S351, or when the determination of S341 or S348 is NO, the host control circuit 210 refers to the information of the game data stored in the subwork RAM 210a, and sets the object (for example, the effect object, the hold object, the simple mode object). ), And sets the animation request in a predetermined area of the subwork RAM 210a (S352). By this processing, an animation request corresponding to the command reception is generated.

  Next, based on the animation request, the host control circuit 210 generates a sound request, a lamp request, and an accessory request corresponding to the effect specified by the animation request (S353). In this process, the host control circuit 210 transmits the generated sound request, lamp request, and accessory request to the host in order to synchronize the video display operation with the audio playback operation, the light emitting operation, and the accessory driving operation. The data is temporarily stored in a request buffer provided in the control circuit 210. In the present embodiment, the request buffer is provided in, for example, the subwork RAM 210a, the SRAM 210b, or the like, but the location where the request buffer is formed is not particularly limited.

  Then, after the processing of S353, the host control circuit 210 ends the animation request construction processing, and moves the processing to S207 of the sub-control main processing (see FIG. 79).

  In the present embodiment, as described above, the animation request construction process is controlled by the host control circuit 210 (sub-control circuit 200). That is, the host control circuit 210 (sub-control circuit 200) also serves as a means for performing the object generation processing in S350 (processing information generating means) and a means for performing the animation request generation processing in S352 (production effect request generation means). .

[Drawing control processing]
Next, with reference to FIGS. 93A and 93B, the drawing control process performed in S208 in the sub-control main process (see FIG. 79) will be described. FIG. 93A is a flowchart illustrating a procedure of a drawing control process executed by the host control circuit 210. FIG. 93B is a flowchart illustrating a procedure of a process executed by the display control circuit 230 when a rendering request is output from the host control circuit 210 to the display control circuit 230 in the rendering control process.

(1) Drawing Control Process Executed by Host Control Circuit First, the host control circuit 210 performs a moving image command creation process as shown in FIG. 93A (S361). The details of the moving image command creation processing will be described later with reference to FIG. 94 described later.

  Next, the host control circuit 210 performs management processing of the moving image reproduction state (S362). Next, the host control circuit 210 issues (outputs) a moving image command (moving image decoding start command) to the display control circuit 230 (S363). With this process, the process of the display control circuit 230 is started.

  Next, the host control circuit 210 issues (outputs) the drawing request generated in the previous frame (previous drawing control processing) stored in the subwork RAM 210a to the display control circuit 230 (S364). The display control circuit 230 performs drawing processing based on the transmitted drawing request of the previous frame.

  Next, the host control circuit 210 performs an all command list creation process (S365). With this processing, in the next frame, a drawing request used in the drawing processing executed by the display control circuit 230 is generated, and the drawing request is stored in the subwork RAM 210a. The details of the all command list creation processing will be described later with reference to FIG. 96 described later.

  Next, the host control circuit 210 confirms that the rendering result display processing has been started based on the display start command output from the display control circuit 230 (S366). Then, after the processing of S366, the host control circuit 210 ends the drawing control processing, and moves the processing to S209 of the sub-control main processing (see FIG. 79).

(2) Processing of Display Control Circuit Executed During Drawing Control Processing First, when a moving image command (moving image decoding start command) output from the host control circuit 210 is input to the display control circuit 230, the display control circuit 230 Then, the decoding process of the moving image is started (S371). In the present embodiment, the decoding process and the later-described drawing process are performed over a period of two frames.

  Next, when a drawing request output from the host control circuit 210 (a drawing request generated in the previous frame) is input to the display control circuit 230, the display control circuit 230 performs a drawing process based on the drawing request. (S372). The details of the drawing process will be described later with reference to FIGS.

  Next, the display control circuit 230 starts display processing of the rendering result (drawing result) obtained in the drawing processing of S372 (S373). In this processing, the display control circuit 230 changes the function of one frame buffer (function variable data area) in the SDRAM 250 in which the rendering result is stored from the drawing function (second function) to the display function (first function). Switch to start the rendering result display process.

  Next, the display control circuit 230 outputs to the host control circuit 210 a display start command indicating that the display processing of the rendering result (drawing result) has been started (S374). Then, after the process of S374, the display control circuit 230 ends the series of processes performed during the drawing control process. Thus, in order to execute the drawing processing based on the drawing request generated in the previous frame, the function of the frame buffer (used area) executed after the end of the drawing processing is displayed from the drawing function (storage area for drawing). The sound request and the accessory request are transmitted to the corresponding control circuits at the timing of switching to the function (storage area for display). For this reason, the sound request and the accessory request are transmitted to the corresponding control circuit two frames later after each request is generated.

[Movie command creation processing]
Next, with reference to FIG. 94, the moving image command creation processing performed in S361 during the drawing control processing (see FIG. 93A) will be described. FIG. 94 is a flowchart illustrating the procedure of the moving image command creation process according to the present embodiment.

  First, the host control circuit 210 refers to the animation request stored in the subwork RAM 210a and acquires information for setting a root composition of drawing data (S381). It should be noted that the root composition is the main drawing data to be displayed during the effect, and in the present embodiment, the number of root compositions that can be set is eight at the maximum. Therefore, in the present embodiment, up to eight pieces of drawing data set in the root composition can be reproduced simultaneously.

  Next, the host control circuit 210 refers to the animation request stored in the subwork RAM 210a, and acquires information for setting a sub-composition of the drawing data (S382). The sub-composition is drawing data that gives a secondary visual effect (effect or the like) to the root composition.

  Next, the host control circuit 210 determines whether or not the processing of S384 to S387 described below has been executed according to all layers corresponding to the drawing data specified by the animation request or all layers specified by the animation request. (S383). Here, “executed according to all layers” includes execution for all layers, execution for the number of times corresponding to all layers, execution based on all layers, and the like. The number of times corresponding to the number of layers corresponding to the request or the drawing data may be the number of times that the processes of S384 to S387 described below are performed. Further, the processing of S384 to S387 described below may be executed under various preconditions, such as selecting each layer even if it is not all layers.

  In step S383, the host control circuit 210 determines that the processing in steps S384 to S387 described below has not been performed in accordance with all the layers corresponding to the drawing data specified by the animation request or all the layers specified by the animation request. In this case (NO in S383), the host control circuit 210 performs a process of reading animation data stored in the sub main ROM 205 (S384). The details of the animation data reading process will be described later with reference to FIGS. 95A and 95B described later.

  After the processing of S384, the host control circuit 210 acquires information on drawing data from the animation data (S385). Next, the host control circuit 210 rewrites the information on the drawing data according to the effect content specified by the animation request (S386). In this process, for example, information on the footage, the effect, and the movement is rewritten according to the effect contents.

  Next, the host control circuit 210 performs a creation process of a moving image command (a command for starting a decoding process of image data) (S387). After the processing in S387, the host control circuit 210 returns the processing to S383, and repeats the processing from S383.

  Here, returning to the processing of S383 again, in S383, the host control circuit 210 determines that the processing of S384 to S387 is performed for all the layers corresponding to the drawing data specified by the animation request or all the layers specified by the animation request. If the host control circuit 210 determines that the root composition specified by the animation request is set in accordance with the drawing data in which the root composition specified by the animation request is set (S383: YES). Is determined (S388).

  In S388, when the host control circuit 210 determines that the processing of S381 to S387 is not executed according to the drawing data in which the root composition specified by the animation request is set (NO in S388) In this case, the host control circuit 210 returns the processing to S381, and repeats the processing from S381. On the other hand, in S388, when the host control circuit 210 determines that the processing of S381 to S387 described above has been executed in accordance with the drawing data in which the root composition specified by the animation request is set (YES in S388. In this case, the host control circuit 210 ends the moving image command creation processing, and moves the processing to S362 of the drawing control processing (see FIG. 93A).

[Animation data read processing]
Next, with reference to FIG. 95A and FIG. 95B, the animation data reading process performed in S384 during the moving image command creation process (see FIG. 94) will be described. FIG. 95A is a flowchart illustrating the procedure of the animation data reading process according to the present embodiment. FIG. 95B is a diagram showing various data included in the animation data stored in the sub main ROM 205 and a configuration of a storage area for those data.

  First, the host control circuit 210 refers to the configuration specification table in the sub main ROM 205 and checks the configuration data of the animation specified by the object (S391). Next, the host control circuit 210 acquires the address of the specified configuration data (S392).

  Next, the host control circuit 210 refers to the storage area of the specified configuration data in the sub main ROM 205 (S393). Next, the host control circuit 210 refers to the configuration information included in the configuration data and acquires the information to be drawn (S394). Note that the configuration information mainly includes information such as a frame position, a width, a height, the number of layers, a start frame, an end frame, and the number of data updates (each frame, two frames, and the like). Next, the host control circuit 210 acquires the address of the referenced layer data by referring to the storage area of the configuration data (S395).

  Next, the host control circuit 210 refers to the storage area of the layer data of the address acquired in the processing of S395 (S396). Then, the host control circuit 210 acquires the layer information included in the layer data (S397). The layer information includes, for example, information such as a footage ID / component ID, a start frame, an end frame, and the number of parameters. Next, the host control circuit 210 acquires various data addresses (for example, parameter addresses and effect table addresses) to be referred to when acquiring various layer parameters (S398).

  Next, the host control circuit 210 refers to the storage area of the parameter data of the parameter address acquired in the processing of S398 (S399). Next, the host control circuit 210 acquires parameter information of the layer and various parameters of the layer included in the parameter data (S400). The layer parameter information includes, for example, information such as the number of frames and the data type. Further, various parameters of the layer are constituted by parameters set for each frame, and each time the sub-control main process is executed in frame units, the parameters of the corresponding frame are requested.

  Next, the host control circuit 210 refers to the footage table corresponding to the footage ID included in the layer information acquired in the processing of S397 (S401). Next, the host control circuit 210 acquires the footage information and the information for each footage type stored in the footage table (S402). The footage information includes, for example, information such as a footage type, an image width, and a height. The information for each footage type includes, for example, information such as a decode rate.

  Next, the host control circuit 210 refers to the effect table specified by the layer data, that is, the effect table of the effect table address acquired in the processing of S398 (S403). Next, the host control circuit 210 acquires the address of the effect data to be referred to (S404).

  Next, the host control circuit 210 refers to the storage area of the effect data at the address obtained in the process of S404 (S405). Then, the host control circuit 210 acquires the effect information included in the effect data (S406). The effect information includes, for example, information such as the effect type and the number of parameters. Next, the host control circuit 210 acquires the address of the parameter data included in the effect data (S407).

  Next, the host control circuit 210 refers to the storage area of the parameter data of the parameter address acquired in the process of S407 (S408). Next, the host control circuit 210 acquires parameter information of the effect and various parameters of the effect included in the parameter data (S409). Note that the parameter information of the effect includes, for example, information such as the number of frames and the data type.

  Then, after the processing of S409, the host control circuit 210 ends the animation data reading processing, and moves the processing to S385 of the moving image command creation processing (see FIG. 94).

[All command list creation processing (drawing request generation processing)]
Next, with reference to FIG. 96, a description will be given of the all command list creation processing performed in S365 in the drawing control processing (see FIG. 93A). FIG. 96 is a flowchart showing the procedure of the all-command-list creation process in the present embodiment.

  First, the host control circuit 210 determines whether or not the processing of S412 to S418 described later has been executed for all the root compositions of the drawing data (S411).

  In step S411, when the host control circuit 210 determines that the processing of steps S412 to S418 described below has not been executed for all the root compositions of the drawing data (in the case of S411 being NO), the host control circuit 210 At the time of the later-described processing of S413 to S418 for the second and subsequent root compositions, decoding of still images and various commands (still image decoding, drawing commands, and the like) to be described later in the processing for the first root composition are performed. The process waits until the generation processing is completed (S412).

  Next, the host control circuit 210 creates a sprite buffer 0 command (S413). The command for the sprite buffer 0 is used, for example, in a rendering process described below, for example, when the sprite buffer 0 is provided in the built-in VRAM 237 and a process of reading and decoding a still image (sprite) from the CGROM board 204 into the sprite buffer 0 is performed. This is a command used for

  Next, the host control circuit 210 acquires texture information (S414). In this process, the host control circuit 210 acquires information on the specified texture source (SDRAM 250).

  Next, the host control circuit 210 creates an effect command (S415). Note that the effect command is a command that is used, for example, when an effect buffer is provided in the built-in VRAM 237 and various processes are performed on the effect data using the effect buffer in a drawing process described later.

  Next, the host control circuit 210 creates a drawing command (S416). Note that the drawing command is a command used in executing a rendering (drawing) process on various decoding results read into the internal VRAM 237, for example, in a drawing process described later.

  Next, the host control circuit 210 creates a still image decoding command (S417). The command for decoding a still image is provided by, for example, providing a sprite buffer 1 in a half area in the built-in VRAM 237 and reading a still image (sprite) from the CGROM board 204 into the sprite buffer 1 in a drawing process described later. This command is used when executing processing.

  Next, the host control circuit 210 creates a frame termination command (S418). Note that, in the drawing processing described later, for example, a frame end command is used to transfer a rendering result finally stored in a composition drawing buffer provided in the internal VRAM 237 to a frame buffer (first This is a command used when executing a process of writing to the first frame buffer or the second frame buffer. Then, after the processing in S418, the host control circuit 210 returns the processing to S411, and repeats the processing from S411.

  Here, returning to the process of S411 again, when the host control circuit 210 determines in S411 that the processes of S412 to S418 have been executed for all the root compositions of the drawing data (in the case of YES determination in S411) ), The host control circuit 210 generates a drawing request including all commands generated by the loop processing of S412 to S418 (S419). Then, after the processing of S419, the host control circuit 210 ends the all command list creation processing, and moves the processing to S366 of the drawing control processing (see FIG. 93A). In this embodiment, the host control circuit 210 is used in the above-described drawing control processing (FIG. 93A), moving image command creation processing (FIG. 94), animation data reading processing (FIG. 95A), and all command list creation processing (FIG. 96). May be executed by the display control circuit 230. In this case, an animation request is transmitted from the host control circuit 210 to the display control circuit 230, and the display control circuit 230 performs these various processes based on the received animation request.

[Drawing process]
Next, the drawing process executed by the display control circuit 230 in S372 during the drawing control process (see FIG. 93B) will be described with reference to FIGS. Note that FIG. 97A, FIG. 98A, and FIG. 99A are flowcharts showing the procedure of the drawing process in the present embodiment. FIGS. 97B, 98B, and 99B are diagrams showing input / output operations and storage operations of various data between the CGROM substrate 204 (CGROM 206), the built-in VRAM 237, and the SDRAM 250, which are performed in each processing step of the drawing process. is there.

  First, the display control circuit 230 decodes predetermined moving image data (compressed predetermined moving image data: information related to first image data) stored in the CGROM board 204, and decodes the decoding result (first image data). ) Is stored in a movie buffer (first data area) provided in the SDRAM 250 (S421: see arrow T1 in FIG. 97B). The movie buffer is a buffer that stores a result of decoding moving image data. The size of the movie buffer secured in the SDRAM 250 changes according to the size (capacity) of moving image data to be used, the number of streams, and the like.

  Next, the display control circuit 230 determines whether or not the decoded moving image data is referred to in the effect drawing operation (S422).

  In S422, when the display control circuit 230 determines that the moving image data is not referred to in the effect drawing operation (NO in S422), the display control circuit 230 performs the process of S424 described later. On the other hand, in S422, when the display control circuit 230 determines that the moving image data is referred to in the effect drawing operation (when S422 is YES), the display control circuit 230 decodes the moving image data stored in the movie buffer. The result is transferred and stored in the texture buffer (second data area) in the SDRAM 250 (S423).

  In the process of S423, first, the display control circuit 230 expands the decoding result of the moving image data stored in the movie buffer in the SDRAM 250 to the movie blend buffer generated in the built-in VRAM 237 (arrow in FIG. 97B). T2). In this process, the entire area of the built-in VRAM 237 is used as a movie blend buffer. Next, the display control circuit 230 transfers the decoding result of the moving image data expanded in the movie blend buffer to the texture buffer in the SDRAM 250, and performs an alpha conversion process on the decoding result (see an arrow T3 in FIG. 97B). . By this processing, the transparency is set for the decoding result of the image data. The moving image that has been subjected to such an alpha conversion process is used when the moving image is not represented by three primary colors (RGB) (when it is represented by black and white or the like).

  In the present embodiment, the following two methods can be used as the method of the alpha conversion processing, and one of the two methods is used. However, the method of the alpha conversion process to be used may be appropriately selected according to, for example, the configuration and type of the image data, the content of the image effect, or the like. It may be set.

  The first method of alpha conversion processing (second transparency setting means) is a method of performing alpha conversion processing on a decoding result using an alpha table stored in the CGROM 206. The alpha table is a table that defines an alpha value (opacity) independent of color data (RGB), and one alpha value is assigned to each dot of pattern data. That is, in the first method of the alpha conversion processing, the display control circuit 230 obtains the data (transparency data) of the alpha value (opacity) corresponding to the image data by referring to the alpha table, Set the transparency for. The alpha value data (alpha table) may be compressed and stored in the CGROM 206 or may be stored without being compressed. Further, the alpha table may be stored in a storage unit (information storage unit) other than the CGROM 206.

  On the other hand, the second method of alpha conversion processing (first transparency setting means) is a method that does not use an alpha table. In the alpha conversion processing of the decoding result based on the second method, the display control circuit 230 uses the luminance value of a predetermined color component included in the image data as the alpha value (opacity) (the luminance value of the color component is expressed as alpha). To the component value (alpha value). For example, in the second method, the transparency of the image data can be set by converting the luminance value of the R (red) component into the value (alpha value) of the A (alpha) component.

  After the process of S423 or when the determination of S422 is NO, the display control circuit 230 stores the still image data of the sprite data (compressed still image data: second image data) stored in the CGROM board 204 and used in each root composition. The image data is read out to the sprite buffer 0 in the built-in VRAM 237 (see the arrow T4 in FIG. 97B) and decoded, and the decoding result (sprite data: second image data) is transferred to the texture buffer in the SDRAM 250. (S424: See arrow T5 in FIG. 97B). Note that the “sprite data” here is image data obtained by expanding still image data, but the present invention is not limited to this. For example, reduction, enlargement, curvature, brightness change, and the like may be applied to still image data. May be processed. The sprite data decoded in the process of S424 is image data drawn a plurality of times, image data used for effects, and image data of a size that cannot be stored in the sprite buffer 1. In this process, the entire area of the internal VRAM 237 is used as the sprite buffer 0.

  Next, the display control circuit 230 determines whether or not the buffer size (effect buffer size) used in the effect data drawing process is equal to or less than half the size of the built-in VRAM 237 (S425). Note that the effect buffer in the built-in VRAM 237 stores the effect data (image data used in the effect) included in the sprite data transferred to the texture buffer in S424 in the decoding result of various images stored in the texture buffer in the SDRAM 250. Is a buffer for applying.

  In S425, when the display control circuit 230 determines that the buffer size used in the effect data drawing processing is not less than half the size of the built-in VRAM 237 (NO in S425), the display control circuit 230 A drawing process (effect calculation drawing process) for applying effect data is performed on the decoding results of various images stored in the texture buffer (S426).

  Specifically, in the process of S426, first, the display control circuit 230 reads out the decoding result of various images and effect data stored in the texture buffer to the effect buffer provided in the built-in VRAM 237 (arrow in FIG. 98B). T6). At this time, the entire area of the built-in VRAM 237 is used as an effect buffer. Next, the display control circuit 230 performs drawing processing (effect calculation drawing processing: effect rendering addition processing) for applying the effect data to the decoding results of various images. Then, the display control circuit 230 transfers the result of the effect calculation drawing process (effect result) from the effect buffer in the built-in VRAM 237 to the texture buffer in the SDRAM 250 (see the arrow T7 in FIG. 98B).

  On the other hand, in S425, when the display control circuit 230 determines that the buffer size used in the rendering processing of the effect data is equal to or less than half the size of the built-in VRAM 237 (when S425 is YES), the display control circuit 230 A half area of the built-in VRAM 237 is operated as an effect buffer, and the other half area is operated as a copy buffer (S427). Next, the display control circuit 230 reads out the decoding result of the various images and effect data stored in the texture buffer from the effect buffer provided in the built-in VRAM 237, and performs an effect calculation drawing process (S428).

  At this time, if the decoding result (effect source image) of the effect data has already been transferred to the copy buffer, the display control circuit 230 reads the effect source image from the texture buffer of the SDRAM 250 without reading the effect source image from the copy buffer. The source image of the effect is directly read into the effect buffer (see arrow T8 in FIG. 98B), and the effect calculation drawing process is performed. On the other hand, if the source image of the effect has not been transferred to the copy buffer, the display control circuit 230 reads the source image of the effect from the texture buffer of the SDRAM 250 to the copy buffer (see the arrow T9 in FIG. 98B). The effect source image is read from the copy buffer to the effect buffer and effect calculation drawing processing is performed. Then, the display control circuit 230 stores the result of the effect calculation drawing process (effect result) in the copy buffer (see the arrow T10 in FIG. 98B), and transfers the effect result stored in the copy buffer to the texture buffer of the SDRAM 250. (See arrow T11 in FIG. 98B). When a plurality of effects are applied and the buffer usage of each effect is equal to or less than half the size of the built-in VRAM 237, the display control circuit 230 copies the result (effect result) for each effect calculation drawing process. After the drawing results of the plurality of effects are completed to the end, the effect results are transferred from the copy buffer to the texture buffer of the SDRAM 250.

  As described above, in the present embodiment, before the composition drawing process described later, the drawing process is performed on all the effects applied to the layers used in each composition. Further, in the present embodiment, when the buffer capacity used for the effect is less than half of the capacity of the built-in VRAM 237, half the area in the built-in VRAM 237 is used as a copy buffer, and the buffer capacity used for the effect is changed to the built-in VRAM 237. If the capacity is not less than half, the entire area of the built-in VRAM 237 is used as an effect buffer. That is, the area in the built-in VRAM 237 used as the effect buffer is appropriately changed according to the buffer capacity used for the effect. By performing such processing, it is possible to speed up the processing when applying the effect calculation drawing processing to a plurality of effects.

  After the processing in S426 or S428, the display control circuit 230 reads out and renders still image data of sprite data not decoded in S424 (not stored in the texture buffer) to a composition drawing buffer provided in the built-in VRAM 237. (S429). Specifically, first, the display control circuit 230 reads the still image data not decoded in S424 from the CGROM board 204 into the sprite buffer 1 provided in a half area in the built-in VRAM 237, and decodes the data (see FIG. 99B Arrow T12). Note that “reading and decoding still image data into sprite buffer 1” includes a mode in which still image data is read while being decoded into sprite buffer 1. Therefore, in this processing, the reading processing of the still image data and the decoding processing may be performed at the same timing, or the reading processing may be performed after the decoding processing of the still image data is performed. That is, the process of “reading out and decoding the still image data into the sprite buffer 1” only needs to include both processes regardless of the processing order of the reading process and the decoding process of the still image data. It should be noted that the process of “reading out to the sprite buffer 1 and decoding” may be a process including only the reading process and the decoding process of the still image data.

  Next, the display control circuit 230 performs a drawing process by transferring the decoding result (sprite data) of the still image data stored in the sprite buffer 1 to the composition drawing buffer (see the arrow T13 in FIG. 99B).

  After the process of S429, the display control circuit 230 reads out and decodes the decoding result of the moving image data stored in the movie buffer in the SDRAM 250 into the composition drawing buffer in the built-in VRAM 237 (S430). Specifically, first, the display control circuit 230 transfers the color component of the decoded result of the moving image data stored in the movie buffer in the SDRAM 250 to the movie blend buffer provided in the remaining half area in the built-in VRAM 237. At the same time, the decoding result is subjected to an alpha conversion process (see arrow T14 in FIG. 99B). Next, the display control circuit 230 transfers the decoding result of the moving image data transferred to the movie blend buffer and subjected to the alpha conversion processing to the composition drawing buffer to perform the drawing processing (see the arrow T15 in FIG. 99B).

  Next, the display control circuit 230 performs a composition drawing process (S431). In this process, the following various processes are performed.

  First, the display control circuit 230 stores various source images (moving image / still image decoding result, effect result, composition drawing result) of each layer stored in the texture source (texture source in the SDRAM 250, movie buffer) in the built-in VRAM 237. (Refer to arrow T16 in FIG. 99B). The display control circuit 230 also stores various source images stored in a texture buffer in the SDRAM 250 into a blend buffer (third data area) provided in the SDRAM 250 and a copy buffer (predetermined data area) provided in the built-in VRAM 237. ) (See arrows T17 and T18 in FIG. 99B).

  Next, the display control circuit 230 inputs and outputs various data between the blend buffer of the SDRAM 250 and the copy buffer of the built-in VRAM 237 (see an arrow T19 in FIG. 99B), and performs a blend operation drawing process. In the blend calculation drawing processing, calculation processing for combining moving picture (movie) data and still picture (sprite) data is performed. Then, the display control circuit 230 transfers the result of the blending operation drawing process (synthesis result) to the composition drawing buffer (see arrow T20 in FIG. 99B).

  Next, the display control circuit 230 performs a drawing (rendering) process using the various source images (moving / still image decoding result, effect result, composition drawing) and the blend result of each layer read into the composition drawing buffer. Apply.

  Then, the display control circuit 230 transmits the drawing result (rendering result) constructed by the drawing (rendering) process to the texture buffer of the SDRAM 250 or a predetermined frame buffer of the SDRAM 250 (first frame buffer or second frame buffer: fourth data area). ) (See arrows T21 or T22 in FIG. 99B). At this time, if the drawing processing target is a sub-composition, the drawing result is stored in a texture buffer, and if the drawing processing target is a root composition, the drawing result is stored in a frame buffer. Is done. When the drawing result is stored in the frame buffer, the drawing result is stored in a frame buffer different from the frame buffer in which the drawing result was stored in the composition drawing process of the previous frame. The composition drawing process in S431 is performed as described above.

In the composition drawing process of S431, when all of the following conditions (1) to (5) are satisfied, the display control circuit 230 is stored in the texture source (texture source in the SDRAM 250, movie buffer). After the various source images of each layer (moving / still image decoding result, effect result, composition drawing result) are copied and drawn in the copy buffer in the built-in VRAM 237, the various source images are read out to the composition drawing buffer to be composed. A drawing process is performed.
(1) The upper left coordinate of the texture does not match the 8-dot alignment. (2) Rotation and enlargement / reduction exist. (3) A bilinear filter is used. (4) Blend drawing operation is multi-rendering.
(5) The various source images of each layer stored in the texture source fit within the size of the copy buffer.

  When the above-described composition drawing process is continuously performed on various source images in the same texture source, various source images cached in the copy buffer are used.

  Then, after the processing in S431 described above, the display control circuit 230 ends the drawing processing, and moves the processing to S373 in the drawing control processing (see FIG. 93B).

  In the drawing process of the present embodiment, as described above, information (compressed moving image data and / or still image data) related to various image data used for the performance is decoded, and the decoding result (image data) is set to a predetermined value. It is temporarily stored in storage means (SDRAM 250 or built-in VRAM 237). Then, various arithmetic processes are performed on the decoding result, and finally various image data are synthesized. This series of processing is executed according to the above-described procedure using various data storage areas (various buffers) provided in the above-described various storage means (built-in VRAM 237 and SDRAM 250), thereby facilitating the synthesis of various image data. It can be executed, and the storage capacity of various storage units can be used efficiently. That is, in the present embodiment, the arithmetic processing of the image data can be performed more efficiently.

  In the drawing process of the present embodiment, the data of the drawing result stored in the first frame buffer and the second frame buffer is displayed while being alternately switched for each frame. Then, during a period in which the drawing result stored in one frame buffer is being displayed, a process of generating data of the drawing result to be displayed next (drawing result stored in the other frame buffer) is performed. At this time, in the present embodiment, the drawing result generation process is performed while considering the balance between the number of times of data communication between the storage units and the storage capacity required for each storage unit. Therefore, in the above-described image display processing and drawing processing using the frame buffer switching function, the efficiency of the display processing and the generation processing of the drawing result can be improved.

  Further, in the drawing processing of the present embodiment, as described above, the decoded moving image data (image data) is subjected to the alpha conversion processing to set the transparency (opacity) (the above-described S423 (arrow T3)). , S430 (see the process of arrow T14). In the present embodiment, an example has been described in which the decoded moving image data (information on image data) is subjected to an alpha conversion process. However, the present invention is not limited to this, and for example, it may be determined according to the content of the image display effect. Then, the decoded still image data (sprite data) may be subjected to an alpha conversion process. In the present embodiment, as a method of the alpha conversion processing, a first method of setting the transparency corresponding to the image data by referring to the alpha table, or a predetermined method included in the image data without using the alpha table A second method of setting the transparency by converting the luminance value of the color component into an alpha value (the value of the alpha component) can be used.

  In the case where the transparency set for each of the image data of the moving image data and the sprite (still image) data is dynamically changed using the former first method, the transparency data for change (alpha value) is also stored in the CGROM 206. It must be stored in advance. Therefore, when this method is used, the ratio of the data relating to the transparency in the storage area of the CGROM 206 (storage means) increases, and the storage capacity of the CGROM 206 may be reduced. In this case, every time the transparency is changed, a process of referring to the alpha table is required, and the processing load on the display control circuit 230 may increase.

  On the other hand, when the latter second method is used, that is, when a method of directly setting transparency using the luminance value of a predetermined color component included in the image data is used, the alpha table becomes unnecessary. In addition, the process of referring to the alpha table is not required.

  Therefore, when dynamically changing the transparency set for each image data of the moving image data and the sprite (still image) data by using the second technique, the storage capacity of the CGROM 206 (storage means) is reduced. Therefore, the processing load on the display control circuit 230 does not increase. As a result, when the second method is used, even when the transparency is dynamically changed, the transparency is used without being affected by an increase in the processing load or pressure on the storage unit. It is possible to adjust the effect of the displayed image. In addition, when the second method is used, effect data can be generated for moving image data used as an effect without referring to an alpha table, and an effect alpha value (transparency data) can be generated. Need not be prepared in advance, it is possible to further reduce the processing load and the storage capacity.

  In the present embodiment, the above-described drawing processing and the processing of each step in the drawing processing are executed by the display control circuit 230 (sub-control circuit 200). That is, the display control circuit 230 (sub-control circuit 200) also serves as a unit for performing a drawing process (image control unit, drawing control unit). Further, the display control circuit 230 (sub-control circuit 200) performs processing of each step in the drawing processing (first image control means, first drawing control means (S421), second image control means (S423)). , Third image control means, second drawing control means (S424), fourth image control means, third drawing control means (S426 to S428), fifth image control means, fourth drawing control means (S431)). .

  Further, in the present embodiment, the alpha conversion process (the process performed during the operation of the arrows T3 and T14) during the drawing process is executed by the display control circuit 230 (sub-control circuit 200). That is, the display control circuit 230 (the sub-control circuit 200) also serves as a unit (a transparency setting unit, a first transparency setting unit, a second transparency setting unit) for performing an alpha conversion process. Further, the transfer processing and drawing processing of various data indicated by arrows in the drawing of the composition drawing processing are executed by the display control circuit 230 (sub-control circuit 200). That is, the display control circuit 230 (sub-control circuit 200) performs various data transfer processing and drawing processing in the composition drawing processing (first image generation control means (T16), second image generation control means (T17 and T18), the third image generation control means (T19), the fourth image generation control means (T20), the fifth image generation control means, and the sixth image generation control means (T22).

[Voice control processing]
Next, with reference to FIG. 100A and FIG. 100B, the audio control processing performed in S209 in the sub-control main processing (see FIG. 79) will be described. FIG. 100A is a flowchart illustrating a procedure of a voice control process performed by the host control circuit 210. FIG. 100B is a flowchart illustrating a procedure of processing executed by the audio / LED control circuit 220 when a sound request is output from the host control circuit 210 to the audio / LED control circuit 220 in the audio control processing.

(1) Voice Control Process Executed by Host Control Circuit The host control circuit 210 outputs the sound request stored in the request buffer in the animation request construction process of FIG. 92 to the voice / LED control circuit 220 (S441).

  In the present embodiment, the host control circuit 210 outputs a sound request after two frames have passed since the request for the production control in order to synchronize the operation of the sound reproduction production by the speaker 11 with the production operation by the display device 13. I do. This is because, as described above, in the image decoding process and the drawing process by the display control circuit 230 of the present embodiment, a series of processes requires a period of two frames.

  Then, after the processing of S441, the host control circuit 210 ends the voice control processing, and moves the processing to S210 of the sub-control main processing (see FIG. 79).

(2) Processing of the audio / LED control circuit executed during the audio control processing First, the sound request output from the host control circuit 210 is input to the audio / LED control circuit 220 (S451). Next, the audio / LED control circuit 220 determines whether or not there is an empty execution system capable of executing a process (code) among the four execution systems for audio reproduction (S452).

  In S452, if the audio / LED control circuit 220 determines that there is no empty execution system among the four execution systems for audio reproduction (if S452 is NO), the audio / LED control circuit 220 It waits until an execution system is generated (S453).

  After the processing in S453 or in S452, if the audio / LED control circuit 220 determines that there is an empty execution system among the four execution systems for audio reproduction (in the case of S452 being YES), the audio / LED The control circuit 220 sets an access number to a predetermined free execution system (S454).

  Next, the audio / LED control circuit 220 reads out the access data associated with the access number from the CGROM board 204 based on the access number in the execution system in which the access number is set (S455).

  Next, based on the access data, the audio / LED control circuit 220 sequentially sets each of the plurality of setting data specified in the access data to the corresponding address, and starts the execution process of the code (processing). (S456). By this processing, the sound reproduction effect by the speaker 11 is started. In the present embodiment, the sound reproduction control is executed by simple access control.

  Next, the audio / LED control circuit 220 determines whether there is a plurality of accesses to the code being referred to (S457). Specifically, the audio / LED control circuit 220 determines whether or not there is an access from another execution system to the code being referred to (setting data) executed in the execution system in which the access number is set. I do. In S457, when the audio / LED control circuit 220 determines that there is no multiple access to the code being referred to (when S457 is NO), the audio / LED control circuit 220 executes the processing of S459 described later. Do.

  On the other hand, if the voice / LED control circuit 220 determines in S457 that there is a plurality of accesses to the code being referenced (YES in S457), the voice / LED control circuit 220 executes the code. Is executed based on the latest sound request (S458). Specifically, for example, code 1, code 2, and code 3 are executed in a predetermined execution system based on a predetermined sound request, and code 3, code 3, and code 3 are executed in another execution system based on the next sound request. When executing the code 4 and the code 5, the sound reproduction of the code 3 having a plurality of accesses is executed based on the next sound request.

  After the processing of S458 or when NO is determined in S457, the audio / LED control circuit 220 sets a simple access end code (S459). Then, after the processing of S459, the audio / LED control circuit 220 ends the above-described series of processing at the time of the audio control processing, and returns the processing to a predetermined control state (for example, the standby state, the audio control (The control state before the processing, the control state of the processing executed after the voice control processing, etc.) are returned to the processing at the time.

[Lamp control processing]
Next, with reference to FIG. 101A and FIG. 101B, the ramp control process performed in S210 in the sub-control main process (see FIG. 79) will be described. FIG. 101A is a flowchart illustrating a procedure of a lamp control process performed by the host control circuit 210. FIG. 101B is a flowchart illustrating a procedure of processing executed by the audio / LED control circuit 220 in the lamp control processing.

  In the present embodiment, a description will be given of a processing example in a case where the above-described “NEXT” and “ODONLY” are not specified in the LED animation reproduction method. The ramp control process in consideration of the case where “NEXT” and “ODONLY” are specified as the reproduction method will be described in detail in Modifications 2 and 3 (see FIGS. 112 to 114 described later).

(1) Lamp Control Processing Executed by Host Control Circuit The host control circuit 210 outputs the lamp request stored in the request buffer in the animation request construction processing of FIG. 92 to the audio / LED control circuit 220 (S461). In the present embodiment, in order to synchronize the effect operation by the lamp (LED) group 18 with the effect operation by the display device 13, the host control circuit 210 transmits the lamp request after two frames have elapsed from the effect control request generation. Output.

  Then, after the processing of S461, the host control circuit 210 ends the ramp control processing, and moves the processing to S211 of the sub-control main processing (see FIG. 79).

(2) Processing of the audio / LED control circuit executed during the lamp control processing First, the lamp request output from the host control circuit 210 is input to the audio / LED control circuit 220 (S471).

  Next, the voice / LED control circuit 220 specifies the LED animation and data table information to be read from the CGROM 206 based on the lamp request (including the LED animation ID) (S472). If the LED animation is designated by this processing, the LED data to be output to each LED 281 can be designated. If the data table information is specified by this process, the data of the reproduction method, the reproduction channel, the extension channel, the light-off data identification, the control part, and the LED data name (for debugging) can be specified.

  Next, the audio / LED control circuit 220 refers to the specified data table information and acquires data such as a reproduction channel (sequencer, layer) for executing the LED animation (S473). Next, the audio / LED control circuit 220 determines whether or not there are a plurality of lamp requests for the same reproduction channel (S474).

  In S474, when the audio / LED control circuit 220 determines that there are a plurality of lamp requests on the same reproduction channel (when S474 is YES), the audio / LED control circuit 220 determines based on the last received lamp request. Then, the LED animation is set to the reproduction channel or the reproduction channel and the extension channel (the extension channel of the same channel as the reproduction channel) (S475). With this process, the data table information currently registered in the registration buffer of the reproduction channel or the registration buffers of the reproduction channel and the extension channel is overwritten by the data table information obtained based on the last received lamp request. Is done.

  On the other hand, in S474, when the audio / LED control circuit 220 determines that there are no multiple lamp requests on the same reproduction channel (when S474 is NO), the audio / LED control circuit 220 sets the reproduction channel or the reproduction The LED animation is set to the channel and the extension channel (S476). By this processing, the data table information acquired based on the currently received lamp request is registered in the registration buffer of the reproduction channel or the registration buffers of the reproduction channel and the extension channel.

  After the processing of S475 or S476, the audio / LED control circuit 220 converts the LED data (output data) to be set to the predetermined port of the control target (within the control part) in the predetermined channel based on the set LED animation by the CGROM 206. (S477). Note that the processing after S477 is executed for each port.

  Next, the audio / LED control circuit 220 determines whether or not there is an overlap of LED data (output data) between channels at a predetermined port, that is, whether or not it is necessary to combine LED data between a plurality of channels. Is determined (S478).

  In S478, when the audio / LED control circuit 220 determines that there is no overlap of the LED data between the channels at the predetermined port (when S478 is NO), the audio / LED control circuit 220 proceeds to S480 described later. Perform processing. On the other hand, in S478, when the audio / LED control circuit 220 determines that the LED data is duplicated between the channels at the predetermined port (if S478 is YES), the audio / LED control circuit 220 The LED data (luminance data) at a predetermined port is determined based on the LED data execution priority set in (S479).

  In the process of S479, for example, if the LED data is not set in the predetermined port to be processed before this process, the LED data acquired this time is set in the predetermined port. For example, if the LED data of a predetermined port set before this process is the LED data of a channel whose execution priority is lower than the channel being processed this time, the LED data acquired this time Overwrites the LED data of the predetermined port. For example, if the LED data of a predetermined port set before this processing is the LED data of a channel having a higher execution priority than the channel being processed this time, the LED data obtained this time Is discarded, and the LED data of the predetermined port is not overwritten (maintained). By repeating such processing for each channel, the LED data of a plurality of channels is synthesized at a predetermined port to be processed (the LED data of the channel with the highest execution priority among the plurality of channels is set). ).

  After the process of S479 or when the determination of S478 is NO, the audio / LED control circuit 220 determines whether the processes of S477 to S479 for the predetermined port have been executed for all the channels (eight channels in this embodiment). It is determined whether or not it is (S480).

  In S480, when the audio / LED control circuit 220 determines that the processes of S477 to S479 for the predetermined port have not been executed for all the channels (when S480 is NO), the audio / LED control circuit 220 In step S477, the process returns to step S477, changes the channel to be processed, and repeats the processing in step S477 and thereafter. On the other hand, in S480, when the audio / LED control circuit 220 determines that the processing of S477 to S479 for the predetermined port has been executed for all the channels (when S480 is YES), the audio / LED control circuit 220 220 determines whether or not the port direct specification data for the predetermined port is included in the lamp request, and if the port direct specification data is included in the lamp request, the sound / LED control circuit 220 Is overwritten with the port direct designation data (S481).

  Next, the audio / LED control circuit 220 determines whether or not the above-described processing of S477 to S481 has been executed for all ports (S482). Here, “all ports” means all ports set in the LED registration process shown in FIG. 84, but the present invention is not limited to this. “All ports” may be any ports that can be arbitrarily set physically regardless of the ports set in the LED registration process shown in FIG. 84, or may be set in the LED registration process shown in FIG. 84. Some ports selected from the selected ports may be used.

  In S482, when the audio / LED control circuit 220 determines that the processing of S477 to S481 is not executed for all ports (when S482 is NO), the audio / LED control circuit 220 performs the processing. Returning to step S477, the port to be processed is changed, and the processing from step S477 is repeated. On the other hand, in S482, when the audio / LED control circuit 220 determines that the processing of S477 to S481 has been performed for all ports (when S482 is determined to be YES), the audio / LED control circuit 220 performs the lamp control. After the above-described series of processing at the time of processing is completed, the processing is performed in a predetermined control state of the audio / LED control circuit 220 (for example, a standby state, a control state before the lamp control processing, a control state of processing performed after the lamp control processing, and the like). ) Return to the processing at the time.

[Accessory control processing]
Next, the accessory control processing performed in S211 in the sub-control main processing (see FIG. 79) will be described with reference to FIG. FIG. 102 is a flowchart illustrating the procedure of the accessory control process according to the present embodiment.

  First, the host control circuit 210 determines whether or not the current operation status is a standby operation for receiving a command from the main control circuit 70 (S491).

  In S491, when the host control circuit 210 determines that the current operation state is not the operation of waiting for receiving a command from the main control circuit 70 (NO in S491), the host control circuit 210 executes the accessory control processing. Are ended, and the process moves to S212 of the sub-control main process (see FIG. 79).

  On the other hand, in S491, when the host control circuit 210 determines that the current operation state is in the standby state for receiving a command from the main control circuit 70 (when S491 is determined to be YES), the host control circuit 210 returns to the main control circuit 210. It is determined whether or not a command related to the effect has been received from the control circuit 70 (S492). The commands related to the effects to be determined in this process are, for example, commands related to the start, stop, demonstration, and big hit of a special symbol. When these commands are received by the host control circuit 210, 20 moves.

  In S492, when the host control circuit 210 determines that the command relating to the effect has not been received from the main control circuit 70 (NO in S492), the host control circuit 210 ends the accessory control process, and To S212 of the sub-control main process (see FIG. 79).

  On the other hand, in S492, when the host control circuit 210 determines that the command related to the effect has been received from the main control circuit 70 (in the case of YES determination in S492), the host control circuit 210 performs the change start command reception character processing. Performed (S493). In this process, the host control circuit 210 mainly sets permission / non-permission of the transfer of the accessory request between the processes related to the accessory control executed by the host control circuit 210. The details of the character processing at the time of receiving the change start command will be described later with reference to FIG.

  Next, the host control circuit 210 performs the accessory processing when the demo command is received (S494). The details of the character processing at the time of receiving the demo command will be described later with reference to FIG. 104 described later. Next, the host control circuit 210 performs the accessory processing when the fluctuation stop command is received (S495). The details of the character processing at the time of receiving the fluctuation stop command will be described later with reference to FIG. Next, the host control circuit 210 performs the accessory processing when the big hit command is received (S496). The details of the bonus processing at the time of receiving the big hit command will be described later with reference to FIG. 107 described later.

  In the present embodiment, an example has been described in which the accessory processing at the time of receiving various commands in S493 to S496 is performed in the accessory control processing. However, the present invention is not limited to this. Each of the accessory processes may be performed as the inclusion process, or each of the accessory processes may be performed immediately after the above-described command analysis process (see FIG. 90).

  Next, the host control circuit 210 performs an initial position restoring operation process (S497). The details of the initial position restoring operation process will be described later with reference to FIG. Next, the host control circuit 210 determines whether or not the current operation status is a standby operation for receiving a command from the main control circuit 70 (S498).

  In S498, when the host control circuit 210 determines that the current operation state is the operation of waiting for reception of a command from the main control circuit 70 (when S498 is YES), the host control circuit 210 performs the processing in S492. , And the processing after S492 is repeated. On the other hand, in S498, when the host control circuit 210 determines that the current operation status is not the operation of waiting for reception of a command from the main control circuit 70 (NO in S498), the host control circuit 210 It is determined whether the request delivery permission is set (S499).

  In S499, when the host control circuit 210 determines that the transfer of the accessory request has not been set (NO in S499), the host control circuit 210 ends the accessory control process and proceeds to the sub process. The process moves to S212 of the control main process (see FIG. 79).

  On the other hand, in S499, when the host control circuit 210 determines that the transfer permission of the accessory request is set (in the case of YES determination in S499), the host control circuit 210 determines in the animation request construction process of FIG. The character request stored in the buffer is acquired (S500). In the present embodiment, the host control circuit 210 acquires a role item request after two frames have passed from the request generation of the direction control, in order to synchronize the direction operation by the role item 20 with the direction operation by the display device 13. .

  Next, the host control circuit 210 transmits the excitation data to the motor driver 271 via the I2C controller 261 based on the accessory request (S501). Next, the host control circuit 210 determines whether a communication error signal has been received from the I2C controller 261 (S502). In this process, the host control circuit 210 may determine whether a communication error between the I2C controller 261 and the motor controller 270 or an error of the I2C controller 261 has been detected (acquired or input).

  In S502, when the host control circuit 210 determines that a communication error signal has been received from the I2C controller 261 (when S502 is YES), the host control circuit 210 sets a communication controller error (S503). Then, after the processing of S503, the host control circuit 210 ends the accessory control processing, and moves the processing to S212 of the sub-control main processing (see FIG. 79).

  On the other hand, in S502, when the host control circuit 210 determines that the communication error signal has not been received from the I2C controller 261 (NO in S502), the host control circuit 210 accesses the address of each motor driver 271. It is determined whether or not it is possible (S504).

  If the host control circuit 210 determines in S504 that the address of each motor driver 271 cannot be accessed (NO in S504), the host control circuit 210 sets a connection error (S505). Then, after the processing of S505, the host control circuit 210 ends the accessory control processing, and moves the processing to S212 of the sub-control main processing (see FIG. 79).

  On the other hand, in S504, when the host control circuit 210 determines that the address of each motor driver 271 can be accessed (in the case of YES determination in S504), the host control circuit 210 continues until the effect operation by the accessory 20 ends. The object 20 (motor 272) is moved (S506). In this process, after the operation of the motor 272 stops, the accessory 20 (the motor 272) is moved until the sensor detects that the motor 272 (the accessory 20) has returned to the initial position.

  Next, the host control circuit 210 determines whether or not the operation of the accessory 20 (motor 272) ends normally (S507). In S507, when the host control circuit 210 determines that the operation of the accessory 20 (motor 272) has been completed normally (if S507 is YES), the host control circuit 210 ends the accessory control process, The processing moves to S212 of the sub-control main processing (see FIG. 79). On the other hand, in S507, when the host control circuit 210 determines that the operation of the accessory 20 (motor 272) is not normally terminated (NO in S507), the host control circuit 210 sets a data error. (S508). Then, after the processing of S508, the host control circuit 210 ends the accessory control processing, and moves the processing to S212 of the sub-control main processing (see FIG. 79).

[Processing of character when receiving start command]
Next, with reference to FIG. 103, the change-of-change-command-reception-receiving accessory processing performed in S493 in the accessory control processing (see FIG. 102) will be described. FIG. 103 is a flowchart showing the procedure of the character processing at the time of receiving the change start command in the present embodiment.

  First, the host control circuit 210 determines whether a change start command has been received (S511). Specifically, the host control circuit 210 determines, for example, whether or not the special symbol effect start command has been received.

  In S511, when the host control circuit 210 determines that the change start command has not been received (NO in S511), the host control circuit 210 ends the change start command reception character processing and ends the processing. The process moves to S494 of the accessory control process (see FIG. 102). On the other hand, if the host control circuit 210 determines in S511 that the change start command has been received (YES in S511), the host control circuit 210 determines whether all the motors 272 are at the initial position. (S512).

  In S512, when the host control circuit 210 determines that all the motors 272 are at the initial position (if S512 is YES), the host control circuit 210 sets permission to transfer the accessory request (S513). When the transfer permission of the accessory request is set, the control state of the accessory 20 shifts from the command reception standby state to the accessory request transfer permission state.

  Next, the host control circuit 210 sets “0” to the initial position restoration counter (S514). The initial position restoration counter is a counter that counts the number of times the motor 272 has performed the initial position restoration operation, and is provided in the subwork RAM 210a. Then, after the processing of S514, the host control circuit 210 ends the change processing command reception-time accessory processing, and moves the processing to S494 of the accessory control processing (see FIG. 102).

  On the other hand, in S512, when the host control circuit 210 determines that the one or more motors 272 are not at the initial position (in the case of NO determination in S512), the host control circuit 210 sets the non-permission of the accessory request. (S515). Next, the host control circuit 210 performs a transition setting to the initial position restoring operation (S516). Then, after the processing of S516, the host control circuit 210 terminates the change processing command reception accessory processing, and shifts the processing to S494 of the accessory control processing (see FIG. 102).

[Processing of character objects when receiving demo command]
Next, with reference to FIG. 104, a description will be given of the demo command receiving accessory processing performed in S494 during the accessory control processing (see FIG. 102). FIG. 104 is a flowchart illustrating the procedure of the accessory processing upon receiving a demo command in the present embodiment.

  First, the host control circuit 210 determines whether a demo command has been received (S521). Specifically, for example, the host control circuit 210 determines whether or not the above-described demonstration display command has been received.

  In S521, when the host control circuit 210 determines that the demo command has not been received (if S521 is NO), the host control circuit 210 ends the demo command reception character processing, and terminates the processing. The process moves to S495 of the control process (see FIG. 102). On the other hand, if the host control circuit 210 determines in S521 that the demo command has been received (YES in S521), the host control circuit 210 determines whether an error due to a failure of the motor 272 or the like has been detected. It is determined (S522). In this process, the host control circuit 210 determines whether various errors (communication controller error, connection error, data error) set in the processes after S502 in the accessory control process (see FIG. 102) have occurred. It is determined whether or not.

  In S522, when the host control circuit 210 determines that an error due to a malfunction of the motor 272 or the like is detected (YES in S522), the host control circuit 210 performs an error process (S523). The details of the error processing will be described later with reference to FIG. Next, the host control circuit 210 performs a setting for shifting to the error operation at the time of the accessory operation (S524). Then, after the process of S524, the host control circuit 210 ends the demo command reception accessory processing, and shifts the processing to S495 of the accessory control processing (see FIG. 102).

  On the other hand, in S522, when the host control circuit 210 determines that an error due to a failure of the motor 272 or the like has not been detected (NO in S522), the host control circuit 210 determines that all the motors 272 are in the initial position. It is determined whether or not there is (S525).

  In S525, if the host control circuit 210 determines that the one or more motors 272 are not at the initial position (if S525 is NO), the host control circuit 210 ends the demo command reception character processing, The processing moves to S495 of the accessory control processing (see FIG. 102). On the other hand, in S525, if the host control circuit 210 determines that all the motors 272 are at the initial position (if S525 is YES), the host control circuit 210 performs the accessory excitation release processing (S526). In this process, the host control circuit 210 stops outputting excitation data to all the motors 272 (motor drivers 271).

  Next, the host control circuit 210 sets the transfer permission of the accessory request (S527). Next, the host control circuit 210 sets “0” to the initial position restoration counter (S528). Then, after the processing of S528, the host control circuit 210 ends the demo command reception accessory processing, and shifts the processing to S495 of the accessory control processing (see FIG. 102).

[Error processing]
Next, with reference to FIG. 105, an explanation will be given on the error processing performed in S523 during the demo command reception accessory processing (see FIG. 104). FIG. 105 is a flowchart showing the procedure of the error processing in this embodiment.

  First, the host control circuit 210 sets the non-permission of the accessory request (S531). Next, the host control circuit 210 stops all the motors 272 (S532).

  Next, the host control circuit 210 resets the software of the motor driver 271 (S533). Next, the host control circuit 210 resets the I2C controller 261 (S534). Then, after the processing of S534, the host control circuit 210 ends the error processing, and shifts the processing to S524 of the demo command reception accessory processing (see FIG. 104).

[Character processing when receiving a fluctuation stop command]
Next, with reference to FIG. 106, a description will be given of the change-of-variable-stop-command-received character processing performed in S495 in the character-control processing (see FIG. 102). FIG. 106 is a flowchart showing the procedure of the character processing at the time of receiving the fluctuation stop command in the present embodiment.

  First, the host control circuit 210 determines whether a fluctuation stop command has been received (S541). Specifically, the host control circuit 210 determines, for example, whether or not the special symbol stop command has been received.

  In S541, if the host control circuit 210 determines that the fluctuation stop command has not been received (if S541 is NO), the host control circuit 210 ends the fluctuation stop command reception character processing and ends the processing. The process moves to S496 of the accessory control process (see FIG. 102). On the other hand, in S541, when the host control circuit 210 determines that the fluctuation stop command has been received (YES in S541), the host control circuit 210 determines whether an error due to a failure of the motor 272 or the like has been detected. Is determined (S542).

  In S542, when the host control circuit 210 determines that an error due to a failure of the motor 272 or the like is detected (YES in S542), the host control circuit 210 performs the error processing described with reference to FIG. 105 ( S543). Next, the host control circuit 210 performs a setting for shifting to the accessory operation error operation (S544). Then, after the processing of S544, the host control circuit 210 ends the change processing command upon reception of the fluctuation stop command, and shifts the processing to S496 of the control processing of the character (see FIG. 102).

  On the other hand, in S542, when the host control circuit 210 determines that an error due to a failure of the motor 272 or the like has not been detected (NO in S542), the host control circuit 210 determines that all the motors 272 are in the initial position. It is determined whether or not there is (S545).

  In S545, if the host control circuit 210 determines that the one or more motors 272 are not at the initial position (if S545 is NO), the host control circuit 210 ends the variable stop command reception character processing. Then, the process proceeds to S496 of the accessory control process (see FIG. 102). On the other hand, in S545, if the host control circuit 210 determines that all the motors 272 are at the initial position (if S545 is YES), the host control circuit 210 sets permission to transfer the accessory request (S546). ).

  Next, the host control circuit 210 sets “0” to the initial position restoration counter (S547). Then, after the processing of S547, the host control circuit 210 terminates the change processing command upon reception of the fluctuation stop command, and shifts the processing to S496 of the control processing of character (see FIG. 102).

[Processing of the accessory when receiving the big hit command]
Next, with reference to FIG. 107, the bonus item processing at the time of receiving a jackpot command performed in S496 in the bonus item control process (see FIG. 102) will be described. FIG. 107 is a flowchart showing the procedure of the bonus item processing at the time of receiving a big hit command in the present embodiment.

  First, the host control circuit 210 determines whether or not a big hit command has been received (S551). Specifically, the host control circuit 210 determines, for example, whether or not the special symbol hit start display command has been received.

  In S551, when the host control circuit 210 determines that the jackpot-related command has not been received (NO in S551), the host control circuit 210 ends the jackpot-based command reception character processing and ends the processing. The process moves to S497 of the accessory control process (see FIG. 102). On the other hand, in S551, if the host control circuit 210 determines that the big hit command has been received (if S551 is YES), the host control circuit 210 determines whether all the motors 272 are at the initial position. (S552).

  In S552, when the host control circuit 210 determines that one or more motors 272 are not at the initial position (NO in S552), the host control circuit 210 performs the processing of S554 described later. On the other hand, in S552, if the host control circuit 210 determines that all the motors 272 are at the initial position (if S552 is YES), the host control circuit 210 sets permission to transfer the accessory request (S553). ).

  After the processing of S553 or when the determination of S552 is NO, the host control circuit 210 sets “0” to the initial position restoration counter (S554). Then, after the processing of S554, the host control circuit 210 ends the jackpot processing at the time of receiving the jackpot command, and shifts the processing to S497 of the accessory control processing (see FIG. 102).

[Initial position recovery operation processing]
Next, with reference to FIG. 108, the initial position restoring operation process performed in S497 in the accessory control process (see FIG. 102) will be described. FIG. 108 is a flowchart showing the procedure of the initial position restoring operation processing in the present embodiment.

  First, the host control circuit 210 determines whether or not the transfer of the accessory request is set (S561).

  In S561, when the host control circuit 210 determines that the transfer of the accessory request is set (if S561 is YES), the host control circuit 210 ends the initial position restoring operation processing, and executes the processing. The process moves to S498 of the accessory control process (see FIG. 102). On the other hand, in S561, when the host control circuit 210 determines that the transfer permission of the accessory request is not set (in the case of NO determination in S561), the host control circuit 210 shifts to the error operation at the time of the accessory operation. It is determined whether or not is set (S562).

  In S562, when the host control circuit 210 determines that the shift to the accessory-operation-time error operation has not been set (NO in S562), the host control circuit 210 performs the processing of S565 described later.

  On the other hand, in S562, if the host control circuit 210 determines that the shift to the error operation at the time of the accessory operation is set (if S562 is YES), the host control circuit 210 determines the operation of the accessory 20. The process ends (S563). Next, the host control circuit 210 performs a transition setting to the initial position restoring operation (S564).

  After the processing of S564 or when the determination of S562 is NO, the host control circuit 210 determines whether or not the transition to the initial position restoring operation is set (S565).

  In S565, when the host control circuit 210 determines that the transition to the initial position restoring operation is not set (NO in S565), the host control circuit 210 ends the initial position restoring operation processing, and Is moved to S498 of the accessory control process (see FIG. 102). On the other hand, in S565, when the host control circuit 210 determines that the shift to the initial position restoration operation has been set (when S565 is YES), the host control circuit 210 sets the value of the initial position restoration counter to " "1" is added (S566).

  Next, the host control circuit 210 determines whether or not the value of the initial position restoration counter is “10” or more (S567).

  In S567, when the host control circuit 210 determines that the value of the initial position restoration counter is not equal to or more than “10” (NO in S567), the host control circuit 210 moves all the motors 272 to the initial position. (S568). Next, the host control circuit 210 determines whether or not all the motors 272 are at the initial position (S569).

  In S569, when the host control circuit 210 determines that one or more motors 272 are not at the initial position (when S569 is NO), the host control circuit 210 returns the processing to S566, and performs the processing from S566 and on. repeat. On the other hand, in S569, if the host control circuit 210 determines that all the motors 272 are at the initial position (if S569 is YES), the host control circuit 210 performs a transition setting to the command reception standby operation (S569). S570). After the processing of S570, the host control circuit 210 ends the initial position restoring operation processing, and moves the processing to S498 of the accessory control processing (see FIG. 102).

  Here, returning to the process of S567 again, in S567, when the host control circuit 210 determines that the value of the initial position restoration counter is “10” or more (when S567 is YES), the host control circuit 210 210 sets the non-permission of the transfer of the accessory request (S571). Next, the host control circuit 210 stops all the motors 272 until an initialization process is performed by turning on the power again (S572).

  Note that, in the present embodiment, as described above, an example in which the motor 272 is stopped when the value of the initial position restoration counter is “10” or more has been described, but the present invention is not limited to this. The threshold value of the initial position restoration counter for stopping the motor 272 can be arbitrarily set according to, for example, the effect operation of the accessory 20 and the performance of the motor 272.

  Then, after the processing of S572, the host control circuit 210 ends the initial position restoring operation processing, and shifts the processing to S498 of the accessory control processing (see FIG. 102).

[Data communication processing between voice / LED control circuit and LED driver]
Next, a communication process performed between the audio / LED control circuit 220 and the LED driver 280 will be described with reference to FIGS. 109A and 109B. FIG. 109A is a flowchart illustrating a procedure of signal and data transmission processing executed by the audio / LED control circuit 220 in communication processing between the audio / LED control circuit 220 and the LED driver 280. FIG. 109B is a flowchart illustrating a signal and data reception process performed by the LED driver 280 in the communication process between the audio / LED control circuit 220 and the LED driver 280.

  In the present embodiment, when a lamp request is input from the host control circuit 210 to the audio / LED control circuit 220, the audio / LED control circuit 220 outputs lamp output data (LED data) based on the lamp request. 18 is transmitted to each LED driver 280 included. At this time, since the audio / LED control circuit 220 and the LED driver 280 are connected by the SPI bus as described above, signal and serial data communication is performed between the two by the SPI method. In the present embodiment, the communication mode between the audio / LED control circuit 220 and the LED driver 280 is a mode in which signals and serial data are transmitted from the audio / LED control circuit 220 to the LED driver 280 unilaterally.

  The specific procedure of the signal / serial data transmission processing executed by the audio / LED control circuit 220 and the data reception processing executed by the LED driver 280 based on the lamp request will be described below with reference to FIG. And a flowchart of FIG. 109B. In this embodiment, the configuration of the serial data transmitted from the audio / LED control circuit 220 is the configuration described with reference to FIG.

(1) Serial Data Transmission Process of Audio / LED Control Circuit First, as shown in FIG. 109A, the audio / LED control circuit 220 transmits data “1” to the LED driver 280 continuously 16 times or more ( S581). That is, the audio / LED control circuit 220 transmits to the LED driver 280 the data (see FIG. 46) in the area where the data “1”, which is arranged at the head of the serial data, is continuously stored for 16 bits or more.

  Next, the audio / LED control circuit 220 transmits the device address to the LED driver 280 (S582). Next, the audio / LED control circuit 220 transmits the register address to the LED driver 280 (S583).

  Next, the audio / LED control circuit 220 transmits the lamp output data (LED data) to the LED driver 280 (S584). Then, after the processing of S584, the audio / LED control circuit 220 ends the transmission processing of the serial data.

(2) LED driver reception processing (state transition processing based on received data)
First, the LED driver 280 sets a sleep state as shown in FIG. 109B (S591). Note that “to sleep” means that the operation state of the LED driver 280 is set to a sleep (pause) state to be in an operation standby state. The set sleep state is released when the LED driver 280 receives (detects) the first data “1” from the audio / LED control circuit 220.

  Next, the LED driver 280 determines whether or not data “1” has been received (detected) 16 times continuously from the audio / LED control circuit 220 (S592).

  In S592, when the LED driver 280 determines that the data “1” has not been received (detected) from the audio / LED control circuit 220 16 times in a row (NO in S592), the LED driver 280 performs the processing. Is returned to S591, and the processing of S591 and thereafter is repeated. On the other hand, in S592, when the LED driver 280 determines that the data “1” has been received (detected) from the audio / LED control circuit 220 16 times in a row (in the case of YES determination in S592), the LED driver 280 starts. The standby state is set (S593).

  Next, the LED driver 280 determines whether or not data “0” has been received (S594). In this process, the LED driver 280 determines whether or not data “0” (see FIG. 46) stored in the first bit of the device address has been received.

  In S594, when the LED driver 280 determines that the data “0” has not been received (NO in S594), the LED driver 280 returns the processing to S593, and repeats the processing from S593. If the LED driver 280 does not receive the data “0” for a predetermined time and the start standby state continues, the LED driver 280 may perform processing to return the operation state to the sleep state as time-out processing. .

  On the other hand, in S594, when the LED driver 280 determines that the data “0” has been received (YES in S594), the LED driver 280 sets a device address waiting state (S595).

  Next, the LED driver 280 receives the device address transmitted from the audio / LED control circuit 220, and determines whether or not the device address matches that set in the LED driver 280 (S596). In S596, if the LED driver 280 determines that the received device address does not match that set in the LED driver 280 (NO in S596), the LED driver 280 returns the process to S591, and returns to S591 and thereafter. Is repeated. On the other hand, in S596, when the LED driver 280 determines that the received device address matches that set in the LED driver 280 (if S596 is YES), the LED driver 280 sets the register address waiting state. (S597).

  Next, the LED driver 280 receives the register address transmitted from the audio / LED control circuit 220, and determines whether or not the register address is an existing register address (S598). In S598, if the LED driver 280 determines that the received register address is not a register address that exists (NO in S598), the LED driver 280 returns the process to S591, and repeats the processes in S591 and thereafter.

  On the other hand, in S598, when the LED driver 280 determines that the received register address is the existing register address (when S598 is YES), the LED driver 280 sets the data reception state (S599). Thereby, the reception process of the lamp output data (LED data) transmitted from the audio / LED control circuit 220 is started. Next, the LED driver 280 determines whether or not data “0FFH (1111111B)” (see FIG. 46) indicating the last data of the lamp output data (LED data) has been received (S600).

  In S600, if the LED driver 280 determines that the data “0FFH” has not been received (NO in S600), the LED driver 280 returns the process to S599, and repeats the processes from S599. On the other hand, in S600, when it is determined that the LED driver 280 has received the data “0FFH” (YES in S600), the LED driver 280 returns the process to S591, and repeats the processes in S591 and thereafter.

[Data communication processing between host control circuit and motor driver]
Next, a communication process performed between the host control circuit 210 and the motor driver 271 will be described with reference to FIGS. 110A and 110B. FIG. 110A is a flowchart illustrating a procedure of a signal and serial data transmission / reception process executed by the host control circuit 210 in the communication process between the host control circuit 210 and the motor driver 271. FIG. 110B is a flowchart illustrating a procedure of a signal and data transmission / reception process executed by the motor driver 271 in the communication process between the host control circuit 210 and the motor driver 271.

  In the present embodiment, when the accessory request is generated in the host control circuit 210 as described above, the host control circuit 210 outputs the excitation data to the motor driver 271 based on the accessory request. At this time, since the host control circuit 210 and the motor driver 271 are connected by the I2C bus, signals (data) are transmitted and received between them by the I2C method. In the present embodiment, the communication direction between the host control circuit 210 and the motor driver 271 is bidirectional.

  Hereinafter, specific procedures of signal and data transmission / reception processing executed by the host control circuit 210 and signal / data transmission / reception processing executed by the motor driver 271 based on the accessory request will be described with reference to FIG. This will be described with reference to the flowchart of FIG. 110B.

(1) Data transmission / reception processing of the host control circuit 210 (serial data input / output processing)
First, as shown in FIG. 110A, the host control circuit 210 issues a start condition and transmits a control byte to all the motor drivers 271 connected to the host control circuit 210 via the I2C bus (S601). . The control byte transmitted in this process includes address information for specifying a predetermined motor driver 271 to which data is to be transmitted, and whether the motor driver 271 receives data from the host control circuit 210 or receives data from the motor driver 271. 271 includes a value of a transmission / reception bit to be described later, which determines whether to transmit data to the host control circuit 210.

  Next, the host control circuit 210 transmits and receives serial data to and from a predetermined motor driver 271 (S602). If the value of the transmission / reception bit included in the control byte transmitted to the motor driver 271 in step S601 is a value corresponding to the operation of the motor driver 271 to receive data from the host control circuit 210, the process proceeds to step S602. The control circuit 210 transmits, for example, excitation data of the motor 272 to the motor driver 271. On the other hand, if the value of the transmission / reception bit included in the control byte transmitted to the motor driver 271 in S601 is a value corresponding to the operation of the motor driver 271 transmitting data to the host control circuit 210, the processing in S602 In, the host control circuit 210 receives, for example, error information and the like from the motor driver 271.

  Next, when the data transmission / reception processing is completed, the host control circuit 210 issues a stop condition (S603). Then, the host control circuit 210 ends the data transmission / reception processing at the time of obtaining the accessory request.

(2) Data Transmission / Reception Processing of Motor Driver First, as shown in FIG. 110B, the motor driver 271 refers to the information of the control byte included in the start condition issued by the host control circuit 210, and stores the control byte in the control byte. It is determined whether the included address matches the address of the motor driver 271 (S611). The configuration of the serial data transmitted from the host control circuit 210 to the motor driver 271 is not the same as the configuration of the serial data shown in FIG. 46, an area corresponding to the device address in FIG. 46 is provided, and the above-mentioned control byte information is stored in this area.

  In S611, when the motor driver 271 determines that the address included in the control byte does not match the address of the motor driver 271 (when S611 is NO), the motor driver performs the process of S614 described later. .

  On the other hand, in S611, when the motor driver 271 determines that the address included in the control byte matches the address of the motor driver 271 (if S611 is YES), the motor driver 271 determines that the address included in the control byte is included. Based on the value of the transmitted / received bit, predetermined data (error information or the like) is transmitted to the host control circuit 210 or specific data (excitation data or the like) is received (S612).

  Next, the motor driver 271 determines whether or not the stop condition issued from the host control circuit 210 has been received (S613). In S613, when the motor driver 271 determines that the stop condition issued from the host control circuit 210 has been received (YES in S613), the motor driver 271 performs the processing of S614 described later. On the other hand, in S613, when the motor driver 271 determines that the stop condition issued from the host control circuit 210 has not been received (NO in S613), the motor driver 271 returns the process to S612. The processing after S612 is repeated.

  Then, when S611 is NO or S613 is YES, the motor driver 271 shifts the state to the standby state (S614). If the determination in S611 is NO, that is, if the motor driver 271 is not the motor driver 271 that transmits and receives data to and from the host control circuit 210, it is in a standby state at the time of the processing in S614. The motor driver 271 performs a process of maintaining the standby state.

<Various modifications>
The configuration of the pachinko gaming machine according to the present invention and the control method of the staging operation are not limited to the example of the above-described embodiment, and various modified examples are conceivable. Hereinafter, various modifications thereof will be described.

[Modification 1]
In the audio control process (see FIGS. 100A and 100B) of the above embodiment, when the audio / LED control circuit 220 sets the access number to the execution system of sound reproduction, it determines the vacant state of the four execution systems, Although an example has been described in which an access number is set to a vacant execution system, the present invention is not limited to this. For example, an execution system to be set for each access number may be determined in advance. In the first modification, a processing example of the voice control processing in such a case will be described.

  In the first modification, processes other than the voice control process can be executed in the same manner as in the above embodiment, and the configuration of the pachinko gaming machine of this example can be the same as that of the above embodiment. Therefore, here, only the voice control processing will be described.

  With reference to FIG. 111A and FIG. 111B, a description will be given of the voice control process of the first modification performed in S209 in the sub-control main process (see FIG. 79). FIG. 111A is a flowchart illustrating the procedure of the voice control process of this example executed by the host control circuit 210. FIG. 111B is a flowchart illustrating a procedure of processing executed by the audio / LED control circuit 220 in the audio control processing of this example.

(1) Voice control processing executed by the host control circuit As shown in FIG. 111A, the host control circuit 210 sends the sound request stored in the request buffer in the animation request construction processing of FIG. The data is output (S701). Also in this example, the host control circuit 210 outputs a sound request after two frames elapse from the request for effect control in order to synchronize the effect operation using the LED data with the effect operation by the display device 13. .

  Then, after the processing of S701, the host control circuit 210 ends the voice control processing, and moves the processing to S210 of the sub-control main processing (see FIG. 79).

(2) Audio / LED Control Circuit Process Executed During Audio Control Process First, as shown in FIG. 111B, a sound request output from the host control circuit 210 is input to the audio / LED control circuit 220 (S711). . Next, the audio / LED control circuit 220 specifies an access number based on the sound request (S712). Next, the sound / LED control circuit 220 determines a sound reproduction execution system for setting the access number based on the specified access number (S713).

  Next, the sound / LED control circuit 220 determines whether or not the process is being executed in the determined execution system (S714).

  In S714, when the sound / LED control circuit 220 determines that the process is not being executed in the determined execution system (when S714 is NO), the sound / LED control circuit 220 accesses the determined execution system. The number is set (S715). On the other hand, in S714, when the sound / LED control circuit 220 determines that the process is being executed in the determined execution system (when S714 is YES), the sound / LED control circuit 220 determines After the processing of the access number currently executed in the system, the access number specified in S712 is set in the execution system so that the processing of the access number specified in S712 is executed (S716). In this case, in the execution system determined in S713, the operation state of the audio / LED control circuit 220 is in a standby state until the processing of the currently executed access number ends.

  After the processing of S715 or S716, the audio / LED control circuit 220 reads the access data associated with the access number from the CGROM board 204 in the execution system in which the access number has been set (S717).

  Next, based on the access data, the audio / LED control circuit 220 sequentially sets each of the plurality of setting data specified in the access data to the corresponding address, and starts the execution process of the code (processing). (S718). With this processing, the effect operation of sound reproduction by the speaker 11 is started. At this time, also in this example, the audio reproduction control is executed by the simple access control.

  After the processing of S718, the voice / LED control circuit 220 determines whether or not there is a plurality of accesses to the code being referred to (S719). Specifically, the audio / LED control circuit 220 determines whether or not there is an access from another execution system to the code being referred to (setting data) executed in the execution system in which the access number is set. I do.

  In S719, when the audio / LED control circuit 220 determines that there is no multiple access to the code being referred to (when S719 is NO), the audio / LED control circuit 220 executes the processing of S721 described later. Do. On the other hand, if the voice / LED control circuit 220 determines in S719 that there is a plurality of accesses to the code being referred to (if S719 is YES), the voice / LED control circuit 220 returns The code is executed based on the latest sound request (S720).

  After the processing of S720 or when the determination of S719 is NO, the audio / LED control circuit 220 sets a simple access end code (S721). Then, after the processing of S721, the audio / LED control circuit 220 ends the above-described series of processing at the time of the audio control processing, and returns the processing to a predetermined control state (for example, standby state, audio control (The control state before the processing, the control state of the processing executed after the voice control processing, etc.) are returned to the processing at the time.

[Modification 2]
In the lamp control process (see FIG. 101A and FIG. 101B) of the above-described embodiment, an example of the process in the case where “NEXT” and / or “ODONLY” is not specified in the playback method of the LED data (LED animation) has been described. Is not limited to this. In the second modification, a description will be given of a lamp control process that also takes into consideration a case where “NEXT” and / or “ODONLY” is specified as a reproduction method of LED data (LED animation). In the second modification, a processing example using only the reproduction channel will be described.

  In the second modification, processes other than the ramp control process can be executed in the same manner as in the above embodiment, and the configuration of the pachinko gaming machine in this example can be the same as that of the above embodiment. Therefore, here, only the lamp control processing will be described.

  With reference to FIGS. 112A and 112B, a description will be given of the lamp control process of the second modification performed in S210 in the sub-control main process (see FIG. 79). FIG. 112A is a flowchart illustrating the procedure of the lamp control process of this example executed by the host control circuit 210. FIG. 112B is a flowchart illustrating a procedure of processing executed by the audio / LED control circuit 220 in the lamp control processing of this example.

(1) Lamp Control Process Executed by Host Control Circuit The host control circuit 210 outputs the lamp request stored in the request buffer in the animation request process of FIG. 92 to the audio / LED control circuit 220 as shown in FIG. 112A. (S731). Also in this example, the host control circuit 210 outputs a lamp request after two frames have passed since the request for effect control in order to synchronize the effect operation using the LED data with the effect operation by the display device 13. .

  Then, after the processing of S731, the host control circuit 210 ends the lamp control processing of this example, and moves the processing to S211 of the sub-control main processing (see FIG. 79).

(2) Processing of Audio / LED Control Circuit Executed During Lamp Control Processing First, as shown in FIG. 112B, a lamp request transmitted from the host control circuit 210 is input to the audio / LED control circuit 220 (S741). .

  Next, the audio / LED control circuit 220 specifies a reproduction channel (sequencer, layer) for executing the LED animation based on the lamp request (S742). Specifically, the audio / LED control circuit 220 specifies the LED animation (various LED data) and data table information to be read from the CGROM 206 based on the lamp request, and executes the LED animation with reference to the data table information. Data of the playback channel (sequencer, layer) to be executed.

  Next, the audio / LED control circuit 220 determines whether or not “NEXT” is specified as the LED animation reproduction method based on the data table information specified by the reproduction channel to be processed (during reference), ie, It is determined whether or not the performed lamp request is a request for immediately executing the lamp lighting operation (S743). Although not shown here, the processing from S743 to S745 to be described later is repeatedly executed by the number of channels.

  In step S743, when the audio / LED control circuit 220 determines that “NEXT” is not specified as the LED animation reproduction method of the reproduction channel being referred to (in the case of YES in S743), the audio / LED control circuit 220 Updates the various information (data table information and LED data) currently stored in the registration buffer of the reproduction channel with the corresponding various information acquired at the time of receiving the current lamp request (S744).

  On the other hand, in step S743, when the audio / LED control circuit 220 determines that “NEXT” is specified as the LED animation reproduction method of the reproduction channel being referred to (in the case of NO in S743), the audio / LED control After the various information (data table information and LED data) currently stored in the registration buffer, the circuit 220 additionally stores (adds and updates) the corresponding various information acquired when the current lamp request is received (S745). ).

  After the processing of S744 or the processing of S745, the audio / LED control circuit 220 performs a reference processing of the registration buffer of each reproduction channel (S746). Next, the audio / LED control circuit 220 determines the SPI channel (physical system) to be used when transmitting the LED data to the LED driver 280 based on the information of the control part included in the data table information stored in the registration buffer. Specify (S747).

  Next, the audio / LED control circuit 220 determines whether or not the port to be processed (being referenced) is a port to be controlled (in the control part) in the predetermined channel (S748). Note that the determination processing in S748 is executed based on the information of the control part included in the data table information stored in the registration buffer, and the processing from S748 is repeatedly executed by the number of ports.

  In S748, when the audio / LED control circuit 220 determines that the port being referred to is not the port to be controlled (NO in S748), the audio / LED control circuit 220 performs the process of S752 described later. On the other hand, in step S748, when the audio / LED control circuit 220 determines that the port being referred to is a port to be controlled (YES in step S748), the audio / LED control circuit 220 determines based on the data table information. Then, it is determined whether or not “ODONLY” is specified as the reproduction method in the reproduction channel (control section) to be processed (S749).

  In S749, if the audio / LED control circuit 220 determines that “ODONLY” is specified as the reproduction method in the reproduction channel to be processed (being referred to) (if S749 is YES), the audio / LED control The circuit 220 performs the port information (LED data) overwriting process based on the execution priority set for the channel and the presence or absence of output data (S750).

  In the process of S750, for example, the audio / LED control circuit 220 determines that the processing target channel has a higher execution priority than the channel corresponding to the LED data currently set to the port, and the port (control If there is LED data (LED data other than the light-off data) output to the target port), the LED data is overwritten on the LED data currently set to the port. On the other hand, if the processing target channel has a higher execution priority than the channel corresponding to the LED data currently set to the port, and there is no LED data to be output to the port being referred to (the output data is ), The LED data overwriting process is not performed, and the LED data currently set in the port is maintained. If the processing target channel has a lower execution priority than the channel corresponding to the LED data currently set to the port, the LED data is output regardless of the presence or absence of the LED data output to the referenced port. Is not performed, and the LED data currently set in the port is maintained.

  On the other hand, in S749, if the audio / LED control circuit 220 determines that “ODONLY” is not specified as the reproduction method in the reproduction channel to be processed (being referred to) (if S749 is NO), The LED control circuit 220 performs an overwriting process of the port information (LED data) based on the execution priority set for the channel (S751).

  In the process of S751, for example, if the channel to be processed has a higher execution priority than the channel corresponding to the LED data currently set to the port, the audio / LED control circuit 220 Overwrite the LED data currently set in the port. At this time, even when the output data is LED data (light-off data) of the transparent definition, the overwriting process of the LED data is performed. On the other hand, if the processing target channel has a lower execution priority than the channel corresponding to the LED data currently set to the port, the overwriting process of the LED data is not performed, and the LED currently set to the port is not processed. Data is maintained.

  After the processing of S750 or S751, or when the determination of S748 is NO, the audio / LED control circuit 220 determines that the processing of S748 to S751 described above is performed for all the reproduction channels (for eight channels) of the port being referred to. It is determined whether or not the execution has been performed (S752).

  In S752, when the audio / LED control circuit 220 determines that the processing of S748 to S751 has not been executed for all the reproduction channels (when S752 is NO), the audio / LED control circuit 220 performs the processing Is returned to S748, the reproduction channel to be processed is changed, and the processing from S748 is repeated.

  On the other hand, in S752, when the audio / LED control circuit 220 determines that the processing of S748 to S751 has been executed for all reproduction channels (when S752 is YES), the audio / LED control circuit 220 refers to It is determined whether or not the port direct designation data for the middle port is included in the lamp request, and if the port direct designation data is included in the lamp request, the audio / LED control circuit 220 Is overwritten with the port direct designation data (S753).

  Next, the audio / LED control circuit 220 determines whether or not the above-described processing of S748 to S753 has been executed for all ports (S754). Here, “all ports” means all ports set in the LED registration process shown in FIG. 84, but the present invention is not limited to this. “All ports” may be any ports that can be arbitrarily set physically regardless of the ports set in the LED registration process shown in FIG. 84, or may be set in the LED registration process shown in FIG. 84. Some ports selected from the selected ports may be used.

  In S754, when the audio / LED control circuit 220 determines that the processing of S748 to S753 has not been executed for all ports (when S754 is NO), the audio / LED control circuit 220 performs the processing. The process returns to S748, the port to be processed is changed, and the process from S748 is repeated. On the other hand, in S754, when the audio / LED control circuit 220 determines that the processing of S748 to S753 has been executed for all ports (when S754 is YES), the audio / LED control circuit 220 determines whether the lamp control is performed. After the above-described series of processing at the time of processing is completed, the processing is performed in a predetermined control state of the audio / LED control circuit 220 (for example, a standby state, a control state before the lamp control processing, a control state of processing performed after the lamp control processing, and the like) ) Return to the processing at the time.

[Modification 3]
In the third modification, a description will be given of a processing example in which not only the reproduction channel but also the extension channel is used in the ramp control processing of the second modification. In the third modification, processes other than the ramp control process can be executed in the same manner as in the above embodiment, and the configuration of the pachinko gaming machine of this example can be the same as that of the above embodiment. Therefore, here, only the lamp control processing will be described.

  With reference to FIG. 113A and FIG. 113B, a description will be given of a ramp control process of the third modification performed in S210 in the sub-control main process (see FIG. 79). FIG. 113A is a flowchart illustrating the procedure of the lamp control process of this example executed by the host control circuit 210. FIG. 113B is a flowchart illustrating a procedure of processing performed by the audio / LED control circuit 220 in the lamp control processing of this example.

(1) Lamp Control Processing Executed by Host Control Circuit The host control circuit 210 outputs the lamp request stored in the request buffer in the animation request processing of FIG. 92 to the audio / LED control circuit 220 as shown in FIG. 113A. (S761). Also in this example, the host control circuit 210 transmits a lamp request after two frames have passed from the production of the production control request in order to synchronize the production operation using the LED data with the production operation by the display device 13. .

  Then, after the processing of S761, the host control circuit 210 ends the lamp control processing of this example, and moves the processing to S211 of the sub-control main processing (see FIG. 79).

(2) Processing of Audio / LED Control Circuit Executed During Lamp Control Processing First, as shown in FIG. 113B, a lamp request transmitted from the host control circuit 210 is input to the audio / LED control circuit 220 (S771). .

  Next, the audio / LED control circuit 220 specifies a channel (sequencer, layer) for executing the LED animation based on the lamp request (S772). When an extended channel is used, in this process, the audio / LED control circuit 220 specifies a sequencer or a layer to be used in the extended channel and a reproduction channel of the same channel. On the other hand, when the extension channel is not used, in this processing, the audio / LED control circuit 220 specifies a sequencer or a layer to be used for the reproduction channel.

  Next, the audio / LED control circuit 220 determines whether or not “NEXT” is specified as the LED animation playback method based on the data table information specified by the channel to be processed (during reference), that is, the input is performed. It is determined whether the lamp request is a request for immediately executing the lamp lighting operation (S773). Although not shown here, the processing from S733 to S775 to be described later is repeatedly executed by the number of channels.

  In S773, if the audio / LED control circuit 220 determines that “NEXT” is not specified as the LED animation playback method of the channel being referred to (if S773 is YES), the audio / LED control circuit 220 Then, various information (data table information and LED data) currently stored in the channel registration buffer is overwritten and updated with the corresponding various information acquired at the time of receiving the current lamp request (S774).

  On the other hand, in S773, when the audio / LED control circuit 220 determines that “NEXT” is specified as the LED animation playback method of the channel being referred to (in the case of NO determination in S773), the audio / LED control circuit 220 220 additionally stores (additionally updates), after various information (data table information and LED data) currently stored in the channel registration buffer, the corresponding various information acquired at the time of receiving the current lamp request (additional update). S775).

  When the extended channel is used, in the processing of S774 or S775, the audio / LED control circuit 220 stores various information (data table information and An overwrite update process or an additional update process of (LED data) is performed. On the other hand, when the extension channel is not used, in the processing of S774 or S775, the audio / LED control circuit 220 stores various information (data table information and LED data) in the registration buffer of the reproduction channel of the channel being referred to. Perform overwrite update processing or additional update processing.

  After the processing of S774 or the processing of S775, the audio / LED control circuit 220 performs data setting processing of each port (S776). By this processing, the combined LED data (output data) is set for each port to be controlled. The details of the data setting process for each port will be described later with reference to FIG. 114 described later. Then, after the processing of S776, the audio / LED control circuit 220 ends the above-described series of processing at the time of the lamp control processing, and returns the processing to a predetermined control state of the audio / LED control circuit 220 (for example, a standby state, a lamp control state). The processing returns to the control state before the processing, the control state of the processing executed after the lamp control processing, etc.).

(3) Data setting processing of each port Next, referring to FIG. 114, data of each port performed in S776 in the processing of the audio / LED control circuit (see FIG. 113B) executed during the lamp control processing of this example The setting process will be described. FIG. 114 is a flowchart showing a procedure of data setting processing of each port executed by the audio / LED control circuit 220 in the lamp control processing of this example.

  First, the audio / LED control circuit 220 performs reference processing of the registration buffer of each channel (S781).

  Next, the audio / LED control circuit 220 uses two sequencers on the predetermined channel based on the data table information stored in the registration buffer of the predetermined channel to be processed (during reference) (playback channel and extension It is determined whether or not to use a channel) (S782). Although not shown here, a series of processing from S782 to S784 described later is repeatedly executed by the number of channels.

  In S782, when the audio / LED control circuit 220 determines that two sequencers are used in a predetermined channel (when S782 is determined as YES), the audio / LED control circuit 220 sets the registration buffers for the reproduction channel and the extension channel. The SPI channel (physical system) used by each control unit controlled by each sequencer is specified based on the data table information stored in the storage unit (S783). On the other hand, in S782, when the audio / LED control circuit 220 determines that the two sequencers are not used in the predetermined channel (NO in S782), the audio / LED control circuit 220 stores the reproduction channel in the registration buffer of the reproduction channel. Based on the stored data table information, an SPI channel (physical system) used by a control unit controlled by the playback channel sequencer is specified (S784).

  Next, the audio / LED control circuit 220 determines whether or not the port to be processed (under reference) is a port to be controlled (within the reproduction channel) in the predetermined channel (S785). Note that the determination processing in S785 is executed based on the data table information stored in the reproduction channel registration buffer, and a series of processing in S785 to S791 described later is repeatedly executed by the number of ports.

  In S785, when the audio / LED control circuit 220 determines that the port being referred to is not a control target port (NO in S785), the audio / LED control circuit 220 performs the process of S789 described later. On the other hand, in S785, when the audio / LED control circuit 220 determines that the port being referred to is the port to be controlled (YES in S785), the audio / LED control circuit 220 determines based on the data table information. Then, it is determined whether or not “ODONLY” is specified as the reproduction method in the reproduction channel (control part) to be processed (being referred to) (S786).

  In S786, if the audio / LED control circuit 220 determines that “ODONLY” is specified as the reproduction method in the reproduction channel being referred to (if S786 is YES), the audio / LED control circuit 220 The port information (LED data) is overwritten based on the execution priority of the channel and the presence or absence of output data (S787). In this process, the same process as S750 in the ramp control process of the second modification (FIGS. 112A and 112B) is performed.

  On the other hand, in S786, if the audio / LED control circuit 220 determines that “ODONLY” is not specified as the reproduction method in the reproduction channel being referred to (if S786 is NO), the audio / LED control circuit 220 Performs overwrite processing of port information (LED data) based on the execution priority set for the channel (S788). In this process, the same process as S751 in the ramp control process of the second modification (FIGS. 112A and 112B) is performed.

  After the process of S787 or S788, or when the determination of S785 is NO, the audio / LED control circuit 220 determines that the processes of S785 to S788 are performed for all the reproduction channels (for eight channels) of the port being referred to. It is determined whether or not the execution has been performed (S789).

  In step S789, when the audio / LED control circuit 220 determines that the processing in steps S785 to S788 has not been executed for all the reproduction channels (when S789 is NO), the audio / LED control circuit 220 performs the processing Is returned to S785, the reproduction channel to be processed is changed, and the processing after S785 is repeated.

  On the other hand, in S789, when the audio / LED control circuit 220 determines that the processing of S785 to S788 has been executed for all the reproduction channels (when S789 is YES), the audio / LED control circuit 220 refers to It is determined whether or not the port direct designation data for the middle port is included in the lamp request, and if the port direct designation data is included in the lamp request, the audio / LED control circuit 220 Is overwritten with the port direct designation data (S790).

  Next, the audio / LED control circuit 220 determines whether or not the above-described processing of S785 to S790 has been executed for all ports (S791).

  In step S791, if the sound / LED control circuit 220 determines that the processing in steps S785 to S790 has not been performed for all ports (if S791 is NO), the sound / LED control circuit 220 performs the processing. Returning to step S785, the port to be processed is changed, and the processing from step S785 is repeated. On the other hand, in S791, if the audio / LED control circuit 220 determines that the processing of S785 to S790 has been performed for all ports (if S791 is YES), the audio / LED control circuit 220 will be described later. The processing of S792 is performed.

  In this example, when an extended channel is also used, the same processing as the above-described processing of S785 to S791 performed on the reproduction channel is similarly performed on the extended channel. At this time, the processes of S785 to S791 for the reproduction channel and the processes of S785 to S791 for the extension channel are simultaneously performed in parallel. At this time, the processing of S785 to S791 for the reproduction channel is actually executed by the sequencer set to the reproduction channel, and the processing of S785 to S791 for the expansion channel is performed by the sequencer set to the expansion channel. Be executed.

  If the determination in S791 is YES, is the audio / LED control circuit 220 executing the series of processes in S785 to S791 on two channels (a reproduction channel sequencer and an extension channel sequencer) in a predetermined channel? It is determined whether or not it is (S792). Although not shown here, a series of processing from S792 to S794 to be described later is repeatedly executed for the number of channels.

  In S792, if it is determined that the audio / LED control circuit 220 has performed the series of processes of S785 to S791 using two sequencers (YES in S792), each of the audio / LED control circuits 220 The sequencer sets (reserves) clear data (light-out data) in the corresponding control part (S793). On the other hand, in S782, if the audio / LED control circuit 220 determines that the series of processes of S785 to S791 has not been executed using two sequencers (if S792 is NO), the audio / LED control circuit 220 220 executes the reproduction channel clear function (S794). By this processing, clear data (light-out data) is set (reserved) in the control portion of the reproduction channel.

  After the above-described series of processing of S792 to S794 has been executed for all channels, the audio / LED control circuit 220 ends the data setting processing of each port.

[Modification 4]
In the above embodiment, between the audio / LED control circuit 220 (master) and each LED driver 280 (slave) connected by the SPI bus, the audio / LED control circuit 220 unilaterally sends the LED data and the LED driver 280 to each LED driver 280. Although the configuration has been described in which serial data including device address data is transmitted and the transmission LED driver 280 is specified by the device address data included in the serial data, the present invention is not limited to this.

  For example, when transmitting / receiving serial data between the audio / LED control circuit 220 and the LED driver, a configuration may be adopted in which the LED driver to be transmitted / received is specified by the slave select signal. In the fourth modification, a configuration example will be described in which an LED driver to which serial data (such as LED data) is to be transmitted is specified using a slave select signal (SS signal).

  Hereinafter, the connection configuration between the voice / LED control circuit and the LED driver in this example, the communication principle, and the procedure of the communication process will be described. In the pachinko game machine of this example, the connection between the voice / LED control circuit and the LED driver is described. Configurations other than the communication mode described above can be configured in the same manner as the above embodiment. Therefore, only the communication mode (configuration and communication control method) between the audio / LED control circuit and the LED driver will be described here.

[Connection configuration between audio / LED control circuit and LED driver]
First, the connection configuration between the audio / LED control circuit 290 and the LED driver 291 of the fourth modification will be described with reference to FIG. FIG. 115 is a diagram showing a connection configuration between the audio / LED control circuit 290 and the LED driver 291 in this example.

  Also in this example, since the audio / LED control circuit 290 and the LED driver 291 are connected by the SPI bus, in each physical system (SPI channel), the signal wiring of the serial clock (SCL) and the serial data ( SDO, SDI) signal wiring is provided separately. Then, in each physical system (SPI channel) of the audio / LED control circuit 290 (master), each output terminal (SCL1, SCL2) of the serial / clock signal of the audio / LED control circuit 290 is connected to a corresponding plurality of LED drivers 291. It is connected in parallel to the (slave) serial clock signal input terminal (SCL). The serial data output terminals (SDO1 and SDO2) of the audio / LED control circuit 290 are connected in parallel to the serial data input terminal (SDI) of the corresponding LED driver 291. Further, the input terminals (SDI1 and SDI2) of the serial data of the audio / LED control circuit 290 are connected in parallel to the output terminals (SDO) of the serial data of the plurality of LED drivers 291.

  Further, in this example, as shown in FIG. 115, a plurality of slave select terminals (SS1, SS2, SS3) are provided in the audio / LED control circuit 290 (master), and each LED driver 291 (slave) is provided. Also, a slave select terminal (SS) is provided. Note that the slave select terminal (SS) provided in each LED driver 291 is additionally provided, for example, in the terminal group 280d of the LED driver 280 of the above embodiment described with reference to FIG. Then, each slave select terminal of the audio / LED control circuit 290 is connected to the corresponding slave select terminal (SS) of the LED driver 291.

[Communication principle]
Next, the principle of serial data communication between the audio / LED control circuit 290 (master) and the LED driver 291 (slave) will be described with reference to FIG. FIG. 116 is a diagram showing a state of a serial data communication operation between the audio / LED control circuit 290 (master) and the LED driver 291 (slave).

  As shown in FIG. 116, the audio / LED control circuit 290 includes a buffer (first storage unit), a shift register (first input / output unit), and a shift clock generation unit. (Second storage means) and a shift register (second input / output means). Note that the shift register in the audio / LED control circuit 290 is constituted by an 8-bit shift register. The shift register in the LED driver 291 is also formed of an 8-bit shift register.

  In the serial data communication operation between the audio / LED control circuit 290 (master) and the LED driver 291 (slave), the operation of the shift register in the audio / LED control circuit 290 is input from the shift clock generator. Controlled based on the serial clock signal. The operation of the shift register in the LED driver 291 is also controlled based on the serial clock signal output from the shift clock generator in the audio / LED control circuit 290. The serial clock signal output from the shift clock generator in the audio / LED control circuit 290 is connected to the serial clock signal wiring (SCL terminals (SCL1, SCL2) of the audio / LED control circuit 290 and the LED driver 291). Are connected to the LED driver 291 via a connection wiring between the SCL terminals. In this example, data communication is performed in units of 8 bits.

  When the communication operation of serial data from the audio / LED control circuit 290 (master) to the LED driver 291 (slave) starts, a buffer in the audio / LED control circuit 290 (master) is used to start the communication in the audio / LED control circuit 290. The transmission data (8 bits) is transmitted to the shift register, and the data (M0 to M7) of each bit constituting the transmission data is stored in the corresponding register in the shift register. Further, transmission data (8 bits) is transmitted from a buffer in the LED driver 291 (slave) to a shift register in the LED driver 291, and data (S 0 to S 7) of each bit constituting the transmission data is stored in the shift register. Is stored in the corresponding register.

  Next, the 1-bit data M7 stored in the first register of the shift register in the audio / LED control circuit 290 is transmitted to the serial data communication wiring (the SDO terminal (SDO1 or SDO2) of the audio / LED control circuit 290 and the LED). The signal is transmitted to the LED driver 291 via the connection wiring between the SDI terminals of the driver 291). At this time, the data (M0 to M6) stored in the shift register of the audio / LED control circuit 290 is shifted and stored in the first register.

  Further, at the same time as the transmission processing of the data M7 by the audio / LED control circuit 290, the 1-bit data S7 stored in the first register of the shift register in the LED driver 291 is used for serial data communication wiring (audio / LED control). The signal is transmitted to the audio / LED control circuit 290 via the SDI terminal (SDI1 or SDI2) of the circuit 290 and the connection wiring between the SDO terminal of the LED driver 291. At this time, the data (S0 to S6) stored in the shift register of the LED driver 291 is shifted and stored in the first register.

  Next, the data M7 transmitted from the audio / LED control circuit 290 to the LED driver 291 is stored in the last register in the shift register of the LED driver 291. At this time, the data S7 transmitted from the LED driver 291 to the audio / LED control circuit 290 is stored in the last register in the shift register of the audio / LED control circuit 290.

  FIG. 117 shows the data storage state of the shift register in the audio / LED control circuit 290 and the data storage state of the shift register in the LED driver 291 when the above-described one-bit data communication is completed. As shown in FIG. 117, in the data communication of this example, data is sequentially switched from the last register of each shift register.

  When the one-bit data communication described above is repeated eight times, the data in the shift register of the audio / LED control circuit 290 and the data in the shift register of the LED driver 291 are interchanged, and the 8-bit data is exchanged. Communication ends. When the 8-bit data communication is completed, the 8-bit received data (S0 to S7) stored in the shift register of the audio / LED control circuit 290 is transmitted to and stored in a buffer in the audio / LED control circuit 290. Is done. The 8-bit received data (M0 to M7) stored in the shift register of the LED driver 291 is transmitted to and stored in a buffer in the LED driver 291.

[Communication processing between audio / LED control circuit and LED driver]
Next, with reference to FIGS. 118A and 118B, a communication process of this example performed between the audio / LED control circuit 290 and the LED driver 291 will be described. FIG. 118A is a flowchart showing a procedure of signal and data transmission / reception processing of this example executed by the audio / LED control circuit 290. FIG. 118B is a flowchart illustrating a procedure of a signal and data transmission / reception process executed by the LED driver 291 in the communication process between the audio / LED control circuit 290 and the LED driver 291 in this example.

(1) Serial data input / output processing of the audio / LED control circuit First, the audio / LED control circuit 290 transmits a slave selector signal (SS signal) to all the LED drivers 291 as shown in FIG. 118A. (S801). At this time, only the LED driver 291 corresponding to the device address designated by the slave select signal (address designation signal) receives the slave select signal.

  Next, the audio / LED control circuit 290 performs serial data transmission / reception processing with the LED driver 291 at the device address specified by the slave select signal (S802). At this time, the audio / LED control circuit 290 transmits and receives serial data in 8-bit units according to the communication principle described with reference to FIGS. Next, the audio / LED control circuit 290 completes the transmission / reception processing of the serial data (S803).

  Next, the audio / LED control circuit 290 stops transmitting the slave select signal (S804). Then, after the processing of S804, the audio / LED control circuit 290 ends the serial data input / output processing.

(2) Serial Data Input / Output Process of LED Driver First, as shown in FIG. 118B, the LED driver 291 determines whether or not a slave select signal has been received (S811). In this process, if the LED driver 291 is the LED driver 291 corresponding to the device address specified by the slave select signal, the result of the determination process in S811 is YES.

  In S811, if the LED driver 291 determines that the slave select signal has not been received (NO in S811), the LED driver 291 performs the process of S814 described later. On the other hand, in S811, when the LED driver 291 determines that the slave select signal has been received (YES in S811), the LED driver 291 shifts the operation state from the standby state to the activation state (S812).

  After the processing in S812, the LED driver 291 performs transmission / reception processing of serial data with the audio / LED control circuit 290 (S813). At this time, the LED driver 291 transmits and receives serial data in 8-bit units according to the communication principle described with reference to FIGS. 116 and 117. Then, the LED driver 291 completes the transmission / reception processing of the serial data.

  After the processing in S813 or when the determination in S811 is NO, the LED driver 291 shifts the operation state to the standby state or maintains the standby state (S814). Then, after the processing of S814, the LED driver 291 ends the serial data input / output processing.

  In this example, as described above, only the specific LED driver 291 can be designated by the slave select signal transmitted from the audio / LED control circuit 290, and data can be transmitted to the LED driver 291. In this case, the number of signal wirings between the audio / LED control circuit 290 and the LED driver 291 is increased as compared with the above embodiment, but the processing load on the LED driver 291 can be reduced, and the audio / LED control circuit 290 The balance between the processing load and the processing load of the LED driver 291 can be adjusted.

[Modification 5]
In the above embodiment, a configuration in which one LED 281 is connected to each port, that is, an example in which the LED 281 is a static LED (an example of static output control) has been described, but the present invention is not limited to this. A configuration in which a plurality of LEDs are connected to each port, that is, an LED in which the LEDs are dynamically controlled (hereinafter, referred to as a dynamic LED) may be used.

  In Modification Example 5, a configuration example in which the LED is a dynamic LED (configuration example of dynamic output control) will be described with reference to FIG. 119. FIG. 119 is an example showing an example of dynamic output control of LED data. The example illustrated in FIG. 119 illustrates an example in which three LEDs (red LED, blue LED, and green LED) are connected to one port 1. In this example, the reproduction time (lighting time) in the LED data is set to “12” (about 48 msec), and the red component luminance data, the green component luminance data, and the blue component luminance data are each set to “0xFE”. Will be described. That is, in this example, the data type (format) of the LED data is the same as that of the above embodiment (see FIG. 52).

  When the LED data of the data type is input to the LED driver, the LED driver refers to the information of the control part (including the type information of the LED) and corresponds to the type of the connected LED from the LED data. A drive signal corresponding to the luminance data is output to the LED via the port 1. Therefore, only the red luminance data “0xFE” in the LED data is output to the red LED, and the red LED is turned on for about 48 msec at a luminance corresponding to the red luminance data “0xFE”. Further, only the blue luminance data “0xFE” in the LED data is output to the blue LED, and the blue LED is turned on for about 48 msec at a luminance corresponding to the blue luminance data “0xFE”. Further, only the green luminance data “0xFE” in the LED data is output to the green LED, and the green LED is turned on for about 48 msec at a luminance corresponding to the green luminance data “0xFE”. In this case, white lighting is performed by three LEDs of a red LED, a blue LED, and a green LED. In this example, since the LEDs are dynamically controlled, when the lighting period is 48 msec, the LED driver responds to the luminance data “0xFE” while switching the red LED, the green LED, and the blue LED in this order at 2 msec intervals. The driving signal is output to each LED, and this series of switching operation of the driving signal is repeated eight times.

  As described above, in this example, since the data type of the LED data is the same as that of the above-described embodiment, all the static LEDs included in the pachinko gaming machine 1 of the above-described embodiment may be replaced with dynamic LEDs. Some of the static LEDs may be replaced with dynamic LEDs.

  In this example, as described above, the data type (format) of the LED data output to the dynamic LED can be the same as that of the static LED in the above embodiment. In this case, even when a plurality of LEDs having different LED output control methods are used at the same time, LED data of the same data type can be transmitted. Therefore, for each type of output control performed by the LED driver, There is no need to prepare LED data of different data types. In this case, the LED data creation process and the LED data output process can be shared regardless of the type of LED output control. Therefore, even if a plurality of types of LEDs having different LED data output control methods are used in combination, it is easy to combine (overwrite, update, and the like) the LED data used in the reproduction channel, and to easily perform complicated LED output control. Can be performed.

  Further, in this example and the above-described embodiment, the data type of the LED data is the same regardless of the type of the output control of the LED. The composition processing becomes easy, and more complicated LED control can be performed. That is, in this example, the number of options for effect control using LEDs can be increased, and more advanced effect control can be realized.

[Modification 6]
In the sixth modification, an example of the configuration of a pachinko gaming machine further provided with a function of detecting an excitation state (such as an excitation continuation time) of a motor 272 for driving the accessory 20 and performing error detection based on the detection result is provided. Will be described. In addition, in the sixth modification, the configuration other than the excitation state detection function of the motor 272 can be configured in the same manner as the above embodiment. Therefore, here, only the configuration and processing for realizing the function of detecting the excitation state of the motor 272 will be described.

(1) Configuration Example of Excited State Detection of Motor First, a configuration example of a function of detecting the excited state of the motor 272 will be described with reference to FIG. FIG. 120 is a schematic configuration diagram of a detection function unit of the excitation state of the motor 272 in the sixth modification. In this example, an example in which four motors 272 are connected to the motor driver 271 will be described.

  As shown in FIG. 120, an excitation state detection function unit 275 of the motor 272 (hereinafter, referred to as an excitation state detection unit 275) in this example includes three OR circuits (a first OR circuit 276, a second OR circuit 277, and a third OR circuit). 278).

  One input terminal of the first OR circuit 276 in the excitation state detection unit 275 is connected to the output terminal OUT0 of the four output terminals of the motor driver 271. The other input terminal of the first OR circuit 276 is connected to the motor driver 271. Is connected to the output terminal OUT1. Further, one input terminal of the second OR circuit 277 is connected to the output terminal OUT3 of the motor driver 271 and the other input terminal of the second OR circuit 277 is connected to the output terminal OUT4 of the motor driver 271.

  One input terminal of the third OR circuit 278 in the excitation state detection unit 275 is connected to the output terminal of the first OR circuit 276, and the other input terminal of the third OR circuit 278 is connected to the output terminal of the second OR circuit 277. You. The output terminal of the third OR circuit 278 is connected to a predetermined input terminal P provided for the motor driver 271 for detecting the excitation state.

  In a pachinko game machine equipped with an excitation state detection unit 275 (excitation detection means) having the configuration shown in FIG. 120, when excitation data is output from motor driver 271 to at least one of four motors 272, excitation state detection unit 275 The data “1” is output from the third OR circuit 278 to the motor driver 271 as an excitation detection signal (determination result signal). On the other hand, when the excitation data is not output to any of the four motors 272 from the motor driver 271, data “0” is output as the excitation detection signal from the third OR circuit 278 in the excitation state detection unit 275. 271 is output.

  In this example, the host control circuit 210 determines whether at least one of the four motors 272 is in an excitation state based on the excitation detection signal (“1” or “0”) input to the motor driver 271. I do. Then, the host control circuit 210 counts a time during which the motor 272 is continuously excited (a time during which the excitation detection signal “1” is continuously detected), and the continuous excitation time becomes longer than a predetermined value. For example, the driving of all the motors 272 is stopped. Here, “all the motors 272” means all the motors 272 connected to the motor driver 271; however, the present invention is not limited to this, and all the motors that drive the accessory 20 are used. Or a plurality of motors 272 connected to a plurality of motor drivers 271.

  The configuration of the excitation state detection unit 275 is not limited to the example illustrated in FIG. 120, and may be any configuration as long as it can determine whether at least one of the plurality of motors 272 is in the excitation state. can do. For example, the number of OR circuits included in the excitation state detection unit 275 and the connection between the OR circuits can be appropriately changed according to, for example, the number of motors 272 connected to the motor driver 271. Further, for example, a configuration may be employed in which the excitation state of some of the motors 272 having a high operating rate among the plurality of motors 272 is determined. In this case, the excitation state detection unit 275 is connected to only the output terminal corresponding to a part of the motor 272 having a high operating rate to be monitored, among the plurality of excitation data output terminals provided in the motor driver 271. Is done. In the configuration in which the excitation state of some of the motors 272 to be monitored among the plurality of motors 272 is determined, some of the motors 272 are arbitrarily selected regardless of the operation rate, and The excitation state of the motor 272 may be monitored.

(2) Accessory Control Process Next, with reference to FIG. 121, the accessory control process of this example executed by the host control circuit 210 will be described in more detail. FIG. 121 is a flowchart showing the procedure of the accessory control process of this example.

  First, the host control circuit 210 determines whether or not the reset process of the I2C controller 261 is being performed (S821).

  In S821, when the host control circuit 210 determines that the reset processing of the I2C controller 261 is being performed (when S821 is YES), the host control circuit 210 ends the accessory control processing. On the other hand, in S821, when the host control circuit 210 determines that the reset process of the I2C controller 261 is not being performed (NO in S821), the host control circuit 210 determines whether all the motors 272 are at the initial position. Is determined (S822).

  In S822, when the host control circuit 210 determines that all the motors 272 are at the initial position (in the case of YES determination in S822), the host control circuit 210 determines each motor driver 271 (motor 272), and outputs excitation data (S823). Thus, an effect operation using the accessory 20 (a driving operation of the motor 272) is started. Next, the host control circuit 210 determines whether or not an error has occurred during the effect operation (the driving operation of the motor 272) using the accessory 20 (S824).

  In S824, if the host control circuit 210 determines that an error has occurred (if S824 is YES), the host control circuit 210 performs the processing of S830 described below. On the other hand, in S824, if the host control circuit 210 determines that no error has occurred (NO in S824), the host control circuit 210 determines the duration of the excitation state of the motor 272 (continuous excitation time). The measurement is performed (S825). In this process, the host control circuit 210 measures the continuous excitation time of the motor 272 based on the excitation detection signal input from the third OR circuit 278 in the excitation state detection unit 275 to the motor driver 271.

  After the processing in S825, the host control circuit 210 determines whether or not the duration of the excitation state of the motor 272 (continuous excitation time) is equal to or longer than a predetermined time (S826).

  In S826, when the host control circuit 210 determines that the continuous excitation time of the motor 272 is equal to or longer than the predetermined time (YES in S826), the host control circuit 210 performs the process of S830 described later. On the other hand, if the host control circuit 210 determines in S826 that the continuous excitation time of the motor 272 is not longer than the predetermined time (NO in S826), the host control circuit 210 determines whether the motor 272 is being excited. Is determined (S827).

  If the host control circuit 210 determines in step S827 that the motor 272 is being excited (YES in step S827), the host control circuit 210 returns to step S824, and performs the processing in step S824 and subsequent steps. On the other hand, in S827, when the host control circuit 210 determines that the motor 272 is not being excited (NO in S827), the host control circuit 210 ends the accessory control process.

  Here, returning to the process of S822 again, in S822, when the host control circuit 210 determines that one or more motors 272 are not at the initial position (when S822 is NO), the host control circuit 210 Then, excitation data for moving (returning) the accessory 20 to the initial position is output to the motor 272 (S828). Next, the host control circuit 210 determines whether an error has occurred in the operation of moving the accessory 20 to the initial position (the driving operation of the motor 272) (S829).

  In S829, when the host control circuit 210 determines that an error has occurred (YES in S829), the host control circuit 210 performs the process of S830 described later. On the other hand, in S829, when the host control circuit 210 determines that no error has occurred (NO in S829), the host control circuit 210 ends the accessory control processing.

  If the determination in S824, S826 or S829 is YES, the host control circuit 210 stops the driving operation of all the motors 272 (S830). Specifically, the host control circuit 210 releases the excitation of all the motors 272. Then, after the processing of S830, the host control circuit 210 ends the accessory control processing.

  In the process of S830, the host control circuit 210 further controls the display device 13 to display information indicating that a drive error of the accessory 20 has occurred on the display screen. However, this error display is not released until the power is turned off.

  As described above, in this example, when the continuous excitation time of the motor 272 exceeds a predetermined time, the driving operation of all the motors 272 is stopped. The threshold value of the continuous excitation time of the motor 272 for determining whether or not to execute the process of stopping the driving operation of the motor 272 (the process of protecting the motor 272) is arbitrarily set according to the effect contents of the accessory 20 for example. Can be set. The detection process of the excitation state (continuous excitation time) of the motor 272 and the protection process of the motor 272 based on the detection result are performed as additional processes of the accessory control process (see FIG. 102) performed in the above embodiment. The processing after S499 in the accessory control processing of the above embodiment (see FIG. 102) may be replaced with the processing of the flowchart shown in FIG.

  The excitation data output from the host control circuit 210 to the motor 272 (motor driver 271) based on the accessory request may include excitation data corresponding to one predetermined operation of the accessory 20 in some cases. And a plurality of excitation data respectively corresponding to a plurality of predetermined operations.

  In the latter case, a plurality of excitation data is output from the host control circuit 210 to the motor 272 (motor driver 271) in a predetermined order based on the accessory request. In this case, in the accessory control processing of this example, the processing of S824 to S827 in FIG. 121 is repeated for each excitation data (for each operation of the accessory). Therefore, for example, in the excitation data output operation corresponding to the predetermined operation in the middle of a series of driving operations of the accessory 20, the continuous excitation time of the motor 272 becomes equal to or longer than the predetermined time (YES in S826). ), The driving operation of the motor 272 is stopped at that time, and thereafter, the output processing of the excitation data for each operation scheduled to be output is also stopped.

(3) Various effects obtained by the configuration of this example As described above, in this example, the output state of the excitation data (voltage signal) output from the motor driver 271 to at least one motor 272 (the excitation state of the motor 272). Is detected by the excitation state detection unit 275, and the continuous excitation time of the motor 272 (the continuous drive time of the accessory 20) is measured based on the detection result. Then, based on the measured continuous excitation time of the motor 272 (continuous drive time of the accessory 20), it is determined whether or not all the motors 272 are stopped (excitation is released).

  By providing the function of detecting the excitation state of the motor 272, it is possible to detect, for example, a case where excessive excitation data is output to the motor 272 or a case where unintended motor excitation is performed. Can be. As a result, the operation of the accessory 20 can be guaranteed, and the failure of the motor 272 can be suppressed.

  Further, when the excitation state of the motor 272 is detected (managed) for each operation of the accessory 20, the drive of the motor 272 can be stopped at a time when the effect operation can be separated. The stop processing of the motor 272 can be performed.

  Further, in this example, when an abnormality is detected in the excitation state of the motor 272, the error display is continued on the display screen of the display device 13 until the power is turned off. Therefore, in this case, it is possible to prompt the user to turn off the power supply and to forcibly release the excitation of the motor 272.

[Modification 7]
In the pachinko gaming machine 1 of the above embodiment, as shown in FIG. 8, the fourth connection terminal in the connection terminal group 264 provided on the built-in relay board 260 is replaced with a ground (GND) terminal provided in the built-in relay board 260. Although an example in which the connection is made has been described, the present invention is not limited to this.

  For example, the third or fourth connection terminal in the terminal group 11b provided in the speaker box 11a may be connected to a ground terminal (not shown) provided in the speaker box 11a.

  Further, for example, the fourth connection terminal in the connection terminal group 264 provided on the built-in relay board 260 may be connected to a power supply voltage terminal provided in the built-in relay board 260. In this case, in the configuration of the built-in relay board 260 shown in FIG. 8, a NOT circuit is further provided between the mute terminal (MUTE) of the digital audio power amplifier 262 and the NOT circuit 268, or the NOT circuit 268 Is omitted.

  In the above embodiment, an example has been described in which the mute function is activated when the level (amplitude value) of the signal input to the mute terminal (MUTE) of the digital audio power amplifier 262 is LOW. It is not limited to this. The mute function may be activated when the level (amplitude value) of the signal input to the mute terminal (MUTE) of the digital audio power amplifier 262 is at the HIGH level. In this case, a NOT circuit is further provided between the mute terminal (MUTE) of the digital audio power amplifier 262 and the NOT circuit 268 in the configuration of the built-in relay board 260 shown in FIG. Is done.

  Furthermore, in the above-described embodiment, an example has been described in which the built-in relay board 260 and the speaker box 11a are connected using the harness 300 in which a plurality of signal wires are bundled into one, but the present invention is not limited to this. Alternatively, the internal relay board 260 and the speaker box 11a may be connected using a plurality of separate signal wirings.

[Modification 8]
The connection configuration between the sub-board 202 and the CGROM board is not limited to the example described in the above embodiment. For example, a configuration may be adopted in which the level of a signal input to one control terminal DIR of the bidirectional balance transceiver 301 in the sub-board 202 can be grasped by the display control circuit 230. In Modification 8, one configuration example will be described.

  FIG. 122 is a connection configuration diagram between the sub-board 202a and the CGROM board 204a according to the eighth modification when the NOR-type CGROM 206a is mounted on the CGROM board 204a. In the configuration of the sub-substrate 202a of this example shown in FIG. 122, the same components as those of the sub-substrate 202 of the above-described embodiment shown in FIG.

  In the example shown in FIG. 122, an example is shown in which the CGROM board 204a on which the NOR-type CGROM 206a is mounted is connected (mounted) to the sub-board 202a. However, the present invention is not limited to this. The CGROM board 204b on which the NAND-type CGROM 206b shown in (1) is mounted may be connected (mounted) to the sub-board 202a of this example.

  As is clear from the comparison between the configuration shown in FIG. 122 and the configuration of FIG. 12 described in the above embodiment, the configuration of the CGROM board 204a on which the NOR type CGROM 206a is mounted is the same. The description of the configuration is omitted.

  In the sub-board 202a of this example, as shown in FIG. 122, the fifth connection terminal (predetermined connection terminal) in the terminal group 303 of the sub-board 202a is connected to one control terminal DIR of the bidirectional balance transceiver 301. Not only that, but it is also connected to the communication selection bus input terminal (predetermined input terminal) of the display control circuit 230a via the signal wiring W4. Thus, the level of the signal input to one control terminal DIR of the bidirectional balanced transceiver 301 can be managed by the display control circuit 230a. The configuration of the sub-substrate 202a other than this connection configuration is the same as the corresponding configuration of the sub-substrate 202 illustrated in FIG. 12 described in the above embodiment, and the description of these configurations will be omitted here.

  As described in the above embodiment, when the type of the CGROM is the NOR type, the level of the signal input to the control terminal DIR (the fifth connection terminal) of the bidirectional balance transceiver 301 becomes LOW, and When the type is the NAND type, the level of the signal input to the control terminal DIR (fifth connection terminal) of the bidirectional balance transceiver 301 becomes HIGH. Therefore, as in this example, in a configuration in which the level of the signal input to one control terminal DIR of the bidirectional balance transceiver 301 can be managed by the display control circuit 230a, the level of the signal input to the control terminal DIR is changed. Thus, it is possible to determine whether the type of the connected CGROM is the NOR type or the NAND type.

  In this case, the display control circuit 230a communicates with a NOR-type CGROM as a communication mode based on the level (amplitude value) of the signal input to the communication selection bus input terminal in the initial setting processing of the display control circuit 230a at startup. One of the communication mode and the communication mode with the NAND type CGROM can be selected and set. That is, also in the pachinko gaming machine of this example, the CGROM can be selected according to the embodiment, and the expandability of the pachinko gaming machine can be secured.

  In this configuration, as in this example, in which the signal level of the fifth connection terminal of the sub-board 202a is monitored and the communication mode for the connected CGROM can be selected based on the signal level, the bidirectional balance transceiver 301 is omitted. May be. In this case, the first input / output terminal GMA31 / GRB3 to the fourth input / output terminal GMA28 / GRB0 of the display control circuit 230a are connected to the input terminal and the output terminal based on the signal level of the fifth connection terminal of the sub-board 202a. The display control circuit 230a performs selection control of which of the terminals is to be operated. That is, in this case, the display control circuit 230a also includes a communication mode setting unit that sets the communication mode between the display control circuit 230a and the CGROM based on the level of the signal applied to the fifth connection terminal of the sub-board 202. Doubles.

[Modification 9]
In the LED animation generation function of the pachinko gaming machine 1 of the above-described embodiment, in each channel of the LED 281, the light-off data and the LED data of “transparency definition” (each luminance data of red, green, and blue components is “0xFF”). LED data: hereinafter, referred to as “transparency definition data”). Modification Example 9 describes an example in which an LED animation is generated using transparency definition data.

(1) Generation example 1
FIG. 123A and FIG. 123B show an outline of an LED animation generation example 1 using the transparent definition data. Note that, in the example shown in FIGS. 123A and 123B, similarly to the generation example 2 (see FIGS. 54A and 54B) of the above embodiment, the generation and output operation of the LED animation when the range of the control part is different between the channels. The outline of is shown.

  In the example shown in FIGS. 123A and 123B, an example in which a predetermined LED animation is executed using eight LEDs 281 (first LED to eighth LED) will be described. The following describes an example in which LED data is set in the. Further, in the example shown in FIGS. 123A and 123B, the control part of the eighth channel is set to the first LED to the third LED, the control part of the seventh channel is set to the first LED to the fifth LED, and the control part of the sixth channel is set. An example in which the control part is set to all the LEDs 281 will be described. Note that, also in this example, the execution priority between channels increases as the channel number increases, as in the above embodiment. That is, the eighth channel is at the top and the first channel is at the bottom.

  In the first generation example, in the eighth channel, the LED data of “red” lighting is set to the first LED and the third LED, and the transparent definition data is set to the second LED. In the seventh channel, LED data of “green” lighting is set to the first LED and the third to fifth LEDs, and the transparent definition data is set to the second LED. In the sixth channel, the LED data of “blue” lighting is set to all the LEDs 281. In the eighth and seventh channels, no LED data is set to the port of the LED 281 that is not designated as the control part.

  In the example illustrated in FIG. 123A, when the LED data of the sixth to eighth channels are combined, the LED data of the sixth to eighth channels overlap in the first LED and the third LED, but the first LED and the third LED have the highest execution priority. Eight-channel LED data is set as a synthesis result. In the fourth LED and the fifth LED, the LED data of the seventh channel and the sixth channel overlap, but the LED data of the seventh channel having a higher execution priority is set as a synthesis result. In the sixth to eighth LEDs, since LED data is set only in the sixth channel, the LED data of the sixth channel is set as a synthesis result.

  Then, in the example shown in FIG. 123A, since the transparent definition data is set for the second LED of the eighth and seventh channels, the LED data set for the second LED of the sixth channel (the LED lit in “blue”) Data) is set to the second LED as a result of synthesizing the LED data. That is, when the transparent definition data is set in the channel with the higher execution priority, the LED data set in the channel with the lower execution priority is output as the synthesis result.

  Therefore, in the generation example 1 of this example, the lighting pattern of the first LED and the third LED in the combined LED animation is the same as the lighting pattern of the first LED and the third LED of the eighth channel, as shown in FIG. 123B. The lighting pattern of the fourth LED and the fifth LED is the same as the lighting pattern of the fourth LED and the fifth LED of the seventh channel, and the lighting pattern of the sixth LED to the eighth LED is the lighting of the sixth LED to the eighth LED of the sixth channel. It becomes the same as the pattern. The lighting pattern of the second LED is the same as the lighting pattern of the second LED of the sixth channel.

  When the execution priority is provided between the channels, for example, as described in the above-described embodiment (see FIGS. 54A and 54B), when the erase data is set in some LEDs of the higher channels such as the seventh and eighth channels, The lighting state of some LEDs of the lower channel is not reflected in the synthesis result. Therefore, in this case, substantially the same state as in the case where some LEDs of the lower channel as well as some LEDs of the lower channel are turned off. On the other hand, when the transparent definition data is set to some of the LEDs of the upper channel as in this example, some of the LEDs of the upper channel are in the erased state, but the lighting state of some of the LEDs of the lower channel is not changed. The result is reflected in the synthesis result and output.

(2) Generation example 2 (example of using transparent definition data in continuous fluctuation production)
In the generation example 2, an effect (for example, a pre-reading effect) that is continuously executed over a plurality of variable display periods, and the effect content, expectation, reliability, and the like change stepwise over a plurality of variable display periods. , Or an LED animation used in an effect (for example, a loop image, a background image, a stage image, etc.) in which the display content or display mode does not change over a plurality of variable display periods using the transparent definition data. An example will be described. Hereinafter, these effects are referred to as “continuously varying effects”. Also, here, an example will be described in which in a continuous fluctuation effect, an effect in which a plurality of types of effects having different effect contents are combined is executed.

  FIG. 124 shows an outline of an LED animation generation example 2 (lighting operation example) using the transparency definition data. Note that FIG. 124 shows how the LED data of each channel set with respect to the predetermined LED 281 changes over time, and how the LED animation LED data (output data) output from the predetermined LED 281 as a synthesis result changes over time. FIG.

  In the example shown in FIG. 124, in a pre-reading effect performed over the period from the previous fluctuation display to the next fluctuation display, the lighting operation corresponding to the first fluctuation effect is performed by the predetermined LED 281 during the previous fluctuation display. During the next variation display, a lighting operation corresponding to the second variation effect is performed. That is, in the example of the continuous fluctuation effect shown in FIG. 124, the effect in which the contents of the effects are different from each other, and the pre-read effect, the first fluctuation effect, and the second fluctuation effect are combined is performed.

  Here, the “fluctuation effect” is an effect that ends in one fluctuation display period or an effect that is separated for each one fluctuation period. Further, even if the effect content is such that the effect content extends over a plurality of variable display periods, the effect in which the effect is temporarily separated at the end of one variable display is also included in the variable effect. Further, in the prefetching effect, control may be performed in the same manner as in the variable effect (that is, the prefetching effect may be included in the variable effect).

  The fluctuating effect performed in the example illustrated in FIG. 124 is, for example, an effect of fluctuating and stopping the decorative design displayed on the display area 13a of the display device 13. In the lighting operation of the LED 281 corresponding to the fluctuating effect, A lighting operation corresponding to the display operation of the decorative design image is performed. In addition, the look-ahead effect performed in the example illustrated in FIG. 124 is, for example, an effect performed using a background image of a decorative pattern. In the lighting operation of the LED 281 corresponding to the look-ahead effect, the lighting operation corresponding to the background image display operation is performed. Is performed.

  In the example shown in FIG. 124, during the prefetching effect, the first variable effect and the second variable effect are selected in the previous variable display, and the second variable effect is selected in the next variable display. This is a production example. The predetermined LED 281 controlled in the lighting operation example shown in FIG. 124 is an LED used for any of the first fluctuation effect and the second fluctuation effect. Therefore, which of the first variable effect and the second variable effect is executed in the predetermined LED 281 is determined according to the execution priority of the channel.

  In order to execute the lighting operation of the LED 281 corresponding to the continuous fluctuation effect, in the example shown in FIG. 124, the first fluctuation effect LED data (LED data of the lighting mode) is set in the eighth channel, and the seventh channel is set in the seventh channel. The second variation effect LED data (lighting mode LED data) is set, and the prefetch effect LED data (lighting mode LED data) is set in the sixth channel. Note that, also in this example, the execution priority between channels increases as the channel number increases, as in the above embodiment. That is, the eighth channel is at the top and the first channel is at the bottom.

  In the example shown in FIG. 124, the first fluctuation effect is performed during the previous fluctuation display, and the second fluctuation effect is performed during the next fluctuation display. Therefore, in the eighth channel, the first fluctuation effect is performed during the previous fluctuation display. The first variation effect LED data is set, and the transparent definition data (the second non-lighting mode LED data) is set during the next variation display. In the seventh channel, the LED data for the second fluctuation effect is set during the previous fluctuation display and the next fluctuation display. In the sixth channel, the pre-reading effect LED data is set during the previous fluctuation display and the next fluctuation display.

  Further, in the example shown in FIG. 124 (at the time of the continuous fluctuation effect), a channel whose execution priority is higher than the channel (the sixth channel) in which the LED data for the prefetch effect is set, that is, data for the fluctuation effect is set. In the first channel (the eighth and seventh channels), before the start of the second (next) variable effect (after the end of the first (previous) variable effect), one frame (“1F” in FIG. 124) of the transparent effect is transmitted. Definition data is set. Therefore, in the channel in which the data for the fluctuation effect is set, at the time of the continuous fluctuation effect, the LED data to which one frame of the transparent definition data has been added immediately before the second (next) fluctuation effect LED data. , Are used as LED data in the next variable display period. In the period in which the transparent definition data for one frame is added to the eighth and seventh channels, LED data for prefetching effect is set for the sixth channel.

  It should be noted that the process of adding one frame of the transparent definition data in the channel (the eighth and seventh channels) in which the data for the fluctuation effect is set, and the one-frame pre-reading effect LED data in the sixth channel The processing to be added is executed when the host control circuit 210 receives a command indicating the start of the next variable display. Specifically, when the effect is a continuous fluctuation effect, first, in the animation request construction process described later, LED data to which transparent definition data for one frame is added to the eighth and seventh channels, and A lamp request is set in which LED data in which LED data for one frame of prefetch effect is added to the sixth channel is set. Then, the LED data associated with the acquired lamp request is set in the LED 281.

  When the LED data is set in each channel of the predetermined LED 281 as described above, the output data of the synthesis result (LED animation) set in the predetermined LED 281 is the first fluctuation effect during the previous fluctuation display. LED data for the pre-reading effect is set during the period of one frame after the end of the previous variable display, and the LED data for the second variable effect is set during the next variable display. Is set (see “output data” in FIG. 124). That is, in the lighting operation example (continuous fluctuation effect) of the LED 281 illustrated in FIG. 124, the lighting operation corresponding to the first fluctuation effect is performed during the previous fluctuation display, and when the first fluctuation effect ends, the look-ahead effect (stage) The lighting operation corresponding to one effect is performed for one frame, and then the lighting operation corresponding to the second variable effect is started.

  The lighting operation example of the LED 281 illustrated in FIG. 124 is an operation example of the LED 281 that performs the lighting operation corresponding to the fluctuation effect in the continuous fluctuation effect. However, the LED 281 that performs the lighting operation corresponding to the pre-reading effect in the continuous fluctuation effect. In, transparent definition data is set for the eighth and seventh channels from the previous variable display period to the next variable display period.

  Here, in order to compare with the lighting operation example of the LED 281 shown in FIG. 124, in FIG. 125, in the channel where the data for the fluctuation effect is set, before the start of the second (next) fluctuation effect (the first (previous time)) An example of the lighting operation of the LED 281 in a case where the light-out data (LED data in the first non-lighting mode) for one frame is set after the fluctuation effect is completed).

  In this case, as the output data of the synthesis result (LED animation) set in the LED 281, during the previous fluctuation display, the LED data for the first fluctuation effect is set, and after the first (previous) fluctuation effect ends. In the period of one frame, not the LED data for the pre-reading effect but the extinguishing data is set, and during the next fluctuation display, the LED data for the second fluctuation effect is set (FIG. 125). "Output data"). That is, in the lighting operation example of the LED 281 shown in FIG. 125, after the lighting operation corresponding to the first fluctuation effect is performed, the light-off operation is performed for a period of one frame, and thereafter, the second fluctuation effect is supported. A lighting operation is started.

  In the lighting operation example of the predetermined LED 281 shown in FIG. 125, in the continuous fluctuation effect, the light-off operation is interposed between the first (previous) fluctuation effect and the second (next) fluctuation effect, so that the fluctuation display period is set. The effect of straddling (continuous fluctuation effect) is interrupted once. Such a lighting operation may be performed, for example, when the result of the previous fluctuation display is a loss, but in this case, it is determined whether or not the continuous fluctuation effect (pre-reading effect or the like) is continuing. There is also a disadvantage that it becomes difficult.

  However, as in the lighting operation example of the LED 281 shown in FIG. 124, in the continuous fluctuation effect, in the upper channel where the data for the fluctuation effect is set, the LED data for the first (previous) fluctuation effect and the second (the next time) If the transparent definition data is set in a period of one frame between the variable effect LED data and the lighting effect corresponding to the prefetch effect, the lighting operation is performed. In this case, it can be easily recognized that the continuous fluctuation effect (pre-reading effect or the like) is continuing.

  In addition, as in the lighting operation example of the LED 281 shown in FIG. 124, in the eighth channel, which is the highest in the execution priority, the transparent definition data is stored for a period from the end of the previous variable display to the end of the next variable display. Is set, the LED data of the eighth channel set during the previous fluctuation display can be reset (terminated).

  In addition, as in the lighting operation example of the LED 281 shown in FIG. 124, in the eighth channel, which is the highest in the execution priority, the transparent definition data is stored for a period from the end of the previous variable display to the end of the next variable display. Is set, while performing the lighting operation corresponding to the pre-reading effect and the second variable effect by the LED data set in the other lower channels, the LED of the lighting mode which becomes unnecessary after the end of the previous variable display. The data (the first fluctuation effect LED data) can be cleared. That is, in a case where the lighting effect of the LED 281 is performed using the LED data of a plurality of channels as in the lighting operation example of the LED 281 illustrated in FIG. When the definition data is set, only the lighting operation by the LED data of the specific channel is terminated, and the effect is smoothly continued while maintaining the lighting operation by the LED data of the other channels (smooth transition to the effect of the next fluctuation) can do.

  That is, by creating an LED animation using the transparent definition data, the effect is an effect in which a plurality of types of LED lighting effects are combined and executed over a plurality of variable display periods, such as a continuous variable effect. Even in such a case, it is possible to accurately and easily perform LED lighting control (effect control using the LED 281).

  In the above-described generation example 2, as the LED data setting mode, for example, on the eighth channel and the seventh channel, LED data (light emitting mode) of an effect that can be divided for each variable display period is set. It may be determined in advance that the LED data of the effect over a plurality of variable display periods is set in the sixth channel. In such a configuration, the transparent definition data for one frame (“1F” in FIG. 124) must be always stored in the eighth and seventh channels before the start of the next variable effect (after the end of the previous variable effect). Is set. In this case, for example, it is not necessary to set the set lighting time of the LED data set on the eighth channel and the seventh channel longer, that is, there is no need to handle unnecessary LED data, and the control is simplified. Is also obtained.

  Further, in the above-described generation example 2, in order to facilitate understanding of the method of creating the LED animation using the transparent definition data, the light emission mode (the lighting mode and / or the lighting mode) for the eighth channel having the highest execution priority is given. Alternatively, an example of setting non-lighting mode LED data) has been described, but the present invention is not limited to this. A light emission mode (LED data, etc.) for error notification with a high notification priority is set on the eighth channel having the highest execution priority, and a light emission mode (lighting mode and / or (Non-lighting mode LED data) may be set.

(3) Generation example 3
As in the above-described generation example 2 (FIG. 124: lighting operation example of the continuous fluctuation effect), in the channel (the eighth and seventh channels) in which the LED data for the fluctuation effect is set, the next time the fluctuation display ends, In the configuration in which the transparent definition data is set over the period up to the end of the variable display, the set lighting time (output period) of the variable effect LED data set in the previous variable display period is the lighting actually executed. It may be longer than the time.

  Also in this case, when the host control circuit 210 receives a command indicating the start of the next variable display, since the transparent definition data is set thereafter, the variable effect for the variable effect set in the previous variable display period is set. Even if the set lighting time is longer than the lighting time of the fluctuation effect actually executed, it is possible to forcibly end the fluctuation effect during the previous fluctuation display before the lighting time reaches the set lighting time. it can. FIG. 126 shows an example of the lighting operation.

  FIG. 126 shows the time change of the LED data set on the eighth channel of the predetermined LED 281 and the LED data (setting data) for the first (previous) fluctuation effect set on the eighth channel of the predetermined LED 281. FIG. 3 is a diagram illustrating a relationship with a configuration.

  In the third generation example shown in FIG. 126, the first variation effect LED data (the lighting mode LED data) is set for the eighth channel during the previous variation display. At this time, the set lighting time of the first variation effect LED data is set to a value longer than the lighting time of the first variation effect that is actually executed (see “setting data” in FIG. 126). Then, when the previous variable display is completed and the host control circuit 210 receives a command indicating the start of the next variable display, the transparent definition data (non-lighting mode) is provided for one frame (“1F” in FIG. 126). LED data) is set in the eighth channel, and thereafter, the transparent definition data is set over the next variable display period.

  As a result, as shown in FIG. 126, in the first variation effect performed during the previous variation display, even if the execution time of the lighting operation of the LED 281 is shorter than the set variation time, the transparent definition is started at the next variation display start. The data is set, and the first fluctuation effect is forcibly ended.

  When the LED animation is created using the transparent definition data as in the above generation example 3, it is not necessary to strictly set the set lighting time of the LED data. In this case, the LED control becomes easy (simple) and the cost can be reduced.

  In the lighting operation example of the LED 281 shown in FIG. 126, the fluctuation effect during the previous fluctuation display is forcibly terminated in the eighth channel (although the LED data is forcibly cleared), but is set thereafter. Since the LED data is also the transparent definition data, it does not affect the lighting control of the LED 281 by the LED data set in another channel.

  In the example shown in FIG. 126, when non-lighting mode LED data is used as the non-lighting mode LED data in place of the transparent definition data, after the end of the previous variable display, regardless of the LED data of other channels, The light-out data set in the eighth channel having the highest execution priority is output as a synthesis result. Therefore, in this case, after the end of the previous variable display, the LED 281 is turned off, and the lighting operation based on the LED data set in another channel is not performed.

  In the above-mentioned generation example 3 (example shown in FIG. 126), in the eighth channel, an example in which the transparent definition data (non-lighting mode LED data) is set over the next variable display period has been described. It is not limited to. For example, in the eighth channel, the LED data of the lighting mode may be set over the next variable display period. Further, in this case, in the eighth channel, even during the period of one frame before the start of the next variable effect (after the end of the previous variable effect), the lighting mode is used instead of the transparent definition data (non-lighting mode LED data). May be set.

  Furthermore, in the above-described generation example 3, the configuration in which the LED data (transparent definition data) in the non-lighting mode is set over the next variable display period in the eighth channel has been described, but the present invention is not limited to this. For example, in the eighth channel, a configuration in which neither the lighting mode LED data nor the non-lighting mode LED data is set over the next variable display period, that is, the LED 281 is driven over the next variable display period A configuration in which the data itself is not set may be adopted. In this case, in the next variable display period, it is determined that the eighth channel is not used, and the eighth channel is omitted from the execution priority determination target. Therefore, in this case, in the next variable display period, the lighting control can be performed with the seventh channel as the highest channel of the execution priority. In this process, the eighth channel is omitted from the execution priority determination target, but the present invention is not limited to this. For example, instead of this omitting process, the execution priority determination is not performed for the eighth channel. Whether or not any of the lighting mode LED data and the non-lighting mode LED data is set for the eighth channel The light emission control of the LED 281 may be performed by performing a process such as performing only the determination of. When such control is performed, it becomes possible to simplify the process of light emission control.

(4) Generation example 4 (example of using transparent definition data when producing a button)
The lighting control of the LED 281 described in the generation example 3 can be applied to effects other than the continuous fluctuation effect. One of them is an effect that instructs a player to perform a button press operation (hereinafter, referred to as a “button effect”). In a fourth generation example, an example will be described in which an LED animation used in a button effect is generated using transparency definition data.

  In the button effect, the button effect is terminated by setting the transparent definition data when a pressing operation of the player is detected during the effect and thereafter. FIG. 127 shows a setting mode of the LED data of each channel when executing the button effect using the transparent definition data.

  In the example shown in FIG. 127, the LED data for the button press effect (the LED data in the first lighting mode) is set to the eighth channel. In this case, as the setting lighting time of the LED 281 in the button effect, the longest LED lighting time of the button effect (executable time of the button pressing operation by the player) is set as shown in “setting data” in FIG. You. In the seventh channel, LED data for stage effects (LED data in the second lighting mode) is set.

  That is, in the example of the button effect shown in FIG. 127, an effect in which the effect contents are different from each other, and in which the button press effect and the stage effect are combined, is performed. Note that, also in this example, the execution priority between channels increases as the channel number increases, as in the above embodiment. That is, the eighth channel is at the top and the first channel is at the bottom.

  Here, the button press effect is, for example, an effect of displaying a symbol image (instruction image) for instructing a player to perform a button press operation on the display area 13a of the display device 13, and corresponds to the button press effect. In the lighting operation of the LED 281 to be performed, a lighting operation corresponding to a symbol image display operation instructing a player to perform a button press operation is performed. The stage effect referred to here is, for example, an effect performed by a background image of a symbol image that instructs a player to perform a button press operation. In the lighting operation of the LED 281 corresponding to the stage effect, the background image is displayed. A lighting operation corresponding to the operation is performed.

  In the button effect, as shown in FIG. 127, during the period from the start of the button effect to the time before the button press operation by the player is detected, the button set to the eighth channel having a higher execution priority than the seventh channel LED data for a press effect is set as output data. Therefore, during the period from the start of the button effect to the time before the button press operation by the player is detected, the lighting operation corresponding to the LED data for the button press effect set on the eighth channel is performed.

  Then, when a button press operation by the player is detected during the button effect, the transparency definition data is set in the eighth channel thereafter. In this case, after the detection of the button press operation, the LED data for the stage effect set on the seventh channel is set as the output data. As a result, when the button pressing operation is detected, the lighting operation corresponding to the button pressing effect ends (the display operation of the instruction image of the button pressing operation ends), and thereafter, the lighting operation corresponding to the stage effect is executed. Is done.

  Even when LED data for a button press effect with the longest LED lighting time set in the upper channel is set as in the above-described button effect, the transparent definition data is transmitted when the button press operation is detected and thereafter. By setting, it is possible to smoothly shift the LED lighting control from the LED lighting control corresponding to the button press effect set to the upper channel to the LED lighting control corresponding to the stage effect set to the lower channel.

  When an effect in which the lighting time of the LED 281 is irregular and an effect in which the lighting time is not irregular as shown in FIG. 127 are executed in combination, it is necessary to prepare LED data with a strictly set time schedule. However, in practice, it is difficult to prepare such LED data. However, as in the above-described generation example 4, the LED data of the effect in which the lighting time of the LED 281 is irregular is set in the upper channel, the LED data of the effect in which the lighting time is not irregular is set in the lower channel, and the lighting time is set. Is set to be longer than the predicted actual maximum lighting time, and the transparent definition data is set to the upper channel at the time of detecting any trigger (such as at the time of detecting a button press) and thereafter. In the setting configuration, it is not necessary to strictly set the time schedule of the combined LED data.

  That is, when the LED animation is created using the transparency definition data, the effect is an effect such as a button effect in which an effect in which the lighting time of the LED 281 is irregular and an effect in which the lighting time is not irregular are combined. Even in this case, it is possible to accurately and easily perform LED lighting control (effect control using the LED 281).

  The lighting operation example of the LED 281 illustrated in FIG. 127 is an operation example of the LED 281 that performs the lighting operation (display operation of the instruction image of the button pressing operation) corresponding to the button pressing effect in the button effect. In the LED 281 responsible for the lighting operation corresponding to the stage effect, the transparent definition data is set for the eighth channel during the period from the start to the end of the button effect.

(5) Method of Controlling LED Lighting Operation Next, a method of generating an LED animation when using the above-described transparent definition data (a method of controlling the lighting operation of the LED 281) will be described with reference to FIG. In this example, the effect using the transparent definition data (for example, the above-described continuous fluctuation effect and button effect) is distinguished from other effects, and if the effect to be executed is the former, the effect is executed. The corresponding lamp request is selected in the animation request construction process. As a result, based on the selected lamp request, the LED data including the transparent definition data as described in the above-described various generation examples is selected, and an LED animation using the transparent definition data is generated.

  FIG. 128 is a flowchart showing the procedure of the animation request construction process in this example. Note that, in each step of the animation request construction processing in this example, the same steps as those in the animation request construction processing (FIG. 92) in the above embodiment are denoted by the same reference numerals.

  In addition, in the ninth modification, processing other than the animation request construction processing can be executed in the same manner as in the above-described embodiment, and the configuration of the pachinko gaming machine of this example can be the same as that of the above-described embodiment. Therefore, here, only the animation request construction processing will be described. In addition, the animation request construction process in this example is also performed in S206 of the sub-control main process (see FIG. 79), similarly to the above embodiment.

(5-1) Animation Request Construction Processing As is clear from the comparison between the flowchart of the animation request construction processing of this example shown in FIG. 128 and the flowchart of the animation request construction processing of the above embodiment shown in FIG. The processes of S341 to S351 during the animation request construction process are the same as those of the above embodiment. Therefore, here, the description of the processing of S341 to S351 is omitted, and the processing of S352 and thereafter will be described.

  After the processing of S351, or when the determination of S341 or S348 is NO, the host control circuit 210 refers to the information of the game data stored in the subwork RAM 210a, and sets the object (for example, the effect object, the hold object, the simple mode object). ), And sets the animation request in a predetermined area of the subwork RAM 210a (S352). By this processing, an animation request corresponding to the command reception is generated.

  Next, the host control circuit 210 performs a sound request generation process based on the animation request (S353A). In this process, the host control circuit 210 generates a sound request corresponding to the effect specified by the animation request. In this process, the host control circuit 210 provides the generated sound request in the host control circuit 210 in order to synchronize the video display operation with the audio reproduction operation, the light emission operation, and the accessory driving operation. Temporarily stored in the request buffer.

  Next, the host control circuit 210 performs a lamp request generation process (S353B). In this process, the host control circuit 210 generates a corresponding lamp request based on the animation request, the effect contents, and the presence or absence of the player's pressing operation. The details of the lamp request generation process will be described later with reference to FIG. 129 described later.

  Next, the host control circuit 210 performs an accessory request generation process based on the animation request (S353C). In this process, the host control circuit 210 generates an accessory request corresponding to the effect specified by the animation request. In this processing, the host control circuit 210 provides the generated accessory request in the host control circuit 210 in order to synchronize the video display operation with the audio reproduction operation, the light emitting operation, and the accessory driving operation. Temporarily stored in the specified request buffer.

  Then, after the processing of S353C, the host control circuit 210 ends the animation request construction processing of this example, and shifts the processing to S207 of the sub-control main processing (see FIG. 79).

(5-2) Ramp Request Generation Processing Next, the ramp request generation processing performed in S353B in the animation request construction processing (see FIG. 128) of this example will be described with reference to FIG. FIG. 129 is a flowchart showing the procedure of the lamp request generation processing of this example executed by the host control circuit 210.

  First, the host control circuit 210 acquires (calls) a lamp request corresponding to the effect specified by the animation request (S851).

  Next, the host control circuit 210 determines whether or not the current time is the start of the fluctuation during the continuous fluctuation effect (S852). Specifically, the host control circuit 210 receives a command (such as a fluctuation stop command or a command indicating a jackpot) relating to the fluctuation stop and then receives a command (such as a special symbol effect start command) relating to the start of the fluctuation. Is determined, and it is determined whether or not the current time is the start of the fluctuation during the continuous fluctuation effect. Then, if the host control circuit 210 receives a command related to start of change after receiving a command related to stop of change, the determination in S852 is YES.

  In S852, if the host control circuit 210 determines that the current time is not the start of the fluctuation during the continuous fluctuation effect (if S852 is NO), the host control circuit 210 performs the processing of S854 described later.

  On the other hand, in S852, when the host control circuit 210 determines that the current time point is the start of the fluctuation during the continuous fluctuation effect (when S852 is YES), the host control circuit 210 issues a lamp request for the continuous fluctuation effect. It is acquired (S853). In this process, the host control circuit 210 rewrites the lamp request obtained in S851 with a lamp request for a continuous fluctuation effect. As a result, a lamp request associated with the LED data for continuous fluctuation effect using the transparent definition data is generated.

  After the process of S853, or when the determination of S852 is NO, the host control circuit 210 determines whether or not the current time is during the button effect and the button operation by the player is detected (S854). Specifically, the host control circuit 210 determines whether a signal (input signal in FIG. 85) corresponding to the execution of the button press operation by the player has been input to the host control circuit 210 from the button operation driver during the button effect. It is determined whether or not the present time is during the button effect and when the button operation by the player is detected. Then, when the host control circuit 210 detects the input of the signal corresponding to the execution of the button pressing operation during the button effect, the determination in S854 is YES.

  In S854, when the host control circuit 210 determines that the determination condition of S854 is not satisfied (when S854 is NO), the host control circuit 210 performs processing of S856 described later.

  On the other hand, in S854, when the host control circuit 210 determines that the determination condition of S854 is satisfied (YES in S854), the host control circuit 210 acquires a lamp request for button effect (S855). In this process, the host control circuit 210 rewrites the lamp request acquired in S851 with a lamp effect for button effect. As a result, a lamp request associated with the button effect LED data using the transparent definition data is generated.

  After the process of S855, or in the case of NO determination in S854, the host control circuit 210 acquires the acquired (generated) image data in order to synchronize the video display operation with the audio reproduction operation, the light emission operation, and the accessory driving operation. ) The lamp request is temporarily stored in a request buffer provided in the host control circuit 210 (S856). After the processing of S856, the host control circuit 210 ends the ramp request generation processing of this example, and moves the processing to S353C of the animation request construction processing of this example (see FIG. 128).

(6) Summary and Modification of Various Effects The lighting control of the LED 281 using the transparent definition data of this example is particularly suitable for the lighting control when a plurality of types of LED lighting effects are combined as described above. Specifically, when the effects are combined, it is usually necessary to create a complicated time chart for the LED data of each effect. However, as shown in this example, a plurality of channels for which the execution priority order is set are set. In the case where the LED data of each effect is set at the same time, and the transparent definition data is appropriately set at a predetermined timing in the upper channel according to the contents of the effect, it is necessary to create data in which the lighting time of the LED 281 is strictly set. It is easier to create the production data. That is, by creating an LED animation using the transparency definition data, even if a plurality of types of LED lighting effects are combined, accurate and simple LED lighting control (effect control using the LED 281) is performed. be able to.

  In the lighting control of the LED 281 using the transparent definition data of this example, the following effects can be obtained. In the current design method for pachinko gaming machines, the set lighting time of the LED is often set to be longer than the actual effect time (set to the longest lighting time). In this case, for example, when the lighting operation of the LED in the previous fluctuation effect ends and the lighting operation of the LED corresponding to the next fluctuation effect starts, the LED data set in the previous fluctuation effect is likely to remain, As a result, there is a problem that the operation of shifting the LED lighting from the previous fluctuation effect to the next fluctuation effect is not smooth. However, by setting the transparent definition data at the start of each variable effect as in this example, it is possible to prevent the influence of extra LED data remaining in the previous variable effect.

  In addition, in the various examples of generating the LED animation described above, as an effect without setting the transparent definition data, an effect called a look-ahead effect or a stage effect has been described as an example, but the present invention is not limited to this. In addition to these effects, for example, LED data used in a display effect of a symbol corresponding to a special symbol lottery result called “fourth symbol” and LED data used in displaying an error are transparent. The definition data may not be set.

  Further, the LED data of the fourth symbol is set to a channel having a higher execution priority than a channel in which LED data for effect called prefetch effect or stage effect is set. Further, the LED data for error display is set to a channel having a higher execution priority than the channel in which the LED data of the fourth symbol is set.

[Application example]
In the above-described embodiment and the above-described various modified examples, the pachinko gaming machine has been described as an example of the gaming machine, but the present invention is not limited to this. The various technologies of the present invention described above can be applied to other game machines, for example, various game machines such as ball game machines, pachislot machines, gaming machines, enclosed game machines, and rotary game machines. It can also be applied.

  DESCRIPTION OF SYMBOLS 1 ... Pachinko gaming machine (game machine), 2 ... Main body, 3 ... Base door, 4 ... Glass door, 11 ... Speaker, 11a ... Speaker box, 11b ... Connection terminal group, 12 ... Game board, 13 ... Display device, 15 ... launching device, 16 ... dispensing device, 18 ... lamp (LED) group, 20 ... accessory, 43 ... ball passage detector, 44 ... first starting port, 45 ... second starting port, 46 ... ordinary electric accessory, 51, 52: General winning opening, 53: First winning opening, 54: Second winning opening, 55: Out opening, 56: Gaming nail, 61: Special symbol display device, 62: Normal symbol display device, 63 ... Normal symbol hold display device, 64 first special symbol hold display device, 65 second special symbol hold display device, 70 main control circuit, 71 main CPU, 72 main ROM, 73 main RAM, 77 one Chip microcomputer, 123 ... Payout / Launch Control circuit, 200: sub control circuit, 201: relay board, 202, 202a: sub board, 203: control ROM board, 204, 204a, 204b: CGROM board, 205: sub main ROM, 206, 206a, 206b: CGROM, 210: Host control circuit, 210a: Subwork RAM, 210b: SRAM, 220, 290: Audio / LED control circuit, 230, 230a: Display control circuit, 234: Video decoder, 235: Still image decoder, 236: SDRAM controller 237 internal VRAM, 238 first display controller, 239 second display controller, 240 3D geometry engine, 241 rendering engine, 250 SDRAM, 260 internal relay board, 261 I2C controller, 262 Digital audio power amplifier, 263 LC circuit, 264 connection terminal group, 268 NOT circuit, 269 voltage conversion circuit section, 270 motor controller, 271 motor driver, 272 motor, 275 excitation state detection section, 276 ... first OR circuit, 277 ... second OR circuit, 278 ... third OR circuit, 280,291 ... LED driver, 281 ... LED, 300 ... harness, 301 ... bidirectional balance transceiver, 302 ... AND circuit, 303,311 ... terminal group Reference numeral 312: Transistor circuit, 350: Voltage drop circuit unit, 351 to 355: First to fifth diodes, 360: Linear regulator

Claims (1)

A gaming machine that changes identification information when a predetermined starting condition is satisfied,
Effect control means for controlling the effect,
Light emitting means for performing a predetermined effect operation based on the driving data,
With
The effect control means,
Drive generation data for generating the drive data can be set, a plurality of systems each set the execution priority of the set drive generation data,
Selecting means for selecting, as the drive data, the drive generation data set to a predetermined system from among the plurality of systems, according to the execution priority set to the system,
When the first drive generation data is set in the first system and the second drive generation data is set in the second system having a higher execution priority than the first system,
When the second drive generation data is data in the first non-lighting mode, the selection unit selects the second drive generation data as the drive data, and the second drive generation data is the second drive generation data. When the data of the second non-lighting mode is different from the data of the first non-lighting mode, the selection means selects the first drive generation data as the drive data,
When starting the variation display of the identification information, in accordance with the content of the effect, in at least one of the systems, at least immediately before starting the production operation of the light emitting means corresponding to the variation display of the identification information, A gaming machine wherein data of a second non-lighting mode is set.

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