JP2023074810A - game machine - Google Patents

Abstract

To further reduce both manufacturing costs and development costs in a game machine having a function to control the display of multiple segments on the sub side.SOLUTION: Data storage means of a game machine comprises a first storage area for storing first light emission data for driving and controlling a plurality of multicolor light emission means, second storage area for storing selection information for selecting one segment light emission means from a plurality of segment light emission means, a third storage area for storing second light emission data for driving and controlling one selected segment light emission means, and a fourth storage area for storing all of the plurality of second light emission data for driving and controlling the plurality of segment light emission means. When setting the second light emission data in the third storage area, control means reads the second light emission data of the corresponding segment light emission means which is stored in the fourth storage area and sets it in the third storage area.SELECTED DRAWING: Figure 156

Description

The present invention relates to gaming machines such as pachislot machines and pachinko machines.

Among conventional game machines, there has been proposed a game machine equipped with a segment display device that selectively emits light from a plurality of segments to display arbitrary numbers and characters under the control of a sub-control board (see, for example, Patent Document 1). ). In the gaming machine disclosed in Patent Document 1, the sub-control board transmits segment image data to the image control board, and the image control board displays the segment image.

JP 2008-295655 A

However, for example, in the game machine of Patent Document 1, the purpose is to cope with an increase in segment size at low cost while maintaining good display quality. There is a demand for a technology capable of further reducing both the manufacturing cost and the development cost in a game machine having a function of controlling the display of a plurality of segments on each side.

The present invention has been made in view of these points, and makes it possible to further reduce both the manufacturing cost and the development cost in a game machine equipped with a function of controlling the display of a plurality of segments on the sub side. for the purpose.

In order to achieve the above object, according to the gaming machine according to the present embodiment, it is possible to provide a gaming machine having the following configuration.

Light-emitting means (for example, various lamp groups described later);
a plurality of light emission driving means (for example, a group of LED driver ICs described later) for driving the light emitting means;
A control means (for example, a sub microprocessor 981 described later) that drives the plurality of light emission drive means and controls the light emission operation of the light emission means,
The light emitting means includes a plurality of multicolor light emitting means (for example, light source units such as the first lamp group 1011 to be described later) and a plurality of segment light emitting means (for example, the first segment to the seventh segment of the seventh lamp group 1017 to be described later). ) and
The multicolor light emitting means is composed of light emitting elements capable of emitting color light, the segment light emitting means is composed of a plurality of segment light emitting elements,
The control means is
light emission data generating means (for example, interrupt control processing and lamp control task to be described later) for generating light emission data (for example, light emission driving data to be described later) for controlling the light emission driving means;
Data storage means (for example, a lamp buffer described later) for storing the light emission data generated by the light emission data generation means,
The data storage means are
a first storage area (for example, a buffer area for a first lamp group 1011 to be described later) for storing first light emission data for driving and controlling the plurality of multicolor light emitting means;
a second storage area (for example, an anode area in a seventh lamp group 1017 to be described later) for storing selection information for selecting one segment light emitting means from among the plurality of segment light emitting means;
a third storage area (for example, a cathode area in a seventh lamp group 1017 to be described later) in which second light emission data for driving and controlling one selected segment light emitting means is stored;
a fourth storage area (for example, a buffer area for a dummy lamp described later) in which all of the plurality of second light emission data for respectively driving and controlling the plurality of segment light emitting means are stored;
When the control means sets the second light emission data for driving and controlling the selected one segment light emission means in the third storage area, the control means sets the corresponding segment light emission means stored in the fourth storage area. A game machine characterized by reading out the second light emission data of and setting it in the third storage area.

According to the gaming machine of the present invention having the above configuration, both the manufacturing cost and the development cost can be further reduced in the gaming machine having the function of controlling the display of a plurality of segments on the sub side.

It is a figure which shows the external structure of the gaming machine which concerns on this embodiment. It is a figure which shows the internal structure of the gaming machine which concerns on this embodiment. 1 is a block diagram showing an electrical configuration of a game machine according to this embodiment; FIG. It is a figure for demonstrating the function flow of the gaming machine based on this embodiment. It is a figure for demonstrating the playability of the 1st gaming machine based on this embodiment. It is a diagram for explaining the mode of the first gaming machine according to the present embodiment. It is a figure which shows the various tables of the 1st gaming machine based on this embodiment. It is a figure which shows the various tables of the 1st gaming machine based on this embodiment. It is a figure which shows the symbol arrangement table of the 1st gaming machine based on this embodiment. It is a figure which shows the internal lottery table of the 1st gaming machine based on this embodiment. It is a figure which shows the symbol combination table of the 1st gaming machine based on this embodiment. It is a figure which shows the symbol combination table of the 1st gaming machine based on this embodiment. It is a figure which shows the symbol combination table of the 1st gaming machine based on this embodiment. It is a figure which shows the symbol combination table of the 1st gaming machine based on this embodiment. FIG. 10 is a diagram for explaining a correspondence relationship between an internal winning combination, a stop operation mode, a display combination, etc., of the first gaming machine according to the present embodiment; It is a figure for demonstrating the limit process of the 1st gaming machine based on this embodiment. It is a diagram showing the configuration of the winning flag storage area, winning operation flag storage area, and symbol code storage area of the first gaming machine according to the present embodiment. It is a figure which shows the structure of the carryover combination storage area|region of the 1st gaming machine which concerns on this embodiment. FIG. 4 is a diagram showing the configuration of a game state flag storage area of the first gaming machine according to the present embodiment; It is a diagram showing the configuration of the mode flag storage area of the first gaming machine according to the present embodiment. It is a figure which shows the structure of the operation|movement stop button storage area|region of the 1st game machine which concerns on this embodiment. It is a diagram showing the configuration of the pressing order storage area of the first gaming machine according to the present embodiment. 4 is a flow chart showing main processing executed by the main control circuit of the first gaming machine according to the present embodiment; 4 is a flowchart showing power-on processing executed by the main control circuit of the first gaming machine according to the present embodiment. FIG. 10 is a flow chart showing medal acceptance/start check processing executed by the main control circuit of the first gaming machine according to the present embodiment; FIG. 4 is a flowchart showing internal lottery processing executed by the main control circuit of the first gaming machine according to the present embodiment; 4 is a flow chart showing a game start state control process executed by the main control circuit of the first gaming machine according to the present embodiment; It is a flow chart showing processing at the start of a game during an advantageous section, which is executed by the main control circuit of the first gaming machine according to the present embodiment. 4 is a flowchart showing reel stop control processing executed by the main control circuit of the first gaming machine according to the present embodiment; 4 is a flow chart showing a game end state control process executed by the main control circuit of the first gaming machine according to the present embodiment. FIG. 10 is a flow chart showing processing at the end of a game during an advantageous section, which is executed by the main control circuit of the first gaming machine according to the present embodiment; FIG. 4 is a flowchart showing regular interruption processing executed by the main control circuit of the first gaming machine according to the present embodiment; 4 is a flow chart showing an overview of sub-side control processing executed by the sub-control circuit of the gaming machine according to the present embodiment; It is a diagram showing a configuration example of a medalless gaming machine according to the present embodiment. It is a figure which shows the structural example of the main-control board of the game machine which concerns on this embodiment. It is a figure which shows the external structure of the 2nd gaming machine based on this embodiment. It is a block diagram showing the electrical configuration of the second gaming machine according to the present embodiment. It is a diagram for explaining the transition of the RT state of the second gaming machine according to the present embodiment. It is a diagram showing a symbol arrangement table of the second gaming machine according to the present embodiment. It is a figure which shows the internal lottery table of the 2nd gaming machine based on this embodiment. It is a figure which shows the internal lottery table of the 2nd gaming machine based on this embodiment. It is a figure which shows the symbol combination table of the 2nd gaming machine based on this embodiment. It is a figure which shows the symbol combination table of the 2nd gaming machine based on this embodiment. FIG. 10 is a diagram for explaining the correspondence relationship (general (non-internal)) among the internal winning combination, the stop operation mode, and the display combination, etc. of the second gaming machine according to the present embodiment; FIG. 10 is a diagram for explaining the correspondence relationship (general (non-internal)) among the internal winning combination, the stop operation mode, and the display combination, etc. of the second gaming machine according to the present embodiment; FIG. 11 is a diagram for explaining the correspondence relationship (inside the RB) between the internal winning combination, the stop operation mode, and the display combination, etc. of the second gaming machine according to the present embodiment; FIG. 11 is a diagram for explaining the correspondence relationship (inside the RB) between the internal winning combination, the stop operation mode, and the display combination, etc. of the second gaming machine according to the present embodiment; FIG. 10 is a diagram for explaining the correspondence relationship (inside the BB) between the internal winning combination, the stop operation mode, and the display combination, etc. of the second gaming machine according to the present embodiment; FIG. 10 is a diagram for explaining the correspondence relationship (inside the BB) between the internal winning combination, the stop operation mode, and the display combination, etc. of the second gaming machine according to the present embodiment; It is a figure for demonstrating the playability of the 2nd gaming machine based on this embodiment. It is a table list of the high probability zone and the BIG probability zone of the second gaming machine according to the present embodiment. It is a table of the high probability zone and the BIG probability zone of the second gaming machine according to the present embodiment and a correspondence table of the zone. It is a table list of the consecutive chan zone of the second gaming machine according to the present embodiment. It is a diagram showing a table type lottery table (RT0) of the second gaming machine according to the present embodiment. It is a diagram showing a table type lottery table (other than RT0) of the second gaming machine according to the present embodiment. It is a diagram showing a table type lottery table (with RB in operation) of the second gaming machine according to the present embodiment. It is a diagram showing a table type lottery table (during BB operation) of the second gaming machine according to the present embodiment. It is a correspondence table of zones and MAP levels of the second gaming machine according to the present embodiment. FIG. 10 is a correspondence table of the MAP level of the second gaming machine according to the present embodiment and the winning rate of the pseudo-bonus. FIG. It is a diagram showing a normal map lottery table_zone 0 (table A) of the second gaming machine according to the present embodiment. It is a diagram showing a normal map lottery table_zone 0 (table B) of the second gaming machine according to the present embodiment. It is a diagram showing a normal map lottery table_zone 0 (table C) of the second gaming machine according to the present embodiment. FIG. 10 is a diagram showing a normal map lottery table_zone 0 (table D) of the second gaming machine according to the present embodiment; It is a diagram showing a normal map lottery table_zone 0 (table E) of the second gaming machine according to the present embodiment. It is a diagram showing a normal map lottery table_zone 1 (table A) of the second gaming machine according to the present embodiment. FIG. 10 is a diagram showing a normal map lottery table_zone 1 (table B) of the second gaming machine according to the present embodiment; It is a diagram showing a normal map lottery table_zone 1 (table C) of the second gaming machine according to the present embodiment. FIG. 10 is a diagram showing a normal map lottery table_zone 1 (table D) of the second gaming machine according to the present embodiment; It is a diagram showing a normal map lottery table_zone 1 (table E) of the second gaming machine according to the present embodiment. It is a diagram showing a normal map lottery table_zone 2 (table A) of the second gaming machine according to the present embodiment. FIG. 10 is a diagram showing a normal map lottery table_zone 2 (table B) of the second gaming machine according to the present embodiment; FIG. 10 is a diagram showing a normal map lottery table_zone 2 (table C) of the second gaming machine according to the present embodiment; FIG. 10 is a diagram showing a normal map lottery table_zone 2 (table D) of the second gaming machine according to the present embodiment; FIG. 10 is a diagram showing a normal map lottery table_zone 2 (table E) of the second gaming machine according to the present embodiment; It is a diagram showing a normal map lottery table_zone 3 (table A) of the second gaming machine according to the present embodiment. FIG. 10 is a diagram showing a normal map lottery table_zone 3 (table B) of the second gaming machine according to the present embodiment; FIG. 10 is a diagram showing a normal map lottery table_zone 3 (table C) of the second gaming machine according to the present embodiment; FIG. 10 is a diagram showing a normal map lottery table_zone 3 (table D) of the second gaming machine according to the present embodiment; It is a diagram showing a normal map lottery table_zone 3 (table E) of the second gaming machine according to the present embodiment. It is a diagram showing a normal map lottery table_zone 4 (table A) of the second gaming machine according to the present embodiment. It is a diagram showing a normal map lottery table_zone 4 (table B) of the second gaming machine according to the present embodiment. It is a diagram showing a normal map lottery table_zone 4 (table C) of the second gaming machine according to the present embodiment. It is a diagram showing a normal map lottery table_zone 4 (table D) of the second gaming machine according to the present embodiment. It is a diagram showing a normal map lottery table_zone 4 (table E) of the second gaming machine according to the present embodiment. It is a figure which shows the re-chan zone map lottery table (table F) of the 2nd gaming machine which concerns on this embodiment. It is a figure which shows the re-chan zone map lottery table (table G) of the 2nd gaming machine which concerns on this embodiment. It is a figure which shows the re-chan zone map lottery table (table H) of the 2nd gaming machine which concerns on this embodiment. It is a figure which shows the re-chan zone map lottery table (table I) of the 2nd gaming machine which concerns on this embodiment. It is a diagram showing a map 0 o'clock forced portent entry lottery table of the second gaming machine according to the present embodiment. It is a diagram showing a forced precursor G number lottery table of the second gaming machine according to the present embodiment. It is a figure which shows the AT lottery table (MAP level 0) at the time of reaching the forced sign G number of the second gaming machine according to the present embodiment. It is a figure which shows the AT lottery table (MAP level 1) at the time of reaching the forced precursor G number of the second gaming machine according to the present embodiment. It is a figure which shows the AT lottery table (MAP level 2) at the time of reaching the number of forced sign G of the 2nd game machine which concerns on this embodiment. It is a figure which shows the AT lottery table (MAP level 3) at the time of reaching the forced precursor G number of the second gaming machine according to the present embodiment. It is a figure which shows the AT lottery table (MAP level 4) at the time of reaching the forced sign G number of the second gaming machine according to the present embodiment. It is a figure which shows the AT lottery table (MAP level 5) at the time of reaching the forced sign G number of the second gaming machine according to the present embodiment. It is a figure which shows the AT lottery table (MAP level 6) at the time of reaching the forced sign G number of the 2nd game machine which concerns on this embodiment. It is a diagram showing a normal AT lottery table (without table type) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 0) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 1) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 2) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 3) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 4) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 5) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 6) of the second gaming machine according to the present embodiment. It is a diagram showing an AT lottery table at the time of reaching the AT point of the second gaming machine according to the present embodiment. It is a figure which shows the AT lottery table during a fake precursor of the 2nd gaming machine which concerns on this embodiment. It is a figure which shows AT type promotion lottery table (REG) in this precursor of the 2nd gaming machine which concerns on this embodiment. It is a figure which shows AT classification promotion lottery table (BIG) in this sign of the 2nd gaming machine which concerns on this embodiment. It is a diagram showing an AT type lottery table (continuous chan zone) of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (200G and later) of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (at the time of special ON) of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (1-100G) of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (101-200G) of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (normal) at the middle stage cherry of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (continuous chan zone) at middle stage cherry of the second gaming machine according to the present embodiment. It is a figure explaining the normal production|presentation pattern of the 2nd gaming machine based on this embodiment. It is a figure explaining the production|presentation pattern at the time of winning the cherry navigation lottery of the 2nd gaming machine which concerns on this embodiment. FIG. 10 is a simplified diagram for explaining the timing of state transition processing of the second gaming machine according to the present embodiment; It is a figure which shows the special rewriting lottery table (special OFF) of the 2nd gaming machine which concerns on this embodiment. It is a figure which shows the special rewriting lottery table (special ON) of the 2nd gaming machine which concerns on this embodiment. It is a diagram showing a cherry-navi lottery table (special OFF) of the second gaming machine according to the present embodiment. It is a diagram showing a cherry-navi lottery table (special ON) of the second gaming machine according to the present embodiment. It is a block diagram showing the configuration of the control system of the third gaming machine according to the present embodiment. FIG. 10 is a diagram showing one configuration example of an information display device used when the third gaming machine according to the present embodiment is a normal (non-medalless) gaming machine. It is a figure which shows one structural example of the information display apparatus used when the 3rd gaming machine based on this embodiment is a medalless gaming machine. FIG. 11 is a block diagram showing the internal configuration of the HB-LSI used in the third gaming machine according to the present embodiment; FIG. 11 is a block diagram showing the internal configuration of an HB-LSI asynchronous serial communication circuit used in the third gaming machine according to the present embodiment; FIG. 10 is a diagram showing the contents of information set in a status register T and a status register R provided in a status monitoring circuit in the asynchronous serial communication circuit of the third gaming machine according to the present embodiment; FIG. 12 is a block diagram showing the internal configuration of the HB-LSI random number generation circuit used in the third gaming machine according to the present embodiment; It is a block diagram showing the internal configuration of the main control board of the third gaming machine according to the present embodiment. FIG. 11 is a block diagram showing the internal configuration of the reel device board of the third gaming machine according to the present embodiment; It is a block diagram showing the internal configuration of the door relay board of the third gaming machine according to the present embodiment. It is a block diagram which shows the internal structure of the sub-control part of the 3rd game machine which concerns on this embodiment. It is a figure which shows the transmission aspect of the command data between the main-control part and sub-control part of the 3rd gaming machine based on this embodiment. It is a diagram showing a modification of the mode of transmission of command data between the main control unit and the sub-control unit of the third gaming machine according to the present embodiment. FIG. 12 is a diagram showing a configuration example of command data transmitted from the main control section to the sub control section in the third gaming machine according to the present embodiment; FIG. 11 is a diagram for explaining an overview of DLE control performed on command data transmitted from the main control section to the sub-control section in the third gaming machine according to the present embodiment; In the third gaming machine according to the present embodiment, it is a diagram showing a configuration example of command data when DLE control is not performed on command data transmitted from the main control section to the sub-control section. In the third gaming machine according to the present embodiment, it is a diagram showing a configuration example of command data when DLE control is performed on command data transmitted from the main control section to the sub-control section. It is a flowchart which shows an example of the communication data storage process performed by the main-control part of the conventional gaming machine. FIG. 10 is a flow chart showing Example 1 of communication data storage processing executed by the main control unit of the third gaming machine according to the present embodiment; FIG. FIG. 13 is a flow chart showing Example 2 of communication data storage processing executed by the main control unit of the third gaming machine according to the present embodiment; FIG. FIG. 10 is a diagram showing a configuration example 1 of data transmitted between boards in the main control unit in the third gaming machine according to the present embodiment; FIG. 10 is a diagram showing a configuration example 2 of data transmitted between boards in the main control unit in the third gaming machine according to the present embodiment; It is a figure which shows the external structure of the 4th gaming machine based on this embodiment. It is a front view of the state where the front panel of the fourth gaming machine according to the present embodiment is removed. It is an LED arrangement port diagram of the fourth gaming machine according to the present embodiment. It is a figure which shows the internal structure of the 4th gaming machine based on this embodiment. It is a block diagram showing the overall configuration of the circuit provided in the fourth gaming machine according to the present embodiment. It is a block diagram showing an internal configuration of a sub-control circuit of the fourth gaming machine according to the present embodiment. FIG. 10 is a diagram showing a connection form between an LED driver IC used in a fourth gaming machine according to the present embodiment and each 7-segment LED in a seventh lamp group; FIG. 11 is a diagram showing another configuration example of a 7-segment LED that can be used in the fourth gaming machine according to this embodiment; FIG. 10 is a diagram showing a connection form between an LED driver IC and each 7-segment LED in a seventh lamp group in a comparative example (static control); FIG. 11 is a diagram showing a configuration (part 1) of a lamp buffer provided in a sub microprocessor in the fourth gaming machine according to the present embodiment; FIG. 20 is a diagram showing the configuration (part 2) of a lamp buffer provided in the sub microprocessor in the fourth gaming machine according to the present embodiment; FIG. 20 is a diagram showing the configuration of anode selection data and segment data stored in corresponding areas in the lamp buffer when dynamically controlling the seventh lamp group in the fourth gaming machine according to the present embodiment; FIG. 12 is a diagram showing the configuration of data stored in a buffer area of 1-byte units constituting a ramp buffer in the fourth gaming machine according to the present embodiment; It is a correspondence table of brightness and PWM values used in the fourth gaming machine according to the present embodiment. In the fourth gaming machine according to the present embodiment, it is a diagram showing a configuration example of segment data when brightness adjustment is performed on the cathodes of each 7-segment LED in the 7th lamp group. In the fourth gaming machine according to the present embodiment, it is a diagram showing a configuration example of anode selection data when brightness adjustment is performed on the anodes of each 7-segment LED in the 7th lamp group. 14 is a flowchart of power-on processing performed by the sub CPU of the fourth gaming machine according to the present embodiment; It is a flowchart of a main board communication task performed by the sub CPU of the fourth gaming machine according to the present embodiment. It is a flow chart of the effect registration task performed by the sub CPU of the fourth gaming machine according to the present embodiment. 14 is a flowchart of effect content determination processing performed by a sub CPU of the fourth gaming machine according to the present embodiment; 14 is a flowchart of a lamp control task performed by the sub CPU of the fourth gaming machine according to the present embodiment; 14 is a flowchart of ramp effect data reading processing performed by the sub CPU of the fourth gaming machine according to the present embodiment; 14 is a flowchart showing interrupt control processing performed by a sub CPU of the fourth gaming machine according to the present embodiment; 14 is a flowchart showing 7-segment data generation processing performed by the sub CPU of the fourth gaming machine according to the present embodiment; 14 is a flowchart showing 7-segment data registration processing performed by the sub CPU of the fourth gaming machine according to the present embodiment; It is a block diagram showing the configuration of the sub-control circuit of the fifth gaming machine according to the present embodiment. FIG. 11 is a schematic diagram showing a menu screen of a fifth gaming machine according to the present embodiment; FIG. 14 is a schematic diagram showing a volume setting mode of the fifth gaming machine according to the present embodiment; FIG. 20 is an image diagram of design specifications regarding setting of a volume adjustment range by the hall side of the fifth gaming machine according to the present embodiment; FIG. 20 is a schematic explanatory diagram showing a screen in a state where a player can select a sound volume level of the fifth gaming machine according to the present embodiment; FIG. 20 is a schematic explanatory diagram showing a sound volume level setting screen by the player side of the fifth gaming machine according to the present embodiment; FIG. 20 is a diagram for explaining an operation method for collectively setting the volume levels of a plurality of categories in the fifth gaming machine according to the present embodiment; FIG. 20 is a diagram for explaining an operation method for individually setting volume levels for a plurality of categories in the fifth gaming machine according to the present embodiment; FIG. 4 is a diagram showing an example of a guide initial image displayed on a main screen and a guide menu screen displayed on a sub screen in one embodiment of the present invention; FIG. 10 is a diagram showing a state in which a finger touches the guide menu “arrangement/dividend” on the guide menu screen displayed on the sub-screen according to the embodiment of the present invention; FIG. 10 is a diagram showing a state in which a finger touches the guide menu “start Unimemo” on the guide menu screen displayed on the sub-screen according to the embodiment of the present invention; FIG. 4 is a diagram showing an example of a Unimemo initial image displayed on a main screen and a Unimemo menu screen displayed on a sub screen in one embodiment of the present invention; FIG. 10 is a diagram showing an example of a password display image displayed on the main screen and a password input menu screen displayed on the sub screen in one embodiment of the present invention, showing a state in which a finger is touching the password input menu "E"; It is a diagram. FIG. 10 is a diagram showing an example of a password display image displayed on the main screen and a password input menu screen displayed on the sub screen in one embodiment of the present invention, showing a state in which a finger is touching the password input menu "F"; It is a diagram. FIG. 10 is a diagram showing a state in which “F” related to detection of selection is displayed on the password display image displayed on the main screen in one embodiment of the present invention; FIG. 10 is a diagram showing another example of the password display image (password input area) and the password input menu screen (keyboard display area) displayed on the main screen in one embodiment of the present invention, showing a state in which all passwords have been input; FIG. 4 is a diagram showing; FIG. 10B is a diagram showing another example of the password display image (password input area) and the password input menu screen (keyboard display area) displayed on the main screen in one embodiment of the present invention, in which part of the password is not input; It is a figure which shows a state. FIG. 4B is an enlarged view of the password display image (password input area) displayed on the main screen in one embodiment of the present invention, and is a diagram for explaining the transition of the display mode. FIG. 4B is an enlarged view of the password display image (password input area) displayed on the main screen in one embodiment of the present invention, and is a diagram for explaining the transition of the display mode. FIG. 4B is an enlarged view of the password display image (password input area) displayed on the main screen in one embodiment of the present invention, and is a diagram for explaining the transition of the display mode. FIG. 4 is a diagram showing an example of a character customization screen in one embodiment of the present invention; FIG. 4 is a diagram illustrating various data related to character customization in one embodiment of the present invention; FIG. 2 is a diagram explaining an overview of data delivery between a gaming machine and a server in one embodiment of the present invention;

A gaming machine according to the present embodiment will be described below with reference to the drawings. In this embodiment, a pachislot machine will be described as an example of a game machine.

[1. Structure of pachislot machine]
First, the structure of the pachi-slot machine 1 will be described with reference to FIGS. 1 and 2. FIG. 1 shows the external structure of the pachi-slot machine 1, and FIG. 2 shows the internal structure of the pachi-slot machine 1. As shown in FIG. Also, for convenience of explanation, the following description of the external structure may include a portion of the internal structure, and the description of the internal structure may include a portion of the external structure.

[1-1. External structure]
[1-1-1. Housing]
A pachi-slot machine 1 is composed of a rectangular box-shaped housing 2 . The housing 2 includes a metal cabinet G having a rectangular opening on the front side as a game machine main body, an upper door mechanism UD arranged in the upper front part of the cabinet G, and a lower front part of the cabinet G. and a lower door mechanism DD.

The cabinet G has an intermediate support plate G1, a pair of left and right side walls G2, a rear wall G3, a top wall G4, and a bottom wall G5. In addition, in FIG.1 and FIG.2, illustration of the back wall G3 and the bottom wall G5 is abbreviate|omitted. In addition, two openings G4a are formed in the upper surface wall G4 of the cabinet G so as to penetrate in the vertical direction at a predetermined interval in the horizontal direction. A wooden plate member G4b is attached to the top wall G4 so as to block the two openings G4a.

The plate member G4b is used to fix the pachi-slot machine 1 to a game island (not shown) when it is installed in the amusement arcade. or integrally formed with the top wall G4. Moreover, as long as a certain strength is ensured for the cabinet G, a part or all of each component can be made of wood or resin material.

Inside the cabinet G, an upper opening G101 is formed that opens forward with the intermediate support plate G1 interposed therebetween. A side opening G102 is formed. That is, the interior of the cabinet G is partitioned into an upper space and a lower space with an intermediate support plate G1 interposed therebetween, and the intermediate support plate G1 functions as a partition plate that partitions the interior of the cabinet G into the upper space and the lower space. there is The upper space is a space on the rear side of the upper door mechanism UD inside the cabinet G, and accommodates a main display device 210 and the like, which will be described later. The lower space is a space on the rear side of the lower door mechanism DD inside the cabinet G, and accommodates a reel unit RU, a main control board 71, and the like, which will be described later.

Note that the cabinet G does not necessarily have to include the intermediate support plate G1. That is, as long as each device and the like can be properly accommodated in the cabinet G, the upper space and the lower space may not be partitioned. Further, the cabinet G can be simply referred to as a "box" or "main body", and functions as a frame for supporting or fixing the upper door mechanism UD and the lower door mechanism DD. It can also be referred to as a "support", "support frame", or "fixed frame".

[1-1-2. front door]
The upper door mechanism UD and the lower door mechanism DD are formed so as to correspond to the shape and size of the opening of the cabinet G, and are provided so as to be able to block the upper and lower spaces of the opening in the cabinet G. As shown in FIG. That is, the upper door mechanism UD and the lower door mechanism DD function as front doors provided on the front side of the pachi-slot machine 1 .

Each of the upper door mechanism UD and the lower door mechanism DD is attached to the cabinet G so as to be openable and closable, for example, by an opening/closing mechanism (not shown) such as a hinge provided on the left side wall G2. Either one of the upper door mechanism UD and the lower door mechanism DD can be opened and closed by the opening/closing mechanism described above, and the other can be attached and detached only when one of the door mechanisms is in an open state. can also

The upper door mechanism UD has an effect display window UD1 provided in its central portion and an upper lamp 23 provided above the effect display window UD1. The effect display window UD1 is configured as, for example, a transparent panel made of resin, and enables visual recognition of the effect image displayed on the screen device C constituting the main display device 210, which will be described later, provided on the rear side thereof. Note that, in this embodiment, the main display device 210 that performs the effect display through the effect display window UD1 may be described as the main effect display section 21 in some cases.

The lower door mechanism DD has a main display window 4 provided substantially in the center of its upper portion, and a reel unit RU attached to the inside of the cabinet G behind the main display window 4. there is

The reel unit RU is mainly composed of three reels 3L (left reel), 3C (middle reel), and 3R (right reel). Each of the reels 3L, 3C, and 3R is composed of, for example, a cylindrically formed reel body and a translucent reel band attached to the peripheral surface of the reel body. ) are drawn at predetermined intervals along the direction of rotation of the reel. The reels 3L, 3C, and 3R are arranged in parallel (in a horizontal row) so that they can rotate vertically at a constant speed. The main display window 4 is configured as, for example, a transparent panel made of resin, and allows at least a portion (for example, three) of the symbols on the peripheral surfaces of the reels 3L, 3C, and 3R to be visible. Further, inside each of the reels 3L, 3C, and 3R, a light source (a reel lamp included in lamps and LEDs, which will be described later) is provided at a position where at least the pattern can be viewed through the main display window 4. At least each reel 3L, 3C, and 3R When 3C and 3R are rotating, they are illuminated from the inside with a constant luminance to ensure the visibility of the pattern.

Further, the lower door mechanism DD has a sub effect display section 22 provided on the left side of the main display window 4 and a effect button 10b provided on the right side of the main display window 4 . The sub effect display section 22 displays the effect image displayed on the sub display device 220 which will be described later. It should be noted that the sub-rendering display section 22 can be configured as a touch panel so that it functions not only as a function of displaying a performance, but also as one of the buttons for performance. The effect button 10b is an operation unit that receives a player's operation for effect (effect operation).

In addition, the lower door mechanism DD is provided substantially in the center of the substantially horizontal pedestal formed below the main display window 4, with the MAX bet button 6a, the 1 bet button 6b, and the checkout button 9 provided on the left side. and a medal slot 5 provided on the right side.

The MAX bet button 6a and the 1 bet button 6b are the player's game operations (betting operations, "insertion operations" and "betting operations") for using the medals deposited (credited) inside the pachislot machine 1. ”, etc.). When the MAX bet button 6a is operated, if the current bet number is less than the maximum bet number (for example, 3) and the number of credited medals is equal to or greater than the difference, the maximum bet number of medals is bet. be. On the other hand, if the credited medals are less than the difference, no medals are bet. Further, when the 1 bet button 6b is operated, if the current bet number is less than the maximum bet number and there is one or more credited medals, one medal is bet.

The settlement button 9 is an operation unit that receives a game operation (settlement operation) of the player for returning credited medals (settlement). If the payment button 9 is operated while there are no credited medals, the medals to be inserted or paid out will be credited within the creditable number (for example, 50). A player's game operation (C/P mode selection operation) for enabling selection of either a mode (C mode) or a pay mode (P mode) in which the medals are not credited may be accepted. That is, the settlement button 9 can also function as a so-called C/P button. The effect button 10a is an operation unit that receives a player's operation for effect (effect operation).

The medal slot 5 accepts medals that are thrown into the pachi-slot machine 1 from the outside by a player. The received medals are detected by the selector 31, which will be described later, and it is determined whether or not they are proper medals. If the one received medal is not proper, the received medal is returned from a medal payout port 11, which will be described later. Also, if the accepted one medal is correct, and if the current bet number is less than the maximum bet number, one medal is bet. If the current number of bets is the maximum number of bets and the credited medals have not reached the creditable number, one medal is credited. On the other hand, when the credited medals have reached the creditable number, the received medals are returned from the medal payout port 11, which will be described later.

Further, the lower door mechanism DD has an information display device 14 provided between the main display window 4 and the above-described pedestal. The information display device 14 includes a plurality of lamps (LEDs) and 7-segment LEDs, and displays information about the game according to lighting modes thereof.

Further, the lower door mechanism DD includes a start lever 7 provided on the left side, three stop buttons 8L, 8C, and 8R provided substantially in the center and a and a locking mechanism 15 . The start lever 7 is an operation unit which is attached so as to be tiltable within a predetermined angle range and receives a game operation (start operation) by the player for starting a game. Each stop button 8L, 8C, 8R is provided corresponding to each reel 3L, 3C, 3R, and is an operation unit that receives a game operation (stop operation) by the player for stopping the rotation of each reel.

The locking mechanism 15 is composed of, for example, a key cylinder lock, and when the lower door mechanism DD is in the closed state, a manager on the amusement arcade side (for example, an amusement arcade clerk, etc.; the same shall apply hereinafter) inserts a door key (not shown) into the keyhole. ) is inserted and turned to the right to unlock, and the lower door mechanism DD is opened. Note that the locking mechanism 15 may have a function as a reset switch as well as a function to manage opening and closing of the door mechanism. For example, when an amusement arcade manager inserts a door key into a keyhole and turns it to the left, it may be possible to detect a reset operation similar to the reset switch 53 described later. Further, in this embodiment, when the lower door mechanism DD is opened, the upper door mechanism UD can also be opened in conjunction therewith. A separate mechanism may be provided so that the opening and closing can be managed independently.

In addition, the lower door mechanism DD includes a waist panel 13 provided in the center of its lower portion, a medal receiving tray 12 provided below the waist panel 13, and a medal dispensing opening 11 provided above the medal receiving tray 12. , and sound transmission holes 24 a and 24 b provided on the left and right sides of the medal payout port 11 .

The waist panel 13 includes, for example, a decorative panel on which model information such as a logo representing the name of the model or a character representing a motif is drawn, and a light source for illuminating the decorative panel from the back side (such as lamps and LEDs, which will be described later). lumbar ramp included). The medal tray 12 stores medals paid out from the medal payout port 11. - 特許庁The medal pay-out port 11 discharges medals paid out (or returned) from the inside of the pachi-slot machine 1 to the outside. The medals discharged from the medal pay-out port 11 include those paid out from a hopper device 32 described later and those returned from a selector 31 described later through a cancel chute (not shown). The sound transmission holes 24a and 24b are located on the back sides of the respective speakers 35a and 35b (the speaker 35a is omitted in FIG. 2) mounted inside the cabinet G. is transmitted toward the front side of the pachi-slot machine 1.

In this embodiment, an upper door mechanism UD and a lower door mechanism DD are provided in correspondence with the fact that the inside of the cabinet G is divided into an upper space and a lower space. As long as it can be opened and closed, it can be configured as a single door mechanism, or it can be configured as three or more door mechanisms. Moreover, it can also be configured as a double door mechanism (for example, an outer door and an inner door) in the front-rear direction. Further, the upper door mechanism UD and the lower door mechanism DD can be simply referred to as "doors" or "doors", and since they function as members capable of opening and closing the opening in the cabinet G, they can be referred to as "opening/closing members" or "doors." It can also be called a "member", or a "door member" or the like.

[1-1-3. Fluctuation display]
As described above, the pachi-slot machine 1 has the reels 3L, 3C, 3R and the main display window 4. As shown in FIG. When the start lever 7 is operated (when the player performs a start operation), the reels 3L, 3C and 3R start rotating by driving and controlling stepping motors 51L, 51C and 51R, which will be described later. As a result, the pattern displayed on the main display window 4 is displayed in a variable manner. When the respective stop buttons 8L, 8C, 8R are operated (when the player performs a stop operation), stepping motors 51L, 51C, 51R, which will be described later, are driven and controlled for the reels 3L, 3C, 3R. to stop each rotation. As a result, the symbols displayed in the main display window 4 are stopped and displayed.

That is, each of the reels 3L, 3C, 3R and the main display window 4 has a variable display section (means) capable of variably displaying (and stopping) a plurality of symbols in a plurality of rows, or a variable displaying (and stopping) display of a plurality of symbols. ) constitute a possible plurality of variable display units (means). The variable display section (means) can also be referred to as a "symbol display section (means)" or a "variable display section (means)". The pattern can also be referred to as a "picture" or "pattern", or as long as it is information visually identifiable by the player, it can also be referred to as "identification information" in that sense.

Further, the main display window 4 is constructed so that when the rotation of each of the reels 3L, 3C, and 3R is stopped, three symbols arranged consecutively are displayed within the frame. That is, the main display window 4 displays one pattern (three in total) in each of the upper, middle, and lower regions of each column (the frame of the main display window 4 displays 3 rows x 3 columns). The pattern is displayed in the form of ). Note that the main display window 4 is sometimes referred to as a "design display area", a "window", or the like.

A valid line is defined in the main display window 4 . The effective line is a line for determining whether or not a prescribed combination of symbols is displayed when symbols of all rows are stopped and displayed in response to a player's stop operation. In that sense, the activated line can also be referred to as a "win line" or a "decision line". Also, the effective line is configured as a line connecting any of the regions of each column. That is, when the main display window 4 is configured to display patterns in the form of 3 rows×3 columns, it is possible to define a maximum of 27 effective lines. However, in practice, one or more of the lines can be defined as valid lines, and the other lines can be defined as invalid lines that are not valid lines.

For example, the line connecting the middle area of the reel 3L, the middle area of the reel 3C, and the middle area of the reel 3R is the "center line", the upper area of the reel 3L, the upper area of the reel 3C, and the upper area of the reel 3R. The connecting line is the "top line", the line connecting the lower area of the reel 3L, the lower area of the reel 3C, and the lower area of the reel 3R is the "bottom line", the lower area of the reel 3L, the middle area of the reel 3C, and the reel 3R. A line connecting the upper area is called a "cross-up line", and a line connecting the upper area of the reel 3L, the middle area of the reel 3C, and the lower area of the reel 3R is called a "cross-down line". One or more of these lines are often defined as effective lines because they are lines that connect each area in a straight line. However, as described above, a so-called irregular line that connects each region of each column with a polygonal line can also be defined as an effective line.

In addition, in order for the activated line to be activated, it is necessary to bet the required amount of medals for the current game (the number of medals that can be used to start the game) prior to the player's start operation. The number of activated lines to be converted may be the same regardless of the number of bets, or may vary according to the number of bets. For example, assuming that the above-mentioned three lines of "center line", "top line", and "bottom line" are defined as active lines, in the case of the former, the number of bets is any of 1 to 3. Even if the 'center line', 'top line', and 'bottom line' are enabled. On the other hand, in the latter case, if the number of bets is 1, only "center line" is activated, and if the number of bets is 2, "center line" and "top line" are activated, and the number of bets is 3. If (maximum number of bets), "center line", "top line" and "bottom line" are enabled.

In this embodiment, the variable display section has three reels 3L, 3C, and 3R, and a main display window 4 capable of displaying three symbols in each column. Although the symbols are displayed in the form of columns, the pattern display form in the variable display section is not limited to this. For example, the number of reels is set to 1, 2, or 4 or more, and, for example, the number of symbols displayed in each row is set to 1, 2, or 4 or more. You can also display the pattern with . In this case, the number of valid lines that can be defined also increases or decreases as appropriate.

Further, in the present embodiment, the variable display section variably displays the symbols by rotating the reels 3L, 3C, and 3R, but the configuration of the variable display section is not limited to this. For example, a configuration using an image display device similar to the main display device 210 and the sub-display device 220, which will be described later, may be used, or a configuration using other display devices (eg, organic EL, 7-segment LED, etc.) may be used. . Also, for example, a configuration using other physical devices (for example, a belt or the like) may be used. Also, the arrangement, size, etc. of the variable display section can be changed as appropriate.

Further, in the present embodiment, the variable display section functions as a main side display section that is directly related to the game and is controlled by the main control circuit 100, which will be described later. A variable display section may be provided as a sub-side display section related to an effect not directly related to the game, which is controlled by the game. Note that the sub-side display section can be configured using the main display device 210 and the sub-display device 220, for example. That is, a variable display unit that variably displays symbols in accordance with a player's start operation (or other start conditions are met), and stops and displays symbols in response to a player's stop operation (or other stop conditions are met). As such, not only the main side display section but also the sub side display section may be provided. In this case, in order to allow the player to identify whether or not the variable display section is directly related to the game, characters such as "pachislot" or "main reel" are displayed near the main side display section. It is sufficient that an identification mark indicating is attached so that it is possible to identify that the variable display portion is the main side display portion. Note that such an identification display may be displayed on the main display device 210 or the sub display device 220 .

[1-1-4. Medal slot]
As described above, the pachi-slot machine 1 includes the medal slot 5 for receiving medals inserted into the pachi-slot machine 1 from the outside by the player. Note that the medal slot 5 and a selector 31, which will be described later, have the function of betting the number of medals required for one game, like the MAX bet button 6a and the 1 bet button 6b. , for example, can be rephrased as a bet operation. Therefore, it can be said that the medal slot 5 is a betting operation detection unit (means) capable of detecting the player's betting operation. The shape, arrangement, size, etc. of the medal slot can be changed as appropriate. Also, when the pachi-slot machine 1 is configured as a medalless game machine, which will be described later, this configuration is not necessarily essential.

In the present embodiment, as an example of the game value that is used in the game or given according to the game result, medals are used as game media. It is not limited to this. For example, coins, game balls, game point data or tokens, etc. may be used. Also, the game value can be simply referred to as "value" or "game value".

[1-1-5. Operation part]
The pachi-slot machine 1 includes, for example, the following operation units as operation units that can be operated by the player. It should be noted that each operation unit shown below is merely an example, and may be configured to include an operation unit different from these, or may be configured not to include an operation unit that is not necessarily essential among these. .

[1-1-5-1. bet button]
As described above, the pachi-slot machine 1 is provided with the MAX bet button 6a and the 1 bet button 6b for receiving a player's bet operation for using medals deposited (credited) therein. Also, such a bet operation is detected by a bet switch 6S, which will be described later. Therefore, the MAX bet button 6a, the 1 bet button 6b, and the bet switch 6S constitute a bet operation detection section (means) capable of detecting the player's bet operation. It should be noted that the bet button only needs to be capable of detecting the player's betting operation, and its shape, arrangement, size, and the like can be changed as appropriate. Further, although the MAX bet button 6a and the 1-bet button 6b are provided in this embodiment, only the MAX bet button 6a may be provided without providing the 1-bet button 6b. Also, a 2-bet button for betting two medals may be provided separately.

[1-1-5-2. start lever]
As described above, the pachi-slot machine 1 has a start lever 7 for receiving a player's start operation for starting a game. Also, such a start operation is detected by a start switch 7S, which will be described later. Therefore, the start lever 7 and the start switch 7S constitute a start operation detection section (means) capable of detecting the player's start operation. It should be noted that the start lever only needs to be able to detect the player's start operation, and its shape, arrangement, size, and the like can be changed as appropriate.

[1-1-5-3. stop button]
As described above, the pachi-slot machine 1 is provided with respective stop buttons 8L, 8C, 8R which are provided corresponding to the respective reels 3L, 3C, 3R and which receive a player's stop operation for stopping the respective rotations. Moreover, such a start operation is detected by a stop switch 8S, which will be described later. Therefore, each of the stop buttons 8L, 8C, 8R and the stop switch 8S constitute a stop operation detector (means) capable of detecting the player's stop operation. It should be noted that the stop button only needs to be able to detect the player's stop operation, and its shape, arrangement, size, and the like can be changed as appropriate.

[1-1-5-4. Settlement button]
As described above, the pachi-slot machine 1 includes the checkout button 9 for accepting the player's checkout operation (return operation) for returning (checkout) credited medals. Further, such a settlement operation is detected by a settlement switch 9S, which will be described later. Therefore, the settlement button 9 and the settlement switch 9S constitute a settlement operation detection section (means) capable of detecting the settlement operation of the player. It should be noted that the checkout button only needs to be able to detect the checkout operation of the player, and its shape, arrangement, size, and the like can be changed as appropriate.

[1-1-5-5. production button]
As described above, the pachi-slot machine 1 is provided with effect buttons 10a and 10b for receiving the player's effect operations. Incidentally, such an effect operation is detected by a detection switch (not shown) provided corresponding to each effect button. Therefore, the effect buttons 10a and 10b and the detection switch constitute a effect operation detection section (means) capable of detecting the effect operation of the player. It should be noted that the effect button only needs to be able to detect the player's effect operation, and its shape, arrangement, size, and the like can be changed as appropriate. In addition, in this embodiment, two production buttons 10a and 10b are provided, but it is possible to configure without providing either of them, or to provide only one of them. can. Also, it can be configured to provide three or more production buttons.

The main uses of the production buttons are to change the production mode when executing a specific production (for example, an operation-linked production described later), and to perform a selection/decision operation in the user menu described later. Therefore, it is also possible to provide a presentation button according to the application. For example, for the former purpose, the production buttons 10a and 10b are used, and for the latter purpose, the above-described touch panel may be used. For use in the latter application, a jog dial, a cross key, or the like that can accept selection/decision operations can be provided as separate effect buttons.

[1-1-6. medal outlet]
As described above, the pachi-slot machine 1 has the medal payout port 11 for discharging medals paid out (or returned) from inside the pachi-slot machine 1 to the outside. When a prize is won and medals are paid out, the medal payout port 11 gives the player the medals paid out from the hopper device 32, which will be described later. It can be said that it is part of the means. Also, the shape, arrangement, size, etc. of the medal payout port can be changed as appropriate. Also, when the pachi-slot machine 1 is configured as a medalless game machine, which will be described later, this configuration is not necessarily essential.

[1-1-7. Medal tray]
As described above, the pachi-slot machine 1 includes the medal receiving tray 12 for storing medals paid out from the medal payout port 11 . That is, the medal receiving tray 12 constitutes a storage section (means) capable of storing the given game value. Note that the shape, arrangement, size, etc. of the medal receiving tray can be changed as appropriate. Also, when the pachi-slot machine 1 is configured as a medalless game machine, which will be described later, this configuration is not necessarily essential.

[1-1-8. waist panel]
As described above, the pachi-slot machine 1 includes, for example, a decorative panel on which model information is drawn and a waist panel 13 composed of a waist lamp for illuminating the decorative panel from the back side. The waist panel 13 basically indicates to the player what kind of model the pachislot machine 1 is. can also be configured as one of the effect executing means capable of executing the effect by configuring with an image display device or the like.

[1-1-9. Information display]
As described above, the pachi-slot machine 1 is provided with the information display device 14 that displays game-related information by its lighting mode. In other words, the information display device 14 constitutes an information display section (means) capable of displaying information about games.

The information display device 14 includes, for example, an insert lamp, a start lamp, a replay lamp, a bet number lamp, a credit lamp, a payout number lamp, an instruction monitor, a limit lamp, and the like.

The insert lamp lights up to indicate that medals can be inserted. The start lamp indicates that the game can be started by operating the start lever 7 by turning on the start lamp. The replay lamp lights to indicate that medals have been automatically inserted due to the operation of the replay. The bet number lamp lights up to display the number of medals bet. The credit lamp displays the number of credited medals according to its lighting mode. The number-of-payouts lamp displays the number of medals (number of payouts) paid out according to the game result by its lighting mode.

Further, the instruction monitor includes a notification lamp (stop operation display section) and a section lamp (state display section). The notification lamp lights up in a manner uniquely corresponding to the information of the stop operation to be notified under a situation (for example, AT state) in which the information of the stop operation is notified to the player, so that the information of the stop operation is displayed. display. It should be noted that the "mode uniquely corresponding to the information of the stop operation to be notified" is, for example, the pressing order (in the present embodiment, this may be described as the "batting order"), the 1st (the first stop operation is In the case of announcing "2nd (perform the first stop operation to the reel 3C)", the numerical value "1" is displayed on the instruction monitor. displays the numerical value "2" on the instruction monitor, and displays the numerical value "3" on the instruction monitor when notifying the pushing order "3rd (performing the first stop operation to the reel 3R)". It's about. Note that the notification lamp may not necessarily be provided separately from the credit lamp and the payout number lamp. For example, either a credit lamp or a payout lamp may be used to display stop operation information.

As described above, in the present embodiment, in a situation where the information of the stop operation is notified to the player, the sub-side notification means (for example, the main effect display section 21) controlled by the sub-control circuit 200, which will be described later. In addition, the information of the stop operation is notified also by the instruction monitor as the main side notification means controlled by the main control circuit 100 which will be described later. The manner of notification by the main-side notification means and the manner of notification by the sub-side notification means may be different from each other. That is, the main-side notification means may perform notification in a manner that uniquely corresponds to the information on the stop operation to be notified, and does not necessarily need to directly notify the information on the stop operation. For example, in the case of announcing the pressing order "1st", even if the indication monitor displays the numerical value "1", there is a possibility that the content of the notification cannot be specified depending on the player. On the other hand, the sub-side notification means may directly notify the information of the stop operation. For example, when informing the pressing order "1st", the main effect display section 21 may directly inform the instruction information for performing the first stop operation on the reel 3L.

In addition, the section lamp indicates that the current state is in an advantageous section, which will be described later, by turning on. For example, when transitioning from a non-advantageous section described later to an advantageous section, the section lamp lights up at an arbitrary timing until the game in the advantageous section starts, and the advantageous section ends and shifts to the non-advantageous section. , the lights are turned off at an arbitrary timing until the game in the non-advantageous section is started. Note that the lighting timing of the section lamp is not limited to this. For example, when the production section (normal advantageous section) described later in the non-advantageous section or the advantageous section first shifts to the increased section (AT state) described later in the advantageous section, any time until the game in the increased section is started It is good also as what lights up at timing. That is, the section lamp may indicate that it is in an advantageous section regardless of whether it is a production section or an increase section, or at least the advantageous section including this from the start of the first increase section It may be one that informs the period until the end of.

In addition, the limit lamp indicates that the limit processing described below has been executed or the possibility thereof, depending on its lighting mode. For example, when the limit process is executed, the lighting informs the player that a state advantageous to the player (for example, the AT state) has been forcibly terminated by the execution of the limit process. In addition, for example, when the execution of the limit process is near, by blinking, it is reported that there is a high possibility that the advantageous state will be forcibly terminated by the execution of the limit process. In addition to these, other information related to the limit processing can be appropriately notified by providing a trigger for lighting, blinking, or extinguishing.

[1-1-10. Effect display section]
As described above, the pachi-slot machine 1 includes the main effect display section 21 and the sub-effect display section 22 that display effect images. The main effect display portion 21 and the sub effect display portion 22 constitute a effect display portion (means) capable of performing effect display. Also, it is configured as one of the effect executing means capable of executing a visual effect for the player.

The main effect display unit 21 includes a main display device 210 that displays effects through the effect display window UD1. The main display device 210 includes a display unit A replaceably mounted on an intermediate support plate G1 in the cabinet G, an irradiation unit B for emitting irradiation light for image display, and irradiation from the irradiation unit B. It is configured as a so-called projection mapping device having a screen device C that makes an image appear by being irradiated with light. In the present embodiment, by configuring the main display device 210 in this way, it is possible to display an advanced and powerful effect, but the configuration of the main display device 210 is not limited to this. In other words, it is only necessary to be able to execute a visual effect for the player, and it can be configured as an image display device such as a liquid crystal display device or an organic EL device, a display device such as a 7-segment LED device, or a sub-reel device. It can also be configured as a variable display device or a dot display device. Moreover, from such a point of view, the shape, arrangement, size, and the like can be changed as appropriate. In addition, if the pachi-slot machine 1 is, for example, a type of game mainly focused on entertaining players with so-called winning numbers, the main effect display section 21 may not be provided (the sub-effect display section 22 as well).

The sub effect display section 22 is configured including a sub display device 220 . Also, the sub-display device 220 is configured as a liquid crystal display device. The sub-display device 220 can also be configured as another image display device or display device like the main display device 210, or can be configured as a variable display device or a dot display device. Moreover, from such a point of view, the shape, arrangement, size, and the like can be changed as appropriate. In addition, since the main effect display section 21 is composed of a large screen, it mainly displays effects closely related to the current game such as notification of pressing order, notification of winning, continuous effects, etc., and a sub-effect display section. 22 is composed of a small screen, it is possible to divide the display content according to the purpose, such as mainly displaying effects that are not so closely related to the current game, such as game history. It is possible. Further, in the present embodiment, two effect display portions, the main effect display portion 21 and the sub-effect display portion 22, are provided. It is also possible to configure so as to provide only one of them. Moreover, it is also possible to configure so as to provide three or more effect display sections.

[1-1-11. lamp]
As described above, the pachi-slot machine 1, like the upper lamp 23 given as an example, includes its light emission mode (lighting, blinking, or extinguishing, as well as its brightness and light emission color when configured as a full-color LED). ), one or more lamps (light emitting means) are provided. Further, such a light emitting means is configured as one of the effect executing means capable of executing a visual effect for the player. From this point of view, the number, shape, arrangement, size, and the like can be changed as appropriate.

Other lamps included in lamps and LEDs to be described later include, for example, side lamps provided on both side end surfaces of the upper door mechanism UD and both side end surfaces of the lower door mechanism DD, and operation units provided in each operation unit. A lamp etc. can be mentioned. The latter includes a function to notify the player whether or not each operation unit can be operated. , can be controlled to emit light according to a unique lighting mode.

[1-1-12. speaker]
As described above, the pachi-slot machine 1 includes speakers 35a and 35b for outputting sounds such as sound effects and BGM. The speakers 35a and 35b constitute audio output means capable of producing effects by outputting audio. In addition, it is configured as one of the effect execution means capable of executing the effect from an auditory point of view for the player. From this point of view, the number, shape, arrangement, size, and the like can be changed as appropriate.

[1-1-13. Other production equipment]
Incidentally, the pachi-slot machine 1 may be provided with an effect device other than the various effect devices (effect execution means) described above. For example, it is possible to provide effects such as a movable production device such as a so-called accessory, a vibration production device that produces production by vibration, or an air production device that produces production by injecting air. That is, an effect device capable of executing an effect that can appeal to any of the player's five senses (visual, auditory, tactile, taste, and olfactory) (allowing the player to recognize that the effect is being performed) Either of them can be used. Therefore, in the present embodiment, unless otherwise specified, "executing a production" means that one or more of the various production devices (production execution means) described above is used to produce a production. indicates that it is permissible to execute

[1-2. Internal structure]
[1-2-1. selector]
The selector 31 (not numbered in FIG. 2) is a downstream passage for medals inserted from the medal slot 5, and is provided on the back side of the lower door mechanism DD. The selector 31 has, for example, a medal sensor 31S, which will be described later, and a sorting device.

The medal sensor 31S detects medals inserted from the medal slot 5 and determines whether or not the detected medals are appropriate medals. When the medal sensor 31S determines that the detected medal is an appropriate medal, and the medal can be accepted, the sorting device sends the medal to the hopper device 32, which will be described later. It is driven and controlled so as to be guided. In this case, 1 is added to the number of bets or the number of credits. On the other hand, when the medal sensor 31S determines that the detected medal is not an appropriate medal, or when the medal is not ready to be accepted, the sorting device passes the medal through the cancel chute to the medal payout opening 11. is driven and controlled to be returned from A selector error occurs when an abnormality occurs in medal detection by the medal sensor 31S. In this case, the error state is canceled when the reset operation is performed after eliminating the cause of the abnormality (for example, medal jam).

That is, the selector 31 constitutes a game medium detection unit (means) capable of detecting the inserted game medium. In addition, the selector 31 constitutes a judgment means capable of judging whether or not the inserted game medium is proper. Further, the selector 31 constitutes a sorting means for storing inside when the inserted game media are correct, and discharging them to the outside when the inserted game media are not correct. Also, the configuration, arrangement, size, etc. of the selector 31 can be changed as appropriate. Also, when the pachi-slot machine 1 is configured as a medalless game machine, which will be described later, this configuration is not necessarily essential.

[1-2-2. Hopper device]
The hopper device 32 is provided in the lower space inside the cabinet G. As shown in FIG. The hopper device 32 includes, for example, a bucket section for storing medals inserted from the medal slot 5 and guided by the selector 31, and a bottom section of the bucket section for agitating the medals stored in the bucket section. It has a disc portion that guides the medals to the discharge portion one by one, a discharge portion that discharges the medals guided by the disc portion one by one, and a count sensor that counts the medals discharged from the discharge portion.

The bucket section is configured to be able to store a fixed number of medals. Medals exceeding a certain number are guided to a medal auxiliary storage box 33, which will be described later, through a guide passage provided on the upper surface side. A hopper empty error occurs when the medals stored in the bucket become empty. In this case, after replenishing medals, the error state is released when the reset operation is performed.

The disc portion has a plurality of medal-shaped cutouts radially formed from the center, and the central shaft is rotated according to a drive signal to guide the medals fitted in the cutouts one by one to the discharge portion. Note that the medals stored in the bucket section are agitated by the rotation of the disk section. Also, when an abnormality occurs in the rotation of the disk portion, a hopper jam error occurs. In this case, the error state is canceled when the reset operation is performed after eliminating the cause of the abnormality (for example, medal jam).

The count sensor detects the medals discharged from the discharge section and counts the number of medals. For example, when one medal is to be paid out, the disc portion starts rotating, and then the rotation of the disc portion stops when the count sensor counts the payout of one medal. In this manner, an appropriate number of medals are paid out.

That is, the hopper device 32 constitutes a game medium payout section (means) capable of paying out game media. Also, as described above, it can be said that it is a part of privilege giving means for giving a privilege to the player. Also, the configuration, arrangement, size, etc. of the hopper device 32 can be changed as appropriate. Also, when the pachi-slot machine 1 is configured as a medalless game machine, which will be described later, this configuration is not necessarily essential.

[1-2-3. Auxiliary storage for medals]
The medal auxiliary storage box 33 is provided in the lower space inside the cabinet G. The medal auxiliary storage box 33 is, for example, a storage unit for storing medals guided from the bucket unit of the hopper device 32, and a medal auxiliary storage unit provided near the storage unit for detecting the capacity of the medals stored in the storage unit. It has a storage switch 33S.

The storage section is configured to be able to store a certain number of medals. When it is determined by the medal auxiliary storage switch 33S that the predetermined number or more of medals have been stored, an auxiliary medal storage error occurs. In this case, the error state is released when the reset operation is performed after reducing the number of medals stored in the storage section to at least less than a certain number.

That is, the auxiliary medal storage box 33 constitutes a surplus game medium storage section (means) capable of storing surplus game media. The configuration, arrangement, size, etc. of the medal auxiliary storage box 33 can be changed as appropriate. Also, when the pachi-slot machine 1 is configured as a medalless game machine, which will be described later, this configuration is not necessarily essential.

[1-2-4. power supply]
The power supply device 34 is provided in the lower space inside the cabinet G. As shown in FIG. The power supply device 34 has, for example, a power board 34a and a power switch 34b, and supplies power to the pachi-slot machine 1 when the power switch 34b is turned on. The power supply device 34 converts AC voltage power of 100 V supplied from a power cable (not shown) into power of DC voltage required for each part, and supplies the converted power to each part. do. In other words, the power supply device 34 constitutes a power supply unit (means) capable of supplying necessary power to the gaming machine. Note that the configuration, arrangement, size, and the like of the power supply device 34 can be changed as appropriate.

In this embodiment, the setting key-type switch 52 and the reset switch 53, which will be described later, are provided on the main control board 71 (more specifically, on the main control board case, which will be described later). A switch can also be configured to be provided on the power supply 34 .

[1-2-5. substrate]
The pachi-slot machine 1 includes, for example, the following boards as boards required for various controls. Note that each substrate shown below is merely an example, and a configuration in which substrates different from these are provided may be employed, or a configuration in which non-essential substrates among these are not necessarily provided may be employed.

[1-2-5-1. Main control board]
The main control board 71 is mounted inside the cabinet G on the rear side of the reel unit RU. In addition, the main control board 71 is a game control board that performs control related to the game. are housed in The electrical configuration of the main control board 71 will be described later.

There are various restrictions on the specifications of the main control board 71, and basically various electronic components are DIP-mounted. implemented). Also, in this case, a test point may be provided for checking the operation using a tester or an oscilloscope. In addition, small electronic parts not exceeding 6 mm square may be used for some or all of the various electronic parts. Moreover, the board surface of the main control board 71 may be configured to have multiple layers.

[1-2-5-2. Sub control board]
The sub-control board 72 is mounted inside the cabinet G on the back side of the intermediate support plate G1. In addition, the sub-control board 72 is an effect control board that controls effects, and is housed in a sub-control board case (not shown) made of resin. The sub control board case can be configured as a transparent (or substantially transparent) resin case similar to the main control board case, or can be made of other materials that are opaque (or substantially opaque). can also be configured as a case using The electrical configuration of the sub control board 72 will be described later.

[1-2-5-3. Other substrates]
(main relay board)
The main relay board 73 (reference numerals omitted in FIG. 2) is attached to a specific position (for example, the back side of the lower door mechanism DD) in the cabinet G, and various devices connected to the main relay board 73 and the main control board 73 are connected to the main relay board 73. It is an intermediate control board for relaying between the board 71 and between the main control board 71 and the sub control board 72 . Note that the main relay board 73 is configured as a board separate from the main control board 71 for convenience of control efficiency and wiring efficiency. A configuration in which the main relay board 73 is not provided can also be adopted. From this point of view, the main relay board 73 may be further divided into a plurality of relay boards to improve control efficiency and wiring efficiency. That is, a plurality of substrates may be provided as the main relay substrate.

(Secondary relay board)
The sub-relay board 74 is mounted at a specific position in the cabinet G (for example, on the back side of the lower door mechanism DD), between various devices connected to the sub-relay board 74 and the sub-control board 72, and It is an intermediate control board for relaying between the main control board 71 and the sub control board 72 . The sub-relay board 74 is configured as a board separate from the sub-control board 72 for convenience of control efficiency and wiring efficiency. It is also possible to have a configuration in which the sub-relay substrate 74 is not provided while the sub-relay substrate 74 is provided. From this point of view, the sub relay board 74 may be further divided into a plurality of relay boards to improve control efficiency and wiring efficiency. That is, a plurality of substrates may be provided as sub-relay substrates.

(External collective terminal board)
The external centralized terminal plate 55 is attached at a specific position (for example, the back side of the lower space) in the cabinet G, and receives signals such as medal insertion signals, medal payout signals, external signals 1 to 4, and security signals. Output to the outside of the pachi-slot machine 1. The output start conditions and output end conditions of the external signals 1 to 4 can be appropriately set, and the transition of the internal state of the pachi-slot machine 1 (for example, bonus state or AT state) can be externally controlled according to the game characteristics. Allows you to report. Since the external centralized terminal board 55 is normally connected to an external data display device or a hall computer, these devices can be used not only for inserting/paying out medals and error occurrences in the pachi-slot machine 1, but also for detecting errors. , such internal state transition situations are recognizable.

(Interface board for testing machine)
The first interface board for testing machine 301 and the second interface board for testing machine 302 are both relay boards used for outputting various game-related signals to the testing machine in the certification test (trial test) of the pachi-slot machine 1. (In addition, since these relay boards are not mounted on the pachi-slot machine 1 as a released product for sale, the main control board 71 for sale includes the first interface board 301 for testing machine and the second interface board 301 for testing machine. Various electronic components required to connect to the interface board 302 are also not mounted). For example, a test signal for controlling the main operations related to the game (for example, internal lottery, reel stop control, etc.) is output via the tester first interface board 301, and is determined by the main control board 71. The test signal or the like related to the push order navigation thus obtained is output via the second interface board 302 for testing machine.

[2. Electrical Configuration of Pachislot Machine]
Next, the electrical configuration of the pachi-slot machine 1 will be described with reference to FIG. 3 is a block diagram showing the electrical configuration of the pachi-slot machine 1. As shown in FIG.

As described above, the pachi-slot machine 1 has a main control board 71, a sub-control board 72, a main relay board 73, and a sub-relay board 74. The main control board 71 and the main relay board 73, the main relay board 73 and the sub-relay board 74, and the sub-relay board 74 and the sub-control board 72 are electrically connected. In addition, the main control board 71 and the sub control board 72 are electrically connected via the main relay board 73 and the sub relay board 74 so that one-way serial communication from the main control board 71 to the sub control board 72 is possible. properly connected.

The main control circuit board 71 is mounted with a main control circuit 100 as a game control unit that controls games. The main control circuit 100 includes, for example, a main CPU 101, a main ROM 102, a main RAM 103, a clock pulse generation circuit (not shown), a random number circuit (not shown), and the like. The main ROM 102 stores various control programs executed by the main CPU 101, various data tables, data for transmitting various control instructions (commands) to the sub control circuit 200, and the like. The main RAM 103 is provided with a storage area for storing various data such as an internal winning combination determined by executing the control program. The clock pulse generation circuit generates a clock pulse signal for operating the main CPU 101 . The random number circuit generates random numbers within a predetermined range (eg, 0-65535 or 0-255, etc.). The main CPU 101 executes various control programs based on the generated clock pulse signal. Also, one or more values are extracted as random numbers from the generated random numbers as needed. In this way, control relating to game operations in general is performed.

A sub-control circuit 200 is mounted on the sub-control board 72 as a production control unit that controls production. The sub-control circuit 200 includes, for example, a sub-CPU 201, a sub-RAM 203, and the like. A ROM cartridge board 202 is connected to the sub control board 72 . The ROM cartridge substrate 202 contains various control programs executed by the sub CPU 201, various data tables, various effect data (for example, video data and drive data for the main display device 210, video data for the sub display device 220, lamp/ lamp data related to the LED group, sound data related to the speaker group, etc.) are stored. The sub-RAM 203 has a storage area for registering performance contents and various performance data determined by executing the control program, a storage area for storing data related to various control instructions (commands) transmitted from the main control board 71, and the like. be provided. In addition, the random number value for the effect related to the effect may be generated and extracted within the sub CPU 201 from a predetermined range of random numbers (for example, 0 to 32767, etc.), or the main control The generation and extraction may be performed by providing a random number circuit similar to the circuit 100 . Alternatively, a sub ROM may be included in the sub control circuit 200 instead of the ROM cartridge board 202, and various control programs may be stored in the sub ROM. Further, the ROM cartridge board 202 may store various performance data, and the sub ROM in the sub control circuit 200 may store various control programs and various data tables. In addition, the sub-control circuit 200 includes an image-dedicated microprocessor such as a GPU (for example, also referred to as "VDP"). may be configured to generate (edit) the

The main control board 71 includes stepping motors 51L, 51C, 51R, a setting key switch 52, a reset switch 53, a role ratio monitor device 54, an external collective terminal plate 55, a hopper device 32, an auxiliary medal storage switch 33S, and a power supply. Device 34 is electrically connected. In addition, the main control board 71 has a door opening/closing monitoring switch 56, a medal sensor 31S, a bet switch 6S, a start switch 7S, a stop switch 8S, an adjustment switch 9S, and an information display device 14 through the main relay board 73. It is connected to the. If the tester first interface board 301 and the tester second interface board 302 are mounted, they are electrically connected to the main control board 71 via the main relay board 73, for example.

In addition, the external collective terminal plate 55, the hopper device 32, the medal auxiliary storage switch 33S, the power supply device 34, the medal sensor 31S, the bet switch 6S, the start switch 7S, the stop switch 8S, the settlement switch 9S, the information display device 14, and the testing machine. Since the first interface board 301 for the tester and the second interface board 302 for the tester have already been described, description thereof will be omitted here.

The stepping motors 51L, 51C, 51R are connected to the reels 3L, 3C, 3R via gears having predetermined reduction ratios, respectively, and are driven to rotate and stop the reels 3L, 3C, 3R. Since each reel 3L, 3C, 3R rotates at a constant angle each time one pulse is output to each stepping motor 51L, 51C, 51R, the main CPU 101 controls each stepping motor 51L, 51C, 51R. The number of times pulses are output to 51C and 51R is counted, and the symbol positions of the reels 3L, 3C and 3R are managed based on the result of this count. Each reel 3L, 3C, 3R is provided with a reel index (not shown) that determines an initial position for such management, and an index sensor (not shown) for detecting the position of the reel index. .

The setting key-type switch 52 is used when changing the setting values of the pachi-slot machine 1 (for example, setting 1 to setting 6 in six steps) (setting change), or when checking the setting of the pachi-slot machine 1 (setting confirmation). used for Here, the set value indicates the degree of the player's advantage in the game, and normally, the lower the set value (for example, the closer to the setting 1) the relatively the degree of the player's advantage. The higher the set value (for example, closer to setting 6), the higher the player's degree of advantage. The setting key-shaped switch 52 is turned on when, for example, the administrator of the amusement arcade inserts a setting key (not shown) into the keyhole and turns it to the left from the initial position, and returns it to the initial position after turning it to the left. and turn off. When the power of the pachi-slot machine 1 is turned off, the settings can be changed by turning on the setting key-type switch 52 and then turning on the power. When the key-shaped switch 52 is turned on, the setting can be confirmed.

The reset switch 53 is capable of detecting a reset operation by an administrator on the amusement arcade side. A reset operation is an operation for canceling various error states. In addition, the reset switch 53 can detect a setting value decision operation by the manager of the game parlor in a state in which the setting can be changed. When the reset switch 53 is operated in a state in which the setting can be changed, the setting value is incremented by 1 each time it is operated (when reaching setting 6, the setting returns to setting 1). In this manner, setting value determination operation can be performed. Further, the set value determined in this manner is fixed when the start lever 7 is operated once thereafter. That is, the start switch 7S is capable of detecting setting value confirmation operation by the manager of the game parlor. In this way, when the setting is to be changed, the setting key-type switch 52 is turned on, the reset switch 53 is operated to select a set value, and the start lever 7 is operated to confirm the selected set value. After that, it is necessary to perform a setting change operation such as turning off the setting key-type switch 52 . It should be noted that this is an example of the setting change operation, and the configuration can be such that the setting can be changed by another operation. Also, when changing settings or confirming settings, for example, the current set value may be displayed in the credit lamp or payout number lamp described above.

The role ratio monitor device 54 is composed of, for example, a 4-digit 7-segment LED, and is provided inside the main control board case. The role ratio monitor device 54 sequentially displays various kinds of ratio information related to the game aggregated and calculated by the main CPU 101 . These ratio information are used when the administrator of the gaming parlor confirms whether or not the pachi-slot machine 1 is illegally remodeled. Note that the role ratio monitor device 54 may be mounted on the main control board 71, or may be mounted on another board (for example, a ratio display board) connected to the main control board 71. may Moreover, as long as it is inside the cabinet G, it may be provided in another place. For example, it may be provided on the main control board case. Also, a management switch for starting the display on the role ratio monitor device 54 or switching the contents thereof may be provided in the cabinet G, and when this switch is operated, the various ratio information described above may be displayed. good. On the premise of using such a management switch, for example, the information display device 14 may also be used as the role ratio monitor device 54 . In addition, immediately after the power is turned on or after a predetermined time (for example, about 10 seconds. The time to be a buffer considering the time required to start up the main control circuit 100 and the sub control circuit 200) after the power is turned on, the role ratio monitor device 54 In order to be able to confirm that the 4-digit 7-segment LED is functioning normally, for example, a test pattern (a pattern in which all seg and decimal LEDs light up) such as "8.8." It is desirable to have a configuration in which the light is lit (or blinked) for a period of time.

In the role ratio monitor device 54, for example, the type of the ratio information is displayed in the upper two digits, and the value (%) indicating the ratio information is displayed in the lower two digits. Here, the various ratio information displayed on the role ratio monitor device 54 includes, for example, cumulative specific section ratio information, continuous role ratio information and role ratio information for the most recent 6000 games, and cumulative continuous role ratio information. and role item ratio information.

The specific section ratio information refers to a stop operation that is advantageous to the player among the game sections of the target number of games played (for example, 175,000 games for "total"; 6,000 games for "last 6,000 games"; the same applies hereinafter). Information indicating the ratio of the number of games played in the game section (for example, AT state) (or simply the number of games in the advantageous section may be used) in which the information of . In addition, the continuous role ratio information means that among the number of medals paid out in the game section of the number of games to be played, the first type special role (RB) is in operation It is information indicating the ratio of the number of medals paid out (including during operation of the first class special bonus (RB) in the state where the operating device (BB) is operating). In addition, the accessory ratio information is the number of medals paid out in the game section of the target number of games, the first type special accessory (RB), the second type special accessory (CB), and the normal accessory (SB ) is information indicating the ratio of the number of medals paid out during the operation of the first class special bonus (RB). BB) is in operation and the first class special bonus (RB) is in operation, and the second class special bonus (CB) is in operation It is a concept that includes the operation of the second type special role product (CB) in the state where the role product continuous operation device (MB) is operating.

In addition, the game section (for example, AT state) in which the information of the stop operation that is advantageous to the player is performed is regarded as the operation of the accessory or the operation of the accessory continuous operation device, and in the respective ratio information It can also be subject to aggregation and calculation. In other words, the role ratio monitor device 54 may appropriately display necessary ratio information, and the various ratio information that can be displayed is not limited to these. Also, for example, when displaying continuous accessory ratio information on a model that is not equipped with a first class special accessory (RB), or when displaying specific section ratio information on a model that is not equipped with an advantageous section function (AT function) For models that do not have corresponding numerical information (corresponding information), the last two digits of the numerical information (% information indicating the ratio) of the four-digit 7-segment LED are displayed when displaying the item. In the 7-segment LED, for example, by lighting up the two vertical bars in the center, such as "--", by performing an identification display for non-compatible information, confirm that the model does not have compatible information. It is desirable to make it recognizable at a glance by a person.

The door opening/closing monitoring switch 56 is provided, for example, on the opening/closing side (right side) of the lower door mechanism DD. In addition, it may be configured to be provided on the back side of the lower door mechanism DD, or may be configured to be provided on the cabinet G side. Further, the upper door mechanism UD may also be provided with a similar door opening/closing monitoring switch. The door opening/closing monitoring switch 56 is turned on when the lower door mechanism DD is open, and is turned off when the lower door mechanism DD is closed, thereby monitoring the opening/closing of the lower door mechanism DD. A door opening error occurs when the door opening/closing monitoring switch 56 is turned on. In this case, the error state is canceled when the lower door mechanism DD is closed.

A ROM cartridge board 202 , a main display device 210 and a sub display device 220 are electrically connected to the sub control board 72 . In addition, the sub control board 72, through the sub relay board 74, 24h door monitoring unit 61, production button groups such as production buttons 10a and 10b, lamps and LEDs such as the upper lamp 23, speakers 35a and 35b. etc. are electrically connected.

Since the ROM cartridge board 202, the main display device 210, the sub-display device 220, the effect button group, the lamps/LEDs, and the speaker group have already been described, description thereof will be omitted here.

The 24h door monitoring unit 61, like the door opening/closing monitoring switch 56, is provided, for example, on the opening/closing side (right side) of the lower door mechanism DD. The function of monitoring the opening and closing of the lower door mechanism DD is the same as that of the door opening/closing monitoring switch 56, but by allowing the sub-control circuit 200 to perform such monitoring, the lower door mechanism DD can be monitored even further. The opening/closing history of the door mechanism DD can be saved for a certain period of time. The opening/closing history can be confirmed from the hall menu, which will be described later. Therefore, for example, if there is a history of opening after the manager of the amusement arcade has left outside business hours, or if there is a history of opening and closing for a long period of time during business hours, this may result in fraud. It is possible to recognize that there is a high possibility that the act has been committed.

[3. Function Flow of Pachislot Machine]
Next, a functional flow of the pachi-slot machine 1 will be described with reference to FIG. FIG. 4 is a diagram for explaining the function flow of the pachi-slot machine 1. As shown in FIG.

When the player inserts medals into the pachi-slot machine 1 (performs a bet operation) and operates the start lever 7 (performs a start operation), random numbers are generated from a predetermined range (for example, 0 to 65535). One random number (in this embodiment, this may be described as an "internal lottery random number") is extracted.

The internal lottery means (the main CPU 101 that performs an internal lottery process, which will be described later) performs lottery based on the extracted random number value to determine an internal lottery combination. By determining the internal winning combination, the combination of symbols permitted to be displayed on the active line is determined in advance. As for the types of symbol combinations, there are two types of combinations: medal payouts, replay activation, bonus activation, etc. and related items are provided. In addition, a win related to the payout of medals is called a "small win", a win related to replay is called a "replay win", and a win related to the activation of a bonus (bonus state) is called a "bonus win". called. Also, a winning combination that can be internally won (that is, a combination of symbols permitted to be established) is sometimes simply referred to as a "winning combination." Also, the internal winning combination may be referred to as a “winning combination”, a “predetermined result”, or a “derivation permissible condition”. In addition, the internal lottery means may be referred to as a ``winning combination determination means'', a ``winning combination determination means'', a ``prior determination means'', or a ``derivation allowable condition determination means''.

Further, when the start lever 7 is operated (start operation is performed), a plurality of reels are rotated. Thereafter, when the player operates the stop buttons (respective stop buttons 8L, 8C, 8R) corresponding to the reels (respective reels 3L, 3C, 3R) (stop operation is performed), reel stop control means (described later) The main CPU 101, which performs reel stop control processing, performs control to stop the rotation of the relevant reel based on the internal winning combination and the timing at which the stop button was pressed (or the pressing order thereof). Note that the operation means for performing the start operation is not limited to a lever-shaped one such as the start lever 7, and any operation means can be used as long as the player can perform the start operation. good. Further, the operation means for performing the stop operation is not limited to button-shaped ones such as the respective stop buttons 8L, 8C, and 8R. It can be a means.

In the pachi-slot machine 1, basically, control is performed to stop the rotation of the relevant reel within a specified time (190 msec) from when the stop button is pressed. In this embodiment, the number of symbols that move with the rotation of the reels within the specified time is referred to as "the number of sliding symbols". In this embodiment, when the prescribed period is 190 msec, the maximum number of sliding symbols (maximum number of sliding symbols) is set to four symbols.

When an internal winning combination that permits the display of a winning combination of symbols is determined, the reel stop control means normally displays the combination of symbols on the effective line within a specified time of 190 msec (for 4 symbols). Stop the rotation of the reel so that it is displayed at the top as much as possible. In addition, the reel stop control means stops the rotation of the reels by using the specified time so that the combination of symbols whose display is not permitted by the internal winning combination is not displayed on the effective line. The symbols displayed when the rotation of the reels is stopped are sometimes referred to as "stop display" or "display result". Further, the display of symbols when the rotation of the reels stops is sometimes referred to as "derivation of stop display" or "derivation of display result".

Further, the reel stop control means automatically stops each reel when a predetermined automatic stop time has passed since the reels are rotated, even if the player does not perform a stop operation. Stop control may be performed. In this case, since the reels are stopped without intervention of the player's stop operation, even if any internal winning combination is determined, any combination of symbols relating to winning is valid. It is desirable to stop spinning the reels so that they are not displayed along the line.

In this way, when all of the plurality of reels stop rotating, the winning determination means (the main CPU 101 that performs a winning operation determination process, which will be described later) determines that the combination of symbols displayed on the activated line is a winning combination. (or other predetermined ones) is determined.
That is, it is determined whether or not a winning combination of symbols (or other predetermined combination of symbols) has been established. Then, the combination of the displayed symbols is the one related to the winning (or other predetermined combination) by the winning determination means (that is, the combination of the symbols related to the winning (or other predetermined combination of symbols) ) is established), a privilege such as payout of medals is given to the player, or various controls are performed with this as a trigger. In the pachi-slot machine 1, as an example, a series of the above-described flow is performed as one game (unit game).

Note that the winning determination means simply determines whether or not the combination of symbols displayed on the activated line corresponds to any combination of symbols among a plurality of predetermined combinations of symbols. Alternatively, it may be determined whether or not the symbol combination corresponds to the internal winning combination determined by the internal lottery means. That is, in the former, it may be determined whether or not there is a winning combination of symbols separately from the internal winning combination. In this case, as long as the stop control is appropriately performed by the reel stop control means, it is possible to sufficiently ensure the prevention of the occurrence of false winnings, so it is possible to reduce the control load related to detection of false winnings. On the other hand, in the latter, by making it possible to determine whether or not the combination of symbols related to winning is a combination of symbols for which winning was permitted, even if an erroneous winning occurs due to a problem with the reels, etc. can be detected, security can be improved.

In addition, in pachislot, in the flow of the series of game operations described above, images are displayed by the display device (for example, the main display device 210, the sub display device 220, etc.), and light is emitted by various lamps (for example, the upper lamp 23, etc.). , sound output by speakers (for example, speakers 35a, 35b, etc.), or a combination of these, various effects are performed. That is, these are the effect executing means for executing the effect. The content of the effect executed by the effect executing means may be determined on the main control circuit 100 side (main side) or may be determined on the sub control circuit 200 side (sub side). That is, any one of them can be the effect content determining means.

For example, when the start lever 7 is operated (a start operation is performed), a random number for effect is extracted in addition to the random number for internal lottery. When the random number value for effect is extracted, the effect content determination means selects the effect to be executed this time from a plurality of types of effect contents associated with the internal winning combination by lottery (or according to predetermined determination conditions). decide.

Next, when the effect content is determined by the effect content determining means, the effect execution means performs a corresponding effect in conjunction with each opportunity such as when the reels start rotating, when each reel stops rotating, and when it is determined whether or not a prize is awarded. to run. In this way, in the pachi-slot machine 1, for example, by executing the effect contents associated with the internal winning combination, the determined internal winning combination (in other words, the combination of symbols to be targeted, the pressing order to be operated, etc.) The player is provided with an opportunity to know or anticipate what is possible, and the interest of the player can be enhanced.

[4. Basic specifications related to playability of pachislot machines]
Next, the basic specifications of the pachi-slot machine 1 will be explained.

[4-1. Pattern arrangement]
As described above, the pachi-slot machine 1 is designed such that a game is played by displaying a plurality of symbols variably and statically. Therefore, the main control circuit 100 must be configured so as to be able to grasp which symbol is arranged at which position on each of the reels 3L, 3C, and 3R. For this reason, the main ROM 102 stores at least data for identifying the type of symbol at each symbol position on each of the reels 3L, 3C, and 3R. As long as such a purpose can be achieved, various data configurations can be adopted, and in this embodiment, as an example thereof, a pattern arrangement table (see FIG. 9), which will be described later, is used.

The symbol arrangement table defines symbol position data (for example, "0" to "19") indicating each symbol position in the rotation direction of each reel 3L, 3C, 3R. Further, data (for example, a pattern code) for specifying the type of pattern is associated with each pattern position data. Further, in the symbol arrangement table, the position of the symbol located in the middle area of each reel within the frame of the main display window 4 when the reel index is detected is defined as "0". The number of symbols in each row, the number of types of symbols, or the maximum number of sliding symbols can be changed as appropriate.

[4-2. Pattern combination]
As described above, the pachi-slot machine 1 is designed so that the combination of displayed symbols affects the game result. That is, the pachi-slot machine 1 gives various benefits, shifts the current state to a relatively advantageous state, or shifts the current state to a relatively disadvantageous state according to the combination of displayed symbols. It makes it possible to migrate. Therefore, the main control circuit 100 must be configured to be able to grasp such a combination of symbols. Therefore, the main ROM 102 defines data for specifying such a combination of symbols. As long as such a purpose is achieved, various configurations can be adopted for the data configuration. ing.

The symbol combination table defines data (for example, "display combination" or "winning operation flag") indicating the type of combination of a plurality of predetermined symbols among the combinations of symbols that can be displayed on the activated line. ing. It should be noted that the symbols forming each combination of symbols can be specified using, for example, the above-described symbol code or the like. In addition, data indicating the type of privilege (for example, "payout etc.") is associated with each combination of symbols. The symbol combination table basically has a data structure corresponding to a winning flag storage area, a winning operation flag storage area, and a symbol code storage area (see FIG. 17), which will be described later. It should be noted that the number of types of combinations of symbols, the content of benefits to be provided, and the like can be appropriately changed and stipulated.

[4-3. Internal winning role]
As described above, the pachi-slot machine 1 is designed such that which combination of symbols is allowed to be displayed (determined in advance) affects the game result. That is, the pachi-slot machine 1 determines the internal winning combination (that is, the type of combination of symbols that can be displayed (or the type of privilege that can be given)) prior to the player's stop operation (in advance). It is possible. Therefore, the main control circuit 100 must be configured to be able to grasp such internal winning combinations. Therefore, data for specifying such an internal winning combination is defined in the main ROM 102 . As long as this purpose is achieved, various data configurations can be employed. In this embodiment, an internal lottery table (see FIG. 10), which will be described later, is used as an example.

The internal lottery table contains data indicating the types of a plurality of predetermined internal winning combinations (for example, "No." or "winning number"), and lottery values for determining each internal winning combination in each gaming state. is defined. Note that the lottery value may also vary depending on the set value. In addition, each internal winning combination is associated with a type of symbol combination permitted (corresponding) to be displayed. In the pachi-slot machine 1, it is possible to associate a plurality of symbol combinations with one internal winning combination. When such an internal winning combination is determined, which symbol combination is displayed? is determined by stop control.

Here, for example, in the later-described internal lottery process (see FIG. 26; more specifically, the internal winning combination determination process in S64) of the present embodiment, first, a numerical range predetermined by a random number circuit (for example, 0 65535) is sequentially added and updated with a lottery value defined for each internal winning combination. Next, it is determined whether or not the lottery result (lottery value+random number) has exceeded 65535 (whether or not the lottery result has overflowed). Then, when the result of the determination exceeds 65535 in a predetermined internal winning combination, the internal winning combination is won (the internal winning combination is determined). However, if none of the internal winning combinations exceeds 65535 even after the determination is made for all the internal winning combinations, the internal winning combination in the current game is "lost". Note that this is just an example of internal lottery processing, and various methods can be employed for the lottery processing as long as an appropriate lottery is performed according to the lottery value (winning probability). For example, the extracted random number value is sequentially subtracted and updated with the lottery value specified for each internal winning combination, and then it is determined whether the subtraction result (lottery result) is less than 0 (lottery result underflows). or not) to determine an internal winning combination.

In this way, in the internal lottery table, the probability (winning probability) of an internal winning combination having a larger defined lottery value is higher. The winning probability of each internal winning combination can be represented by "the lottery value defined for each winning number/the number of all possible random numbers to be extracted (random number denominator: 65536)".

[4-4. stop control]
As described above, in the pachi-slot machine 1, among the combination of symbols permitted to be displayed by the determination of the internal winning combination, which combination of symbols is finally displayed by the player's stop operation is the game result. It is a specification that affects the That is, the pachi-slot machine 1 finally displays not only the type of the determined internal winning combination, but also the player's stop operation timing and pressing order (also referred to as "stop operation mode" or "stop operation procedure"). It is possible to perform control (stop control) to vary (determine) the type of combination of symbols to be played. Therefore, the main control circuit 100 needs to be configured to be able to grasp in what manner the stop control is to be performed for each internal winning combination according to the player's stop operation manner. For this reason, the main ROM 102 defines data for specifying such a mode of stop control. As long as such a purpose is achieved, various configurations can be adopted for the data configuration. there is

In the stop table, data indicating the amount of symbol movement (for example, "number of sliding symbols") is defined for each symbol position data of each of the reels 3L, 3C, and 3R. For example, assume that a predetermined stop table is selected in a game in which a predetermined internal winning combination is determined. Next, it is assumed that a stop operation is performed on the rotating reel 3L. At this time, it is assumed that the stop start position (symbol position data in the middle area of the reel 3L when the stop operation is performed) is "0". Assume that the number of sliding symbols defined in the symbol position data "0" is "4" in the predetermined stop table. Then, the main control circuit 100 performs control so that the reel 3L is stopped at the symbol position moved by four symbols (the position of the symbol position data "4") (the planned stop position becomes "4"). In this way, the stop table defines data (the number of sliding symbols) that enables direct determination of the stop position. Note that such a data configuration is also just an example. Further, performing stop control using such a stop table is generally called "table control".

In the attraction priority table, when there are a plurality of combinations of symbols permitted to be displayed, data indicating which combination of symbols should be preferentially displayed (whether to be attracted) (for example, "attraction priority ”) is stipulated. For example, assume that a predetermined attraction priority table is selected in a game in which a predetermined internal winning combination is determined. Here, it is assumed that the predetermined internal winning combination permits the display of the symbol combination A and the symbol combination B, and the predetermined pull-in priority table is such that the symbol combination B is preferentially displayed over the symbol combination A. An order of priority shall be specified. Next, it is assumed that a stop operation is performed on the rotating reel 3L. Assume that the stop start position is "0" at this time.

Then, the main control circuit 100 determines whether the symbols that make up the symbol combination A and the symbols that make up the symbol combination B for each symbol position within the range of the maximum number of sliding symbols (for example, "4") including the stop start position. search to see if there is If neither pattern is available, the stop position is determined according to a predetermined rule (for example, stop at a closer position, stop at a farther position, etc.). If there are only the symbols constituting the symbol combination A, it is decided to stop at the position corresponding to the symbols. If there are only the symbols constituting the symbol combination B, it is decided to stop at the position corresponding to the symbols. If there are both symbols, the symbol combination B is preferentially displayed over the symbol combination A, so it is decided to stop at the position corresponding to the symbols constituting the symbol combination B. The attraction priority may be stored for all symbol positions during the rotation of the target reel according to the selected attraction priority table, or the target reel may be stopped. Each symbol position within the range of the maximum number of sliding symbols including the stop start position may be stored. Also, such a data configuration is merely an example. Also, performing stop control using such a pull-in priority table is generally referred to as "control control".

In this embodiment, it is possible to adopt a configuration in which stop control is executed by performing only "table control", or a configuration in which stop control is executed by performing only "control control". Alternatively, first perform "table control" to tentatively determine the stop position, then perform "control control" to search for a more appropriate stop position, and change the stop position depending on the search results. It can also be configured to execute stop control that enables to

Thus, in the pachi-slot machine 1, which symbol combination is finally displayed on the activated line is determined based on, for example, the following three factors.

The first element is the determined internal winning combination (lottery result of internal lottery processing). For example, if the result of the internal lottery process is "lost", any combination of symbols related to the replay hand, the combination of symbols related to the small hand, or the combination of symbols related to the bonus hand will finally be on the active line. It is never displayed. Note that "lose" can be regarded as one of the internal winning combinations, or can be regarded as a lottery result in which no internal winning combination is determined.

The second factor is the timing of the player's stop operation (the position of the symbol (depression position) when the player operates any of the stop buttons). For example, in the present embodiment, the maximum number of sliding symbols is set to 4 symbols, so display is permitted even if one of the internal winning combinations is won as a result of the internal lottery process. If the symbols constituting the combination of symbols are arranged in excess of 4 symbols on the effective line (each effective line if there are more than one), the combination of the relevant symbols depends on the timing of the player's stop operation. may not be displayed. This is so-called "dropping".

The third element is the player's pressing order (the order in which the player operates the stop buttons). For example, in the present embodiment, there is a case where an internal winning combination associated with a combination of multiple symbols is determined, and in this case, it is finally displayed on the activated line according to the player's pressing order. The combination of symbols to be played may change. Such an internal winning combination is called a "push-order combination", and if it is a replay combination, it is sometimes called a "push-order replay", and if it is a small combination, it is called a "push-order small combination". It is sometimes called

[4-5. game state]
In the pachi-slot machine 1, it is possible to provide various game states as states in which the game is played in order to vary the degree of advantage of the player or to achieve the intended game characteristics. An example of the game state will be described below.

[4-5-1. Bonus state]
In the pachi-slot machine 1, when a bonus combination is won and a combination of symbols related to the bonus combination is displayed on the effective line, it is possible to shift to the bonus state (activate the bonus state). It should be noted that it is also possible to configure so that such a bonus state is not provided. Also, by providing a plurality of types of bonus combinations, it is possible to provide a plurality of bonus states. When a bonus combination is won, a state (carry-over state) occurs in which the bonus combination is carried over as an internal winning combination over a plurality of games until the combination of symbols related to the bonus combination is displayed on the activated line. Such a bonus combination is sometimes referred to as a "carryover combination". In addition, such carry-over state is sometimes referred to as "between (bonus) flags", "(bonus) inside", and the like.

In the bonus state, it is possible to change the lottery mode (including the winning probability and its content, or the mode of stop control, etc.; hereinafter the same) for minor wins with respect to the state in which the bonus state is not activated (non-bonus state). (Because it is also possible to change the lottery mode of the replay combination, the bonus state can be regarded as one mode of the RT state described later). Therefore, when such a lottery mode becomes a relatively advantageous lottery mode for the player, the bonus state becomes a more advantageous game state than the non-bonus state. On the other hand, if such a lottery mode becomes a relatively disadvantageous lottery mode for the player, the bonus state becomes a game state more disadvantageous than the non-bonus state.

As a bonus role, for example, a first-class special role (RB), a first-class special role continuous operation device (BB), a second-class special role (CB) (but not a carryover role) , Accessory continuous operation device (MB) related to the second type special accessory, and ordinary accessory (SB) (but not carryover role), etc. can be mentioned. Also, for example, the bonus state corresponding to each bonus combination is configured as follows. The RB state is a gaming state that ends when a predetermined number of winnings (for example, the upper limit is 8 times) or a predetermined number of games (for example, the upper limit is 12 times) are played. Configured. The BB state is configured as a game state in which the game ends when the payout of medals exceeds an arbitrary predetermined payout number (for example, the upper limit is 285).

The CB state is configured as a game state that ends when one game is played. The MB state is configured as a game state that ends when the payout of medals exceeds an arbitrary predetermined payout number (for example, the upper limit is 153), or when RB or SB is won during the MB state. be. The SB state is configured as a game state that ends when one game is played.

Note that the operating condition of the bonus state is not limited to the fact that the combination of symbols for the bonus combination is displayed on the active line. For example, during the operation of the accessory continuous operation device (BB) related to the first class special accessory, at the start of operation of the accessory continuous operation device (BB) related to the first class special accessory, the first special role It is also possible to configure such that the first class special role (RB) is automatically activated at the start of the game when the object is not in action, or at the end of the operation of the first class special role. That is, it is possible to perform control so that RB is always in operation while BB is in operation without defining the combination of symbols related to RB. Here, the RB during BB operation is sometimes referred to as "JAC" or the like, and such a specification in which the RB during BB operation automatically operates is sometimes referred to as "auto JAC" or the like. Also, during the operation of the BB, it is possible to perform control so that the RB is in operation when the specified combination of symbols related to the RB is displayed on the activated line. The specification in which the RB operates based on the display of the combination of corresponding symbols is sometimes referred to as "manual JAC" or the like. The same applies to the relationship between the accessory continuous operating device (MB) relating to the second type special accessory and the second type special accessory (CB). That is, without specifying the combination of symbols related to the CB, it is possible to control so that the CB is always in operation during the operation of the MB, and during the operation of the MB, the specified symbols related to the CB It is also possible to control so that the CB is in operation when the combination is displayed on the effective line.

[4-5-2. RT state]
In the pachi-slot machine 1, it is possible to shift to the RT state (activate the RT state) when a predetermined transition condition is satisfied. It should be noted that it is also possible to configure so that such an RT state is not provided. It can also be configured to provide a plurality of RT states. The RT state is a state in which the lottery mode of the replay combination can be varied with respect to the state in which the RT state is not activated (non-RT state). Therefore, when such a lottery mode becomes a relatively advantageous lottery mode for the player, the RT state becomes a more advantageous game state than the non-RT state. On the other hand, if such a lottery mode becomes a relatively disadvantageous lottery mode for the player, the RT state becomes a game state more disadvantageous than the non-RT state. Moreover, when a plurality of RT states are provided, the same applies to between the plurality of RT states. In this case, the RT state in which the lottery mode of the replay combination (in particular, the winning probability) is relatively advantageous to the player is called a "high RT state" or a "high probability replay state". The RT state in which the aspect (particularly, the winning probability) is relatively disadvantageous to the player is sometimes referred to as a "low RT state" or a "low probability replay state".

The RT state can be transitioned to, for example, when any of the following transition conditions are satisfied. Moreover, when a plurality of RT states are provided, the same applies to between the plurality of RT states.
(1) When RB, BB or MB is won (2) When a combination of symbols related to RB, BB or MB is displayed (3) When RB state, BB state or MB state ends (4) RB, (5) (3) or (4) when a specific combination of symbols is displayed when BB or MB has not been won (not carried over) and neither RB, BB or MB has been won. When a predetermined number of games have been played after the transition condition is established

[4-5-3. AT state]
The pachi-slot machine 1 is capable of shifting to the AT state (activating the AT state) when a predetermined transition condition is satisfied. It should be noted that it is also possible to configure so that such an AT state is not provided. It can also be configured to provide a plurality of AT states. The AT state is more advantageous than the state in which the AT state is not activated (non-AT state), for example, by informing the player of the information of the stop operation that is advantageous to the player when the above-described push win is won. It is a game state configured as a state.

In the case of providing multiple AT states, the game period of each AT state (including the ease of extension, etc., if the period can be extended (or "additional"; the same applies hereinafter)), The degree of advantage of the player can be varied by varying the type of the notification target combination for which the stop operation information is notified or the probability of occurrence of the notification of the stop operation information. Also, the conditions for transitioning to the AT state and the conditions for ending the game can be appropriately set according to game characteristics (however, the end due to the execution of limit processing, which will be described later, is excluded). Also, the AT state may be handled in the same way as the bonus state described above, and in this case may be referred to as a "pseudo-bonus state" or the like.

Also, the AT state game period may be managed by the number of games (number of games played) as long as the period is appropriately managed (game number management). may be managed by (set number management). In addition, it may be managed by the number of payouts or the number of net increase (number of difference) during the AT state (number of payouts management, difference number management). In addition, it may be managed by the number of times (navigation count) that notification (for example, push order navigation at the time of winning a push order minor role) that affects the payout of medals in the AT state is performed (navigation count management). The same applies when the AT state is extended. Also, the game period given when shifting to the AT state and the game period given when the AT state is extended may be managed by different management methods. Moreover, when a plurality of AT states are provided, they may be managed by the same management method, or may be managed by different management methods.

[4-5-4. ART state]
In the pachi-slot machine 1, when a predetermined transition condition is satisfied, it is possible to transition to the ART state (activate the ART state) by combining the high RT state and the AT state described above. That is, since the ART state means the AT state performed in the high RT state, at least the low RT state and the high RT state are provided as the RT state, and the state is shifted to the high RT state (or to the low RT state). Although it is different from the AT state in that control is performed (avoiding transition), the basic control is the same as in the AT state. If the transition to the state (or the transition to the low RT state is avoided), it can be said to be synonymous with the AT state). In addition, when the transition condition of the ART state is satisfied, the state may be shifted to the AT state first, and then shifted to the high RT state to shift to the ART state. Alternatively, the high RT state and the AT state may be simultaneously ( Alternatively, the state may be shifted to the ART state by shifting at approximately the same time.

[4-5-5. Other game state]
It should be noted that the pachi-slot machine 1 can be provided with game states other than the various game states described above. For example, each mode (see FIG. 5 and FIG. 6) in an advantageous section to be described later is also a state in which a player plays a game, and is advantageous in determining whether or not to shift to an AT state as a pseudo-bonus state. Since the degree can be changed, these can be regarded as game states. Also, from the same point of view, for example, it is possible to provide a game state in which the degree of advantage of whether or not to shift to a bonus state can be varied. For example, when a bonus hand is won (carried over), the game state in which the combination of symbols related to the bonus hand is likely to be displayed by the stop control, and the combination of symbols related to the bonus hand are relative to this. By providing a game state that is difficult to be displayed on the screen, it is possible to change the degree of advantage of the player. Also, for example, a game state in which a bonus combination is won with a predetermined probability (easy to win) and a game state in which the bonus combination is won with a probability lower than the predetermined probability (relatively difficult to win) are provided. By doing so, it is possible to configure such that the degree of advantage of the player can be varied.

In addition, as a method for changing the degree of advantage of whether or not to shift to the AT state (including whether or not to extend the game period of the AT state in the AT state, the same applies hereinafter), the following method is adopted. You can also For example, a "special combination" can be determined as an internal winning combination. For the specific combination, the number of medals awarded varies depending on the player's stop operation mode (stop operation timing, pressing order, or a combination thereof). (For example, if the stop operation mode is appropriate (correct answer), 8 coins will be paid out, and if inappropriate (wrong answer), 1 coin will be paid out or no payout will be made).

Then, when the specific combination is won in a specific game state, and when 8 coins are paid out, it is determined whether or not the advantage degree of whether or not to shift to the AT state in the current game is changed to an advantageous one. decision (whether or not to directly shift to the AT state, or whether or not to directly extend the game period of the AT state, which will be described as "advantageous decision" hereinafter) is not performed. On the other hand, if 8 coins are not paid out, the advantageous decision is made in the current game. Alternatively, if the specific combination is won in the above-described specific game state, and 8 coins are paid out, the advantageous decision is made in the current game. On the other hand, if 8 coins are not paid out, the advantageous decision is not made in the current game.

In this way, when a player plays a game in a specific game method, there are cases where an advantageous decision is made in the current game as a result of the game, and where the advantageous decision is not made (the advantageous decision is restricted). It can also be configured so that there is a case where the In addition, the player may change between the current game and the next game, and if such restrictions continue after the next game, the (next) player may suffer a significant disadvantage. Therefore, it is desirable that such restrictions be limited to the current game and not to continue after the next game. Such restrictions are also sometimes referred to as "penalties."

[4-6. Game section]
In the pachi-slot machine 1, in order to prevent gambling from becoming excessively high, it is possible to provide various game intervals as states in which the game is played with a concept different from the game state described above. An example of the game section will be described below. The game section is roughly divided into a non-advantageous section and an advantageous section.

(Non-advantageous section)
The non-advantageous section is configured as a game period in which it is not possible to notify the player of a stop operation mode that is advantageous to the player, and has the following requirements. The following requirements are only examples, and if at least one of the requirements is relaxed or tightened, it can be changed accordingly.

(1) It is not possible to notify the player of advantageous stop operation modes (for example, push order navigation, etc.). Therefore, it is not possible to control to the AT state or ART state described above.
(2) When the set value is changed (changed in setting), or when an initialization condition such as "RAM abnormality" described later is met, a non-advantageous interval is set as an initial state.
(3) When the limit process described later is executed in the advantageous interval (that is, a predetermined value updated as the game progresses during the advantageous interval (for example, the advantageous interval game number counter and the advantageous interval payout counter described later) value) reaches a specified value (for example, 1500 games or 2400 sheets), a non-advantageous section is set as an initial state. Note that the predetermined value may be referred to, and if the predetermined value reaches a specific update value even before the predetermined value reaches the specified value, the non-advantageous section may be set on that condition. In addition, if a predetermined end condition is satisfied during the advantageous section and the end is determined (for example, if the configuration is such that a lottery for the end of the advantageous section is performed and the lottery is won, etc.), that condition will be used. A non-advantageous section may be set.
(4) In a non-advantageous section, processing related to an advantageous section (for example, processing for determining whether to transition to an advantageous section) can only refer to the determined internal winning combination. It is not possible to perform processing referring to various parameters other than the internal winning combination, such as result display (combination of symbols) and the number of games in the non-advantageous section (or the advantageous section before transition). To determine which internal winning combination has been determined, it is possible to refer to data directly indicating the internal winning combination, such as the winning number, or sub-flag (multiple roles) generated or converted from the data of the internal winning combination. as one piece of determination target data), it is also possible to indirectly refer to data indicating an internal winning combination.
(5) A non-advantageous section basically has one state, and multiple states cannot be set within the non-advantageous section. For example, it is not possible to set different states such that the non-advantageous section A after the end of the advantageous section is the non-advantageous section A, and the non-advantageous section B is the non-advantageous section after the setting change.

(advantageous section)
The advantageous section is configured as a game period in which it is possible to notify the player of a stop operation mode that is advantageous to the player, and has the following requirements. The following requirements are only examples, and if at least one of the requirements is relaxed or tightened, it can be changed accordingly.

(1) It is possible to notify the player of advantageous stop operation modes (for example, push order navigation, etc.). Therefore, it is possible to control to the above-described AT state or ART state.
(2) When the set value is changed (changed in setting), or when an initialization condition such as "RAM abnormality" described later is met, the advantageous section cannot be set as the initial state.
(3) When the limit process described later is executed in an advantageous section, it is necessary to terminate the advantageous section.
(4) In the advantageous section, processing related to the advantageous section (for example, determination processing of whether to shift the game state (mode) during the advantageous section, or whether to extend a specific game state (mode), etc.) , not only processing referring to the determined internal winning combination, but also processing referring to various parameters other than the internal winning combination, such as the derived result display (combination of symbols) and the number of games in the advantageous interval. . Other examples of the various parameters that can be referred to include, for example, privilege information such as points that can be given according to the various parameters described above, the type of bonus state, the type of RT state, and the stop operation timing of one of the reels. , or the order of pressing.
(5) A plurality of states can be set within the advantageous section. For example, it is possible to set a state such as a normal state that is disadvantageous to the player, a CZ state that easily shifts to the AT state, or an AT state in which the expected value of increased medals is positive when a stop operation is performed according to the notification. In addition, for example, in response to the decision to shift to the CZ state in the normal state, the CZ precursor may be set as a standby state until the transition to the CZ state actually occurs, and a precursor effect suggesting a transition to the CZ state may be performed. In response to the decision to shift to the AT state in the state, normal state or CZ state, the state is set as a waiting state until the actual shift to the AT state, and an indication effect suggesting the shift to the AT state can be performed. A state such as an AT precursor state can also be set according to game characteristics.
(6) It is possible to notify that the area is in an advantageous section by turning on the section lamp (status display unit) that can notify whether it is a non-advantageous section or an advantageous section (the section lamp is not lit). If you do, you can notify that you are in a non-advantageous section). It should be noted that the lighting start timing of the section lamp can be set to some arbitrary timing as described above. Basically, lighting may be started when a non-advantageous section transitions to an advantageous section, and lighting may continue until the transition to a non-advantageous section. However, if the transitioned advantageous section is in the normal state, the lighting may not be started, and the lighting may be started when the AT state is first entered. If the transitioned advantageous section is in the AT state, lighting may be started from that time.

[4-7. limiter]
In the pachi-slot machine 1, an upper limit (restriction) is set for the period in which the advantageous section continues continuously in order to prevent gambling from becoming excessively high due to the advantageous section continuing too long. is possible. Such an upper limit is called a "limiter". Further, in the present embodiment, the termination of the advantageous section by such a limiter is described as execution of limit processing or actuation of the limiter. An example of the limiter will be described below.

(game number limiter)
The number-of-games limiter is configured as a limiter that executes limit processing when the number of games (the number of games played) in the advantageous interval reaches "1500". For example, the later-described advantage interval game number counter starts counting when the advantage interval starts, and increments the count by one each time one game is completed. Then, based on the value of the advantageous interval game number counter reaching a specified value (for example, "1500" or more), the advantageous interval is forcibly played (for example, even if the AT state gaming period remains). Terminate it and move to a non-advantageous section. It should be noted that the number of games for which the game number limiter is activated can be set to any number of games up to the upper limit of "1500". Also, if the requirement for such a game number limiter is relaxed or tightened, it can be changed accordingly. Also, the gambling aspect may be suppressed step by step according to the number of games in the advantageous section.

(Payout number limiter)
The payout number limiter is configured as a limiter that executes limit processing when the number of payout medals in the advantageous section reaches "2400". For example, the advantageous section payout counter, which will be described later, starts counting from the start of the advantageous section, and each time medals are paid out, the corresponding number of medals (more specifically, the number of payouts minus the number of bets) a few minutes) add up the count. Then, based on the fact that the value of the advantageous section payout number counter reaches a specified value (for example, "2400" or more), the advantageous section is forced (for example, even if the AT state game period remains). Terminate it and move to a non-advantageous section. The number of payouts for which the number-of-payouts limiter operates can be set to any number of payouts that is equal to or less than the upper limit of "2400". Also, if the requirements for such a payout number limiter are relaxed or tightened, it can be changed accordingly. Alternatively, the gambling aspect may be suppressed in stages according to the number of medals paid out during the advantageous section.

Also, for example, the advantageous section payout number counter, which will be described later, counts the positive amount from the most recent lowest point, with the lowest point (starting point) at which the absolute number of medals has decreased the most from the start of the advantageous section. (That is, if there is no payout, the count is decremented, etc.). In other words, the payout number limiter executes limit processing when a maximum of "2400" medals are paid out from when the number of medals increases during the advantageous section (for example, when the AT state is started). It can also be configured as a limiter that Further, for example, the advantageous section payout number counter, which will be described later, may simply count the actual payout number (that is, the payout number without subtracting the bet number) instead of the above-described net increase.

The pachi-slot machine 1 may execute limit processing in the advantageous section using only the number-of-games limiter, or limit processing in the advantageous section using only the number-of-payout limiter. Both of the number limiters may be used to limit the advantageous section. When both limiters are used, it is desirable that the advantageous interval is terminated when the operation condition of one of the limiters is satisfied after the advantageous interval starts.

Also, the types of limiters are not limited to the game number limiter and payout number limiter described above. For example, the number of times of navigating the push-order minor combination during the AT state (that is, the number of times the information of the stop operation that is advantageous to the player for the combination related to the payout of medals) is a predetermined number (for example, "400" times). A navigation count limiter may be provided for executing limit processing when the number of times of navigation is reached. That is, as long as the gambling aspect can be appropriately suppressed, it is possible to execute limit processing using various game-related conditions.

[4-8. External signal]
As described above, the pachi-slot machine 1 is designed to output a plurality of types of external signals to the outside. For example, if the external signal 1 is turned on when the bonus state is started, and is turned off when the bonus state is terminated, the external data display device will also follow this. It is possible to perform an effect during the linked bonus state. Further, for example, the external signal 1 is turned on based on the start of the BB state, the external signal 1 is turned off based on the termination of the BB state, and the external signal 1 is turned off based on the start of the MB state. If the external signal 2 is turned on in response to the termination of the MB state, and the external data display machine is turned off, not only the effect during the bonus state but also the bonus state is performed on the external data display machine. The number of times can be counted by type.

Further, for example, if the external signal 1 is turned on when the AT state is started and is turned off when the AT state ends, the external data display device can In conjunction with this, an effect during the AT state can be performed. Further, for example, the external signal 1 is turned on based on the start of a predetermined AT state, and the external signal 1 is turned off based on the termination of the predetermined AT state. If the external signal 2 is turned on when the AT state is started, and turned off when the specific AT state is finished, the external data display device can also be set to the AT state. It is possible not only to perform effects but also to count the number of ATs for each type.

Also, for example, the AT state is configured as an AT state for managing the number of sets, and when the first AT state of the first set is started, the external signal 1 is turned on, and the second and subsequent sets are started. If the external signal 2 is turned on every time the game is played, the number of initial wins in the AT state and the number of extensions in the AT state can also be counted on the external data display. It should be noted that the timing to turn on and the timing to turn off each external signal can be set as appropriate. That is, as long as the situation can be appropriately recognized by an external data display device, hall computer, or the like, the output mode of each external signal can be appropriately set. For example, the period from the OFF state to the ON state and then to the OFF state again can adopt various conditions such as a predetermined time, one game, or until the state changes.

[4-9. command]
As described above, the pachi-slot machine 1 is designed so that a plurality of types of commands can be transmitted from the main control circuit 100 to the sub-control circuit 200 . In the pachi-slot machine 1, the main control circuit 100 and the sub-control circuit 200 cannot communicate with each other, and communication must be performed only in one direction from the main control circuit 100 to the sub-control circuit 200. ing. Therefore, the main control circuit 100 needs to timely transmit information (commands) for reporting changes in the state of the pachi-slot machine 1 to the sub-control circuit 200 . An example of such a command is described below.

The main control circuit 100 transmits an initialization command to the sub control circuit 200, for example, when a setting change operation is performed. The initialization command includes parameters specifying setting values, game states, and the like. Also, for example, when a bet operation is performed, a medal insertion command is transmitted. The medal insertion command includes parameters for specifying the number of bets and the like. Also, for example, when a start operation is performed, a start command is transmitted. The start command includes parameters specifying internal winning combinations, game states, and the like. Also, for example, when a lock effect is performed, a lock command is transmitted. The lock command includes parameters specifying the contents of the lock effect. Also, for example, when the reels 3L, 3C, and 3R start to rotate, a reel rotation start command is transmitted. The reel rotation start command includes parameters specifying that the rotation of the reels has started.

Also, for example, when a stop operation is performed, a reel stop command is transmitted. The reel stop command includes parameters specifying the reel to be stopped, the position at which the reel is to be stopped, and the like. Further, for example, when all the reels are stopped and the display combination (winning operation flag) is determined, the winning operation command is transmitted. The winning operation command includes parameters specifying the type of display combination, the content of the privilege to be given, and the like. Also, for example, when starting an advantageous interval, an advantageous interval start command is transmitted. The advantageous interval start command includes parameters for specifying the start of the advantageous interval, the mode (game state), and the like. Also, for example, when ending the advantageous section, an advantageous section end command is transmitted. The advantageous section end command includes parameters for specifying the termination of the advantageous section, the cause of the termination, and the like. Further, for example, when a settlement operation is performed, a settlement command is transmitted. The settlement command includes parameters for specifying the number of returned items and the like. Note that these are merely examples, and commands other than these can be transmitted as necessary, and unnecessary commands among these can be prevented from being transmitted.

[4-10. staging]
As described above, in the pachi-slot machine 1, various effects are executed using various effect devices in order to increase the interest in the game, to inform the player of useful information, or to achieve the desired game characteristics. It is possible. An example of such effects will be described below.

[4-10-1. Main side production]
In the pachi-slot machine 1, for example, the following effects can be performed under the control of the main control circuit 100 side (main side). As described above, the pachi-slot machine 1 is capable of informing information about the stop operation by means of the instruction monitor, which is also included in production in a broad sense.

(Rock production)
In the pachi-slot machine 1, when a predetermined execution condition is satisfied, an effect of stopping the progress of the game for a predetermined period (invalidating the game operation of the player for a predetermined period) can be performed. Such an effect is called a “lock effect” (or simply “lock”), and is also called a “freeze effect” (or simply “freeze”). It should be noted that it is possible to configure such that such a lock effect is not performed, and it is also possible to configure so that a plurality of types of lock effects can be performed.

Also, the game operation to be invalidated may be, for example, a start operation, a stop operation, or any other operation. For example, when the start operation is disabled for a predetermined period of time, the progress of the game is stopped for a predetermined period of time after all stop operations have been performed. Further, for example, when the stop operation is disabled for a predetermined period of time, the progress of the game is stopped for a predetermined period of time after the start operation is performed. In addition, when multiple types of lock effects are provided, the period during which the progress of the game is stopped (the period during which the player's game operation is disabled), the type of game operation to be disabled, etc. are set for each lock effect. You can do so.

(reel production)
In the pachi-slot machine 1, when a predetermined execution condition is satisfied, the effect display mode of each reel 3L, 3C, 3R (not only the variable display mode but also the combination with the stop display mode) during the execution of the above lock effect. including) can be performed. Such an effect is called a "reel effect", and is also called a "symbol effect" or the like. It should be noted that it is possible to construct such a reel effect so as not to be performed, and it is also possible to construct so that a plurality of types of reel effect can be performed. In addition, the case of "executing (executing) a lock effect" includes both cases in which reel effects are performed and cases in which reel effects are not performed.

The reel effect is, in short, to rotate or stop (temporarily stop) each of the reels 3L, 3C, and 3R regardless of the game operation of the player during the period in which the game operation of the player is invalidated. The performance is performed in Therefore, it is possible to set an operation pattern for performing such an effect operation without considering the rotation speed, the maximum number of sliding symbols, and the like. Also, by setting a plurality of operation patterns, it is possible to provide a plurality of types of reel effects. Also, by combining multiple types of reel effects and multiple types of lock effects, a wider variety of effects patterns can be set. It should be noted that any one of the reels 3L, 3C, and 3R may be used for the reel effect, or any two of them may be used, or all three of them may be used.

(pseudo game)
In the pachi-slot machine 1, when a predetermined execution condition is satisfied, an effect of performing a pseudo game can be performed during the execution of the lock effect. Such an effect is called a "pseudo game". It should be noted that it is possible to construct such a pseudo-game so as not to be performed, it is also possible to construct so as to be able to perform a plurality of types of pseudo-game. In addition, in the case of "executing (executing) the lock effect", it includes both cases in which pseudo-games are performed and cases in which they are not performed.

In short, the pseudo game accepts the player's game operation in a pseudo manner during the period in which the player's game operation is invalidated, thereby rotating or stopping (temporarily stopping) the reels 3L, 3C, 3R. It is a thing that directs by doing. In other words, the above-described reel effect is further effected by intervening the player's game operation. For example, the MAX bet button 6a, the 1 bet button 6b, the start lever 7, the respective stop buttons 8L, 8C, 8R, and the checkout button 9 are basically provided for the purpose of being used for game operations. Therefore, it is inherently undesirable to use it for purposes other than this. However, in the pseudo-game, it is possible to accept these operations on the premise that measures are taken so that the player does not misunderstand that the actual game is being played.

Here, an example is given and demonstrated about the flow of a pseudo-game. Pseudo-games, for example, are performed in the following flow.
(1) The player's actual start operation (where the execution condition is established and the pseudo-game starts)
(2) Pseudo-rotation of each reel (during pseudo-game)
(3) Receiving a pseudo stop operation, thereby temporarily stopping each reel (during pseudo game)
(4) After random delay processing, each reel actually starts spinning (actual game starts after simulated game ends)

Note that the random delay process is, for example, a state in which specific symbols are displayed side by side in the above situation (3), and when each reel starts rotating normally in the above situation (4), the player can make it easier to stop using a specific symbol as a mark (it may help the so-called "eye-pressing"), so to correct this, a random delay period is set for each reel. This is a process for starting the rotation after generating it (such a delay period is also called a "rearrangement period"). In addition, when each reel is temporarily stopped in the situations (3) and (4) described above, the phase signal in the excitation control of each stepping motor must be a predetermined value so as not to misunderstand that it is completely stopped. It is desirable to alternate the reels forward and reverse for less than a period of time (eg, 500ms).

As one of the measures described above, for example, when any combination of symbols is temporarily stopped in the above situation (3) (when the third reel is temporarily stopped and all the reels are temporarily stopped), Until the random delay process is started in the above situation (4), each reel may be slightly vibrated (swayed) up and down. As long as the phase signal changes in less than the above-mentioned predetermined time, when the first reel is temporarily stopped and when the second reel is temporarily stopped, such swinging is not performed. can be

In addition, as one of the above-mentioned measures, for example, a pseudo-game lamp is provided to notify that a pseudo-game is in progress, and after the pseudo-game is started in the above-mentioned (1) situation, the above-mentioned (4 ) until the random delay process is started in the situation, the pseudo-game lamp is lit. In addition, the pseudo-game lamp is preferably installed above the operation unit that receives the game operation of the player and at a position that can be visually recognized during the game. Also, the pseudo-game lamp is an independent lamp that is not used for other purposes, and it is desirable that the entire display portion of the pseudo-game lamp is covered with a monochromatic border. In addition, it is desirable that the pseudo-game lamp has a certain surface area (for example, one side exceeds 10 mm and the surface area exceeds 642 square mm, etc.) including the explanation part of the pseudo-game lamp. In addition, the description part of the pseudo-game lamp is a description that can be recognized as a lamp for notifying that the pseudo-game lamp is in the pseudo-game (for example, "FREEPLAY", "pseudo-game effect", or " It is desirable that such a description portion occupies ⅓ or more of the surface area. It should be noted that the pseudo-game lamp may be controlled by the main control circuit 100 or by the sub-control circuit 200 .

In addition, as one of the above-mentioned measures, for example, after the pseudo-game is started in the above-mentioned (1) situation, the above-mentioned (4 ), the main display device 210 or the sub display device 220 (or both) may be used until the random delay process is started. In addition, it is desirable that the pseudo-game display is displayed above the operation unit that receives the game operation of the player and at a position that can be seen during the game (in this embodiment, the main display device 210 and the sub display device 220 are above the operation unit, so either can be used). In addition, the pseudo-game display has a certain surface area including the explanation part (for example, one side exceeds 10 mm, and if the display screen is less than 7 inches, the surface area exceeds 642 square mm) , if the display screen is 7 inches or more, the surface area is 8.2% or more of the entire screen, etc.). In addition, the description part of the pseudo-game display is a description that can be recognized as a display for notifying that the pseudo-game display is in the middle of a pseudo-game (for example, "FREEPLAY", "pseudo-game effect", Alternatively, it is desirable to have a description such as "reel automatic rendering", etc.), and it is desirable to have a size that can be read by the player without being concealed.

Also, for example, during the pseudo-game (for example, after the pseudo-game is started in the above-described (1) situation until the random delay process is started in the above-described (4) situation), the instruction monitor It is desirable to configure so that the information of the stop operation is not reported (if it is necessary to display the information of the stop operation on the instruction monitor in the game, the display is started at the timing when the random delay process is started). In this way, it is possible to further prevent the player from erroneously recognizing that the actual game is being played during the pseudo-game. It should be noted that, if any of the above measures are taken, during the pseudo-game, even if the sub-side effect device (for example, the main display device 210 or the sub display device 220) is notified of the stop operation information good. Similarly, during the pseudo-game, the sub-side effect device may perform an effect according to the game result of the pseudo-game (interlocked with the pseudo-game operation).

In addition, in an actual game, a test signal corresponding to the game operation of the player or the state in which the game operation becomes possible is output via the first interface board 301 for testing machine. , no test signal corresponding to the player's pseudo game operation or the state in which the pseudo game operation is possible is output. Therefore, during the pseudo-game, a test signal (pseudo-game signal) may be output so that the test machine can recognize that the pseudo-game is in progress. In addition, when the first interface board 301 for the testing machine receives a pseudo-game signal from the main control board 71, it outputs a signal for pseudo-game progress control to the main control board 71, so that the main control board 71 side simulates A game may progress (that is, the first test machine interface board 301 may have a pseudo-game progress function). In addition, when the first interface board 301 for testing machine is provided with such a pseudo-game progress function, a changeover switch capable of switching on/off of the function may be provided. As a result, it is possible to arbitrarily set whether or not to confirm the performance contents of the pseudo-game in the certification test (test shooting test) of the pachi-slot machine 1 .

[4-10-2. Sub side production]
In the pachi-slot machine 1, for example, the following effects can be performed under the control of the sub-control circuit 200 side (sub-side). As described above, in the pachi-slot machine 1, it is possible to notify the stop operation information by the main display device 210 or the like, but this is also included in the production in a broad sense.

(Normal production)
In the pachi-slot machine 1, when a predetermined execution condition is satisfied, an effect that the current game is completed (that is, one game ends) can be performed. Such an effect is called a "normal effect", and is also called a "single effect" or the like. It should be noted that it is possible to configure such that such a normal effect is not performed, and it is also possible to configure so that a plurality of types of normal effect can be performed.

(Continuous production)
In the pachi-slot machine 1, when a predetermined execution condition is established, an effect that continues over a plurality of games (that is, continues for a plurality of games) can be performed. Such an effect is called a “continuous effect”, as well as a “continuous effect”. It should be noted that it is possible to configure such that such continuous effects are not performed, and it is also possible to configure so that a plurality of types of continuous effects can be performed.

(Operation linked production)
In the pachi-slot machine 1, when a predetermined execution condition is satisfied, an effect can be performed in which the content of the effect can be changed according to the player's operation. Such an effect is called an "operation-linked effect", and is also called a "button effect" or the like. It should be noted that it is possible to construct such an operation-linked effect not to be performed, or to perform a plurality of types of operation-linked effect. Also, the operation-linked effect can be configured as a normal effect, or can be configured as a continuous effect. Also, the effect operation can include not only the operation to the effect button group but also various game operations.

Note that the various effects described above can be used for various purposes. For example, it can be used to suggest or notify a set value, an internal winning combination, a game state, a game section, details of awarding of a privilege, a period until the awarding of a privilege, and the like. It can also be used to suggest or notify the degree of advantage. Moreover, these uses are only examples.

(Other performances)
The pachi-slot machine 1 can perform effects other than the various effects described above. For example, various notifications to the player or the game parlor (for example, addiction prevention notification, forgotten item prevention notification, error state notification, demonstration state notification, etc.) are also included in the production in a broad sense as what is used for purposes other than the above. . As for the immersion prevention notification, for example, when the advantageous section ends, a warning or the like to that effect can be notified. In addition, for example, when an advantageous section ends or when a checkout operation is performed, a warning or the like indicating that fact can be notified. Further, the error state notification may be such that a warning or the like indicating the error is notified from the occurrence of the error until the error is resolved. In addition, the demonstration state notification can be made such that an empty machine or the like is notified when the period during which no game has been played reaches a predetermined period or when a settlement operation is performed.

[5. First gaming machine]
Next, with reference to FIGS. 5 to 22, a specific example of the specifications relating to game characteristics of the pachi-slot machine 1 will be described as a "first game machine". It should be noted that various specifications, functions, etc., described as the first gaming machine in the present embodiment can be partially or wholly applied to other gaming machines described in the present embodiment, and Various specifications, functions, and the like, which are described as other gaming machines in this embodiment, can be partially or wholly applied to the first gaming machine as described in this embodiment. In other words, an appropriate combination of these can be used as the invention according to the present embodiment.

First, in the first gaming machine, the activated line is defined as only one line of the above-mentioned "center line". In the first gaming machine, a non-bonus state and a bonus state are provided as game states. In addition, the non-bonus state is between 2BB flags in which "F_2BB" (a bonus combination that can be won only when two cards are bet. Hereinafter, it may be simply referred to as "2BB") described later, and between 2BB flags described later. Between the 3BB flags in which "F_3BB" (a bonus combination that can be won only in a 3-card bet state; hereinafter sometimes simply referred to as "3BB") is carried over not flagged). Also, the bonus state includes a 2BB state that shifts when a combination of 2BB symbols is displayed, and a 3BB state that shifts when a combination of 3BB symbols is displayed. be.

In addition, in the first gaming machine, it is possible to play a game with two medals bet (2 medals bet state) and with three medals bet (3 medals bet state). there is In addition, "bet" means that the player inserts two or three medals into the medal slot 5 for use in the game, or that the player operates the MAX bet button 6a or the 1 bet button 6b. 2 or 3 medals are placed from the credits, and 2 or 3 medals are automatically placed by winning a replay role.

[5-1. Game Features of the First Gaming Machine]
Next, the game flow in the first gaming machine will be described with reference to FIGS. 5 to 8. FIG. FIG. 5 is a diagram showing an example of a game state transition flow in a non-advantageous section and an advantageous section in the first gaming machine, and FIG. 6 is for explaining an example of each mode in the first gaming machine. FIG. 7 and FIG. 8 are diagrams showing examples of various tables in the first gaming machine.

As shown in FIG. 5, in the first gaming machine, the state in which a player plays a game is roughly divided into a non-advantageous section and an advantageous section. Increased sections (advantageous sections/pseudo bonuses) are provided. The non-advantageous section is a game state (non-AT state) in which information on a stop operation that is advantageous to the player is not notified, and is a game state that is disadvantageous to the player. The performance section is a game state (non-AT state) in which information about the stop operation that is advantageous to the player is not notified, and is similar to the non-advantageous section in that it is a game state that is disadvantageous to the player. , differs from the non-advantageous section in that mode transition is performed.

That is, the non-advantageous section is the initial state that is controlled when the game in the advantageous section is completed, when a setting change operation is performed, when other initialization conditions are satisfied, or when the factory is shipped. The effect section is a control state as a normal state in which the player can play a normal game by changing the expectation level of the increase section transition (given) by mode transition or the like.

On the other hand, the increasing section is a game state (AT state) in which information of a stop operation that is advantageous to the player is notified, and is a game state that is advantageous to the player. That is, the increase interval is a control state as an advantageous state in which the player can increase medals. Note that both the performance section and the increase section are advantageous sections, and a series of advantageous sections are formed by mutually shifting between these sections.

In the first gaming machine, as shown in FIG. 7(a), in the non-advantageous section, a non-advantageous section sub-flag as secondary information (sub-flag) corresponding to the internal winning combination (see FIG. 10 described later) is determined. It should be noted that the sub-flag indicates an internal winning combination that plays a similar role (whether or not it is a lottery target combination, its winning probability, etc.) in various lotteries (various processes related to advantageous sections) related to game characteristics by the main control circuit 100. By grouping and assigning the same information, it is information for making the group identifiable. Since this eliminates the need to provide various data tables for each internal winning combination, the amount of data can be compressed, and pressure on the capacity of the main ROM 102 can be avoided. In the non-advantageous section, lottery using this non-advantageous section sub-flag is performed.

The non-advantageous section sub-flag “Ripbell” has internal winning combinations of “F_Replay A” (No. “3”), “F_Replay B” (No. “4”), and “F_Bell 123A1” to “F_Bell 321B2”. ” (No. “10” to No. “33”). The non-advantageous section sub-flag “Weak Che” is determined when the internal winning combination is “F_Cherry” (No. “5”). The non-advantageous section sub-flag “Watermelon” is determined when the internal winning combination is “F_Watermelon” (No. “9”). The non-advantageous section sub-flag “definite combination” is determined when the internal winning combination is either “F_definite cherry” (No. “6”) or “F_reach” (No. “8”). The non-advantageous interval sub-flag “Medium Che” is determined when the internal winning combination is “F_Middle Cherry” (No. “7”). It should be noted that, in the non-advantageous section, as in the advantageous section, the winning sub-flag and the winning sub-flag can be determined. Moreover, these correspondence relationships are not limited to those described above.

Further, in the first gaming machine, as shown in FIG. 7(a), in the advantageous section, an advantageous section winning sub-flag as secondary information (sub-flag) corresponding to an internal winning combination (see FIG. 10 to be described later) is determined. Further, in the advantageous section, an advantageous section winning time sub-flag is determined as secondary information (sub-flag) according to the combination of displayed symbols. In the advantageous section, a lottery is performed using these sub-flags for winning the advantageous section and sub-flags for winning the advantageous section.

The sub-flag “Bell” at the time of winning the advantageous section is determined when the internal winning combination is any one of “F_Bell 123A1” to “F_Bell 321B2” (No. “10” to No. “33”). The sub-flag “Weak Che” at the time of winning an advantageous section is determined when the internal winning combination is “F_Cherry” (No. “5”). The sub-flag “Watermelon” at the time of winning the advantageous section is determined when the internal winning combination is “F_Watermelon” (No. “9”). The sub-flag “fixed combination” at the time of advantageous section winning is determined when the internal winning combination is either “F_fixed cherry” (No. “6”) or “F_reach” (No. “8”). . The sub-flag “middle che” at the time of advantageous section winning is determined when the internal winning combination is “F_middle cherry” (No. “7”).

Advantageous section winning sub-flag "Tsutaribu 1" is set to "Right" when the internal winning combination is either "F_Replay A" (No. It is determined when the combination of symbols of "rising lips" is displayed (that is, when the winning combination is "rising lips"). Advantageous section winning sub-flag ``Common replay 2'' is set to ``Parallel It is determined when the symbol combination of "LIP" is displayed (that is, when the winning combination is "Parallel LIP").

Here, in the first gaming machine, as will be described later, when the internal winning combination is "F_Replay A" (No. "3"), the symbol combination of "rising to the right" is between the 3BB flags. Between the 2BB flags and between the non-flags, a combination of "parallel lips" symbols is displayed.

That is, when the internal winning combination is "F_Replay A" (No. "3"), "Common Replay 1" is determined as a sub-flag at the winning of the advantageous section between the 3BB flags, and is advantageous between the 2BB flags and between the non-flags. As a sub-flag at the time of winning the section, "Tsutaribu 2" is determined. In the first gaming machine, when the sub-flags at the time of winning the advantageous zone are different in this way, various lotteries (for example, a pseudo-bonus transition lottery using a pseudo-bonus transition lottery table shown in FIG. The degree of advantage in the mode transition lottery using the mode transition lottery table shown in 8(f) is varied.

In addition, in the first gaming machine, for example, depending on whether it is between 3BB flags or between 2BB flags, "F_Replay A" (No. ) has been described as an example, but the manner in which the sub-flags fluctuate at the time of winning the advantageous section is not limited to this. For example, as will be described later, when the internal winning combination is "F_Bell 123B1" (No. "12"), the stop control is made different between 3BB flags and 2BB flags. Therefore, when such a winning combination is won, the number of medals to be paid out is not changed (or may be changed), and the combination of displayed symbols is made different. A sub-flag may be determined. Then, the degree of advantage in various lotteries, which will be described later, may be changed in accordance with the difference in the sub-flag at the time of winning the advantageous section.

Further, for example, as will be described later, when the internal winning combination is "F_Watermelon" (No. "9"), regardless of which flag (between non-flags) the pressed position (stop operation timing) ) is appropriate, the combination of "watermelon" symbols is displayed. When a winning combination is won, different advantageous section winning time sub-flags may be determined depending on whether a prize can be won without any omissions or when omissions occur. Then, the degree of advantage in various lotteries, which will be described later, may be changed in accordance with the difference in the sub-flag at the time of winning the advantageous section.

Further, for example, when the internal winning combination is "F_Replay A" (No. "3"), between the 3BB flags, the stop operation is in a specific manner (this particular manner is, for example, a predetermined stop operation It may be performed in any manner, such as a manner in which the hitting order (correct pressing order) is performed, a manner in which the pressing position (timing of the stop operation) is appropriate, and a manner in which these are combined), " A combination of symbols of "parallel lips" is displayed, and if it is not performed in a specific manner, a combination of symbols of "rising to the right" is displayed, thereby determining a sub-flag at the time of winning a different advantageous section You may do so. Then, the degree of advantage in various lotteries, which will be described later, may be changed in accordance with the difference in the sub-flag at the time of winning the advantageous section.

That is, in the first gaming machine, it is possible that the final stop display mode may differ depending on the number of bets, the game state, the mode of the stop operation, or a combination of any of these regarding the specific combination, It is possible to apply all modes that make it possible to determine different secondary information according to different stop display modes, thereby making it possible to vary the degree of advantage.

Returning to the description of the game characteristics of the first gaming machine. In the non-advantageous section, an advantageous section transition lottery is performed for each game. Specifically, the advantageous section transition lottery table shown in (b) of FIG. At a predetermined timing, a transition destination mode or the like is determined according to the non-game section sub-flag. In addition, when making this decision, if only the type of mode when shifting to the advantageous section is determined (in FIG. 5, "advantageous section start"), not only the type of the mode but also the pseudo bonus can be selected. There is a case where it is determined (in FIG. 5, “advantageous section start+pseudo bonus start”). However, in the non-advantageous section, it is also possible to have a specification in which it is not decided to shift to the pseudo bonus.

Here, with reference to FIG. 6, each mode in the first game machine will be described. In the first gaming machine, the mode is control information (which may be called a game state or a control state) for varying the degree of expectation of transition (granting) to an increase section (pseudo bonus) in the performance section (normal game). Yes, in the production section (normal game), according to this mode, it is decided whether or not to transition to a pseudo bonus, to maintain the advantageous section, or to end the advantageous section and move to the non-advantageous section It is designed to

The start mode is a relatively disadvantageous mode because it is easy to stay when transitioning from a non-advantageous section to an advantageous section (production section), and the expectation of shifting to a pseudo-bonus is relatively low (Fig. 7 (c)), and the likelihood of shifting to a more advantageous mode is also relatively low (see FIG. 8 (f), which will be described later). Although not shown, the number of ceiling games is set to "965 games" in the start mode. The number of ceiling games is used to forcibly shift to the pseudo bonus when the period during which the transition to the pseudo bonus is not made reaches a certain period. Therefore, the smaller the number of ceiling games, the more advantageous the player, and the larger the number of ceiling games, the more disadvantageous the player.

The normal A mode is the easiest mode for a player to stay in the game, and is a relatively disadvantageous mode. (see FIG. 8(f)), and the likelihood of shifting to a more advantageous mode is relatively low (see FIG. 8(f) described later). In the normal A mode, the number of ceiling games is set to "965 games". In FIG. 6, "approximately 999 G after the pseudo-bonus" means that after the pseudo-bonus is over, the game is shifted to an end A mode or an end-B mode, which will be described later, and 32 games are played in this mode without transitioning to the pseudo-bonus. After a game has been played and the normal A mode is selected when shifting from the non-advantageous section to the advantageous section after the game is played, the apparent ceiling number of games is "965 games" + end A. This is expressed because it is the game period "32 games" in the mode or the end B mode + the number of games required to shift from the non-advantageous section to the advantageous section. The same applies to the normal B mode, heaven preparation mode, and chance mode.

The normal B mode is relatively easy for the player to stay in the game and is a relatively disadvantageous mode, but it is a more advantageous mode than the normal A mode, and the expectation of shifting to the pseudo bonus is high. It is relatively low (see (c) of FIG. 7 described later), and the degree of expectation of shifting to a more advantageous mode is also relatively low (see (f) of FIG. 8 described later). In the normal B mode, the number of ceiling games is set to "965 games".

In the heaven preparation mode, although the expectation of shifting to the pseudo-bonus is relatively low (see (c) of FIG. 7 described later), the number of ceiling games is set to "466 games", and when shifting to the pseudo-bonus , and after that, it is determined that the mode will shift to heaven mode (see (f) in FIG. 8, which will be described later), so in that sense, the mode is relatively advantageous.

Chance mode has a relatively high degree of expectation for shifting to a pseudo-bonus (see (c) of FIG. 7 described below), and the ceiling number of games is set to "222 games", so in that sense it is relatively advantageous. mode. However, the degree of expectation for shifting to heaven mode is not high (see (f) of FIG. 8 described later).

End A mode is a relatively disadvantageous mode because it is easy to stay if you do not transition to heaven mode (including heaven preparation mode) after transitioning to a pseudo bonus, and it is expected to transition to a pseudo bonus. is the lowest (see (c) of FIG. 7 described later), and the expectation of shifting to a more advantageous mode is also relatively low (see (f) of FIG. 8 described later). In the end A mode, when 32 games are played without transitioning to the pseudo bonus after the pseudo bonus ends, the advantageous section itself ends and the game shifts to the non-advantageous section.

End B mode is a relatively disadvantageous mode, but it is more advantageous than End A mode because it is easy to stay if you do not shift to Heaven mode (including Heaven preparation mode) after transitioning to a pseudo-bonus. mode, the expectation of shifting to a pseudo-bonus is relatively low (see (c) in Fig. 7 below), and the expectation of shifting to a more advantageous mode is relatively low (see the diagram below 8 (f)). In the end B mode, as in the end A mode, when 32 games are played without shifting to the pseudo bonus after the end of the pseudo bonus, the advantageous section itself ends and shifts to the non-advantageous section. Note that the end A mode and the end B mode can also be collectively referred to as "end mode".

The security mode is a mode in which the player stays when Heaven C mode ends, and the degree of expectation for shifting to the pseudo-bonus is relatively high (see (c) of FIG. 7 described later), and the number of ceiling games is "32 games." , so it is a relatively advantageous mode in that sense. However, the degree of expectation for shifting to heaven mode is not high (see (f) of FIG. 8 described later). That is, when Heaven C mode ends, it is positioned as a mode for maintaining (guaranteeing) a relatively advantageous state for a certain period of time in order to prevent a decline in interest due to this.

Heaven A mode can also include the extension (addition) in the case of the specification that the pseudo bonus continues (AT state continues by determining extension (addition) during AT state. The same applies hereinafter), the degree of expectation to shift to a pseudo bonus is relatively high (see (c) of FIG. 7 described later), the number of ceiling games is set to "32 games", and the ceiling It is a relatively advantageous mode in which the probability of maintaining the mode (heaven mode loop rate) is set to a medium level. Although not shown in FIG. 6, for example, the ceiling mode loop rate may have a set difference. For example, when the set values are odd numbers (1, 3, 5), the ceiling mode loop rate is about 75%, and when the set values are even numbers (2, 4, 6), the ceiling mode loop rate is about 67%. The lottery value can also be set such that the higher the set value, the higher the ceiling mode loop rate. The same applies to Heaven B mode and Heaven C mode, which will be described later, and it is possible to provide a set difference in the ceiling mode loop rate.

Heaven B mode is a mode in which a series of pseudo-bonuses can be expected. , and the probability that the ceiling mode is maintained (heaven mode loop rate) is set high, making it a relatively advantageous mode. That is, in terms of ceiling mode loop rate, this mode is more advantageous than Heaven A mode.

Heaven C mode is a mode in which a series of pseudo bonuses can be expected. ”, and the probability of maintaining the ceiling mode (heaven mode loop rate) is set to be relatively high, making it a relatively advantageous mode. That is, in terms of the ceiling mode loop rate, this mode is more advantageous than Heaven A mode and Heaven B mode. The heaven A mode, the heaven B mode, and the heaven C mode can be generically called "heaven mode".

Each of the modes described above is merely an example, and the configuration of the mode is not limited to this. Modes other than the above-described modes can be set, and some of the above-described modes can be set not to be set.

Further, although the non-advantageous section has been described as being relatively less advantageous than the advantageous section, the relationship between the non-advantageous section and the advantageous section is not limited to this aspect. For example, when it is a non-advantageous section, the transition rate to the increased section is higher than when at least one or more modes are set in the advantageous section, or the average number of games required to transition to the increased section is shorter. It is also possible to set a specification such as that the non-advantageous section is most likely to be an increase section. By doing so, an incentive to play a game is generated even in a state where the non-advantageous section is confirmed after a setting change or the like. In addition, even if the lighting of the section lamp ends when 32 games have passed after the end of the pseudo-bonus, the most unfavorable state is not confirmed, so even in such a case, there is a motivation to continue the game. becomes. Also, so far, the presentation section has been described as a game state in which the information of the stop operation, which is advantageous for the player, is not notified. , etc.), it is also possible to set the game state in which the information of the stop operation is notified.

Returning to the description of the game characteristics of the first gaming machine. In the performance section (normal game), first, a pseudo-bonus transition lottery (at the time of winning) is performed with reference to the sub-flag at the time of advantageous section winning for each game. Specifically, the pseudo bonus transition lottery table shown in (c) of FIG. 7 is referred to, the internal winning combination is determined, and during the game after the advantageous zone winning sub-flag is determined according to the internal winning combination. At a predetermined timing, it is determined whether or not to shift to a pseudo bonus according to the sub-flag at the time of advantageous section winning. In addition, in (c) of FIG. 7, "non-winning" means not to shift to the pseudo bonus, "winning (current game)" means to shift to the pseudo bonus from the current game, and " "Winning (next game)" means shifting to a pseudo bonus from the next game.

In addition, in the first gaming machine, when "winning (current game)" is determined, the game is started at the start of the current game, and when "winning (next game)" is determined, the game is started at the start of the next game. After the operation (stop operation) is disabled for a certain period of time, and during the disabled period, a reel effect (“red 7 aligned” effect) is performed in which “red 7” symbols are displayed in alignment on the main display window 4. , in a game in which a pseudo-bonus is started and a "red 7 matching" effect is performed, if it is necessary to notify the information of the stop operation, at least the invalid period ends and the game operation (stop operation) is valid. (It may be before that, but not before the start of the random delay process described above), information about the stop operation is notified.

In the performance section (normal game), as a result of the pseudo-bonus transition lottery (at the time of winning), when it is determined to shift to the pseudo-bonus, a mode transition lottery (at the time of winning) is performed. Specifically, the mode transition lottery table shown in (f) of FIG. 8 is referred to, and the transition destination mode is determined according to the current mode and the advantageous section winning sub-flag. Note that this transition destination mode may be a mode including a pseudo-bonus, or a mode after the pseudo-bonus is finished. Also, as a result of the pseudo-bonus transition lottery (at the time of winning), it is decided to shift to the pseudo-bonus, and if the mode transition lottery (at the time of winning) is performed, the pseudo-bonus transition lottery (at the time of winning) and mode transition lottery, which will be described later. (at the time of winning) and mode transition lottery (at the ceiling) are not performed.

In the production section (normal game), as a result of the pseudo-bonus transition lottery (at the time of winning), if it is not decided to move to the pseudo-bonus, for each game (more specifically, "F_replay A" or "F_replay B”), a pseudo-bonus transition lottery (at the time of winning) is performed with reference to the sub-flag at the time of winning in the advantageous section. Specifically, the pseudo-bonus transition lottery table shown in FIG. At a predetermined timing (before the start of the game), it is determined whether or not to shift to a pseudo-bonus according to the advantageous section winning time sub-flag.

In the pseudo-bonus transition lottery table shown in (c) of FIG. 7, the sub-flag at the time of winning in the advantageous section "Tsut-rep 1" is decided rather than the sub-flag at the time of winning in the advantageous section at "Tsut-rep 1". The percentage of decisions to shift to a pseudo-bonus is higher in the case of However, the mode of giving preferential treatment to "Telephone 2" over "Telephone 1" is not limited to this. For example, when "Common 2" is determined as the sub-flag when winning an advantageous section, it may be decided to shift to a pseudo bonus with a predetermined probability, but "1" is determined as the sub-flag when winning an advantageous section. In this case, the transition to the pseudo-bonus may not be decided.

In the performance section (normal game), as a result of the pseudo-bonus transition lottery (at the time of winning), when it is determined to shift to the pseudo-bonus, a mode transition lottery (at the time of winning) is performed. Specifically, the mode transition lottery table shown in (f) of FIG. 8 is referred to, and the transition destination mode is determined according to the current mode and the advantageous zone winning sub-flag. Note that this transition destination mode may be a mode including a pseudo-bonus, or a mode after the pseudo-bonus is finished. As a result of the pseudo-bonus transition lottery (at the time of winning), it is decided to shift to the pseudo-bonus, and when the mode transition lottery (at the time of winning) is performed, the later-described mode transition lottery (at the ceiling) is not performed.

In addition, in the mode transition lottery table shown in (f) of FIG. 8, "Tsutaribu 2" was determined as the sub-flag when winning the advantageous section rather than when "Tsutaribu 1" was determined as the sub-flag when winning the advantageous section. In this case, the rate at which it is decided to shift to a mode that is relatively advantageous to the player is high. However, the mode of giving preferential treatment to "Telephone 2" over "Telephone 1" is not limited to this. For example, when the sub-flag at the time of advantageous section winning is set to "2", it can be determined to shift to a relatively advantageous mode for the player with a predetermined probability. It may be arranged such that, when "pass 1" is determined, it cannot be determined to shift to a mode that is relatively advantageous to the player.

In the effect section (normal game), as a result of the pseudo-bonus transition lottery (at the time of winning), if it is not decided to move to the pseudo-bonus, the number of ceiling games is updated (additional method or subtraction method), and the ceiling game When the number reaches the number of ceiling games associated with the current mode (or predetermined at the time of transition to an advantageous section, etc.), it is decided to shift to a pseudo-bonus. In this case, it is possible to make sure that "win (current game)" is determined, or that "win (next game)" is always determined. Alternatively, any one of these may be determined by lottery.

In the performance section (normal game), when it is determined to shift to the pseudo bonus due to the number of ceiling games being reached, a mode transition lottery (at the ceiling) is performed. Specifically, the mode transition lottery table shown in (f) of FIG. 8 is referred to, and the transition destination mode is determined according to the current mode. Note that this transition destination mode may be a mode including a pseudo-bonus, or a mode after the pseudo-bonus is finished.

It should be noted that the processing related to the pseudo-bonus transition lottery (at the time of winning) and the pseudo-bonus transition lottery (at the time of winning) differ only in the type of sub-flag, and the rest is the same processing content, so the same lottery table and control flow can be controlled using In addition, the processing related to the mode transition lottery (at the time of winning) and the mode transition lottery (at the time of winning) differ only in the type of sub-flag, and the rest is the same processing content, so the same lottery table and control flow are used. can be controlled by

Further, if "winning (current game)" is not provided as the type of winning of the pseudo-bonus, at the timing when the advantageous zone winning sub-flag is determined, the advantageous zone winning sub-flag has already been determined, and Since the number of ceiling games can also be updated, the pseudo-bonus transition lottery (at the time of winning), the pseudo-bonus transition lottery (at the time of winning), and the pseudo-bonus transition processing when reaching the ceiling can be performed together in one process. can. Similarly, the mode transition lottery (at the time of winning), the mode transition lottery (at the time of winning), and the mode transition lottery (at the ceiling) can be collectively performed in one process.

Returning to the description of the game characteristics of the first gaming machine. As described above, in the production section (normal game), it is decided to shift to the pseudo bonus, and when the pseudo bonus is started ("pseudo bonus start" in FIG. 5), the shift to the increase section (pseudo bonus) . Also, as described above, in the effect section (normal game), if the end A mode or the end B mode is controlled and 32 games are completed without transitioning to the pseudo bonus (in FIG. 5, "advantageous section end (Via end A/B)”) and move to a non-advantageous section. Further, when the conditions for limit processing shown in FIG. 16, which will be described later, are met, the advantageous section is forcibly ended ("advantageous section end (limit processing)" in FIG. 5), and as a result, Move to a non-advantageous section.

In the increase section (pseudo-bonus), when the pseudo-bonus is started, a ceiling reduction lottery is performed. Specifically, the ceiling reduction lottery table shown in (e) of FIG. 8 is referred to, and whether or not to reduce the number of ceiling games after the end of the pseudo-bonus is determined according to the current mode. In (e) of FIG. 8, "non-winning" means that the ceiling game number is not shortened, and "winning (ceiling game number = 0 update)" means that after the pseudo bonus ends, regardless of the mode , means that the ceiling game number to be set is set to "0" (reduced). Note that the ceiling shortening lottery can be performed not only when the pseudo bonus is started, but also every game during the pseudo bonus.

As a result of the ceiling reduction lottery, if it is decided not to shorten the number of ceiling games, when the pseudo bonus ends, if you do not have the 1G consecutive stock described later, the number of ceiling games will be reduced according to the current mode. is set (in the end mode, it is not set because the advantageous section ends after 32 games have elapsed (it is cleared accordingly), but the number of ceiling games may be temporarily set here) , the pseudo-bonus ends ("pseudo-bonus ends" in FIG. 5), and the game shifts to the production section (normal game). On the other hand, if it is decided to reduce the number of ceiling games as a result of the ceiling reduction lottery, "0 games" is set as the number of ceiling games when the pseudo-bonus ends. As a result, the pseudo bonus is started again from the next game after the pseudo bonus is finished. In this case, since the pseudo bonus is started when the ceiling game number is reached, the mode transition lottery (at the ceiling) is performed.

In the increase section (pseudo bonus), a mode transition lottery (at the time of winning) is performed for each game (more specifically, in a game in which "fixed hand" or "medium check" is determined as a sub-flag at the time of advantageous section winning). . Specifically, the mode transition lottery table shown in (f) of FIG. 8 is referred to, and the transition destination mode is determined according to the current mode and the advantageous section winning sub-flag. It should be noted that the transition destination mode may be determined even when a sub-flag at the time of winning an advantageous section other than the above is determined, but in this case, in principle, a relatively disadvantageous mode than the current mode will be transitioned. In order not to be determined as the first mode, another mode transition lottery table having a lottery value different from the mode transition lottery table shown in (f) of FIG. 8 may be referred to.

In the increase section (pseudo bonus), a mode transition lottery (at the time of winning) is performed for each game (more specifically, in the game in which "F_Replay A" or "F_Replay B" is won). Specifically, the mode transition lottery table shown in (f) of FIG. 8 is referred to, and the transition destination mode is determined according to the current mode and the advantageous zone winning sub-flag. In this case, similarly to the above, in principle, the mode transition lottery table shown in FIG. A different mode transition lottery table may be referred to.

In the increase section (pseudo bonus), 1G consecutive lottery is performed for each game. Specifically, the 1G run lottery table shown in (d) of FIG. 7 is referred to, and it is determined whether or not to generate the 1G run according to the current mode and the sub-flag at the time of winning the advantageous section or the sub-flag at the time of winning the advantageous section. be done. In (d) of FIG. 7, "non-winning" means that 1G-runs are not generated, and "winning (1G-runs + 1)" means that the right to generate 1G-runs (1G-run stock) is one. It means that it is granted (the 1G ream stock counter is incremented by 1). A plurality of 1G ream stocks (maximum 255) can be stocked (stored) by a 1G ream stock counter. Therefore, a plurality of 1G ream stocks may be granted during one pseudo-bonus. The 1G-run lottery table can also be configured so that a plurality of 1G-run stocks can be awarded in one 1G-run lottery.

When the pseudo bonus ends, if the value of the 1G-run stock counter is 1 or more (that is, if you have 1G-run stock), one 1G-run stock is consumed (1G-run stock counter is 1 is subtracted), and the pseudo bonus is started again from the next game after the pseudo bonus is finished. In this case, since the pseudo-bonus corresponding to the right of 1G ream stock starts, the above-described mode transition lottery is not performed. On the other hand, when the pseudo-bonus ends, if the value of the 1G-run stock counter is not 1 or more (that is, if you do not own 1G-run stock), and if you have not won the above-mentioned ceiling reduction lottery, The number of ceiling games is set according to the current mode (in the end mode, the advantageous section ends after 32 games have passed (cleared accordingly), so it is not set. may be set), the pseudo-bonus ends ("pseudo-bonus ends" in FIG. 5), and the transition is made to the effect section (normal game).

In addition, if you win the ceiling shortening lottery and you also have 1G consecutive stock, the result of the ceiling shortening lottery will be prioritized, and after the pseudo bonus according to the ceiling shortening is executed, the pseudo bonus according to the 1G consecutive stock will be given. Alternatively, the 1G ream stock may be given priority, and after the pseudo bonus corresponding to the 1G ream stock is executed, the pseudo bonus corresponding to the ceiling reduction may be executed. In the latter case, it is sufficient to separately store information that can carry over the fact that the ceiling is shortened.

In the first game machine, as an example of the configuration of the increase section (pseudo-bonus), it is possible to obtain a maximum of 275 cards by continuing for "55 games", but the configuration of the pseudo-bonus is limited to this. do not have. For example, the pseudo-bonus is configured as a "pseudo BB (big bonus)", and a "pseudo-RB (regular bonus)", which is a pseudo-bonus that continues for "22 games" and allows up to 110 cards to be obtained, is installed. You may do so. In this case, in the above-mentioned pseudo-bonus transition lottery, when reaching the ceiling, and 1G consecutive lottery, when it is decided to move to a pseudo-bonus (to grant rights), the type (for example, "pseudo BB" and or "pseudo RB") is determined with a predetermined probability (for example, each 50%). It should be noted that the value of the "pseudo RB" differs from that of the "pseudo BB" (more specifically, the value of the "pseudo BB" is lower than that of the "pseudo BB"). BB", but by lowering the bernavi rate (probability of notification of stop operation information), it is possible to make a difference in the maximum obtainable number of sheets and to make the value different. Further, when the "pseudo RB" is started, a reel effect in which "BAR" symbols are displayed together in the main display window 4, or a reel effect in which "red 7-red 7-BAR" is displayed is performed. You should do it like this. Furthermore, the increasing section is not limited to being configured as a pseudo bonus. For example, it can be configured as an AT state or an ART state in which the number of games to be continued (game period) can be changed.

Also, during the pseudo-bonus, if the conditions for executing limit processing shown in FIG. ), resulting in transition to a non-advantageous section.

In addition, in the first gaming machine, the above-described game flow is based on the premise that the game is basically played in a three-coin bet state. Therefore, when a game is played with two bets, various lotteries using, for example, (a) to (d) of FIG. 7, (e) and (f) of FIG. The number of ceiling games is not updated either. In addition, when a game is played with two coins bet during the pseudo bonus, since the number of medals is not increased in the state of two bets, the interval during the pseudo bonus is not increased. In other words, the first gaming machine is configured such that the player is basically at a disadvantage when playing a game in a two-coin bet state.

Here, when the game is played with two bets, lotteries related to the advantageous section (AT) (for example, (a) to (d) in FIG. 7, (e) and (f) in FIG. 8, etc. are used). Although various lotteries and processing (for example, updating the ceiling game number, etc.) are not performed, the advantageous section game number counter for the above-mentioned game number limiter and the advantageous section payout number counter for the above-mentioned payout number limiter are updated. should be carried out. These limiters have the function of appropriately suppressing gambling by limiting the upper limit of the number of games you can stay in the advantageous section and the number of winning cards, so if you bet two cards, these counters will not be updated. As a result, there may be cases where the upper limit of the number of staying games or the number of winning cards in the set advantageous section is exceeded due to the intervening game with two bets, and as a result, the gambling aspect cannot be suppressed appropriately. in order to obtain
Therefore, the limiter counter is desirably configured so that it can be updated every game regardless of the number of bets.

In addition, in the first gaming machine, the above-described game flow is basically based on the premise that the game is played in the non-bonus state. Therefore, when a game is played in the bonus state (2BB state and 3BB state), for example, various lotteries using (a) to (d) in FIG. 7, (e) and (f) in FIG. It is not performed, and the number of ceiling games is not updated. In addition, when the bonus state occurs during the pseudo-bonus, the bonus state is configured as a state in which the expected increase in medals is lower than in the non-bonus state (more specifically, in the non-bonus state with three bets). , In some cases, the pseudo bonus does not become an increase section. That is, the first gaming machine is constructed so that the player may be at a disadvantage if he/she plays the game in the bonus state.

Therefore, in the first gaming machine, it is recommended to play a game with a 3-card bet state between 2BB flags (in this embodiment, the 3-card bet state between 2BB flags is referred to as a "recommended game state”, and other states may be described as “non-recommended gaming states”). That is, in the first gaming machine, 2BB is a bonus combination that is won only when 2 symbols are bet, and between the 2BB flags, the combination of symbols related to 2BB wins only when 2 symbols are bet, and wins when 3 symbols are bet. It is configured not to Also, 3BB is a bonus combination that is won only when 3 symbols are bet, and between the 3BB flags, the combination of symbols related to 3BB wins only when 3 symbols are bet, and does not win when 2 symbols are bet. In addition, there is no case where 3BB wins between 2BB flags, and there is no case where 2BB wins between 3BB flags.

Then, in the first gaming machine, using these configurations, for example, 2BB is won in the 2-card bet state between non-flags (2BB is not won), and then 3-card bet state after 2BB flags are won. , the game can be played in the above-described recommended game state without worrying about whether or not the bonus combination is won.

As described above, in the first gaming machine, the ceiling reduction lottery is performed during the pseudo bonus. Here, looking at the ceiling shortening lottery table shown in FIG. While the ceiling reduction lottery is won with a probability of /8 (32/256), the ceiling reduction lottery is not won in other modes. That is, in the case of a mode with a ceiling number of games of "32 games", the "32 games" may be shortened to "0 games", and in the case of a mode with a ceiling number of games greater than that, There is no case where the number of ceiling games is shortened.

Even in a mode with a ceiling number of games greater than "32 games", the number of ceiling games is lower than in a mode with a ceiling number of games of "32 games" may be determined to be shortened.

Also, the manner in which the number of ceiling games is shortened is not limited to that described above. For example, if "32 games" is shortened to a predetermined number of games (0 to 31 games) that are smaller than that, the same effect can be exhibited, so that the number of games to be shortened will be further determined when the ceiling shortening lottery is won. Alternatively, in the ceiling reduction lottery, the number of games to be shortened may be determined in advance.

Further, the trigger for performing the ceiling reduction lottery is not limited to the above. For example, during the pseudo-bonus, a ceiling-shortening lottery may be performed for each game. Also, in the advantageous section (normal game), when the current mode is one of the security mode, heaven A mode, heaven B mode, and heaven C mode, a ceiling shortening lottery will be performed for each game. can be In these cases, the sub-flag for advantageous section winning and the sub-flag for advantageous section winning may be referenced to determine whether or not the ceiling reduction lottery is won.

Further, as described above, in the first gaming machine, a 1G consecutive lottery is performed during the pseudo bonus. Here, looking at the 1G run lottery table shown in (d) of FIG. 7, 1G run stock may be awarded regardless of the current mode. That is, the right to continue the pseudo-bonus can be granted regardless of whether the mode is the ceiling game number of "32 games" or not.

Note that the mode of granting the right is not limited to the one described above. For example, when the number of ceiling games is "32 games", the 1G consecutive lottery is not performed in consideration of the fact that the ceiling short lottery is performed, and the number of ceiling games is greater than "32 games". By performing the 1G consecutive lottery when , it is possible to prevent the gambling aspect of the game from becoming excessively high.

Further, the trigger for performing the 1G consecutive lottery is not limited to the one described above. For example, a 1G run lottery may be performed even in an advantageous section (performance section) other than the pseudo bonus, and the 1G run stock stocked as a result may be consumed in the next pseudo bonus.

Although not shown in FIGS. 5 to 8, in the first gaming machine, when the current mode is heaven mode at the start of the pseudo-bonus or during the pseudo-bonus, it is in an advantageous state. A special bonus mid-effect for suggesting something is executed with a predetermined probability. Therefore, when the special bonus middle effect is executed, it is possible to expect that the ceiling reduction lottery will be executed. In addition, the effect during the special bonus may be executed with a probability of 100% when the ceiling reduction lottery is won. In this way, for example, when the special bonus mid-effect is executed at the start of the pseudo-bonus, it is suggested that the player is staying in the heaven mode at least, and furthermore, it is expected that the player may have won the ceiling reduction lottery. can make you feel. Further, the effect during the special bonus may be executed at a predetermined probability or at a probability of 100% even when the 1G consecutive lottery is won during the pseudo bonus. In this way, (1) heaven mode only, (2) heaven mode + ceiling short winning, (3) heaven mode + 1G consecutive winning, (4) heaven mode + ceiling short winning + 1G consecutive winning, (5) 1G consecutive winning Various possibilities, such as winning only, can be suggested, and the amusement of the game can be improved.

Thus, in the first gaming machine, when it is confirmed that the advantageous state (for example, pseudo-bonus) will be controlled again within a predetermined period (for example, 32 games) after the end of the advantageous state (for example, , heaven mode), the period can be further shortened, so even if the game period of a series of advantageous intervals is limited (for example, when limit processing is executed), the player can It is possible to prevent the loss of interest in the game by allowing the game to be played in a state where the degree of advantage is as high as possible.

In addition, in the first gaming machine, even if it is not confirmed that the advantageous state will be controlled again within a predetermined period after the advantageous state ends (for example, in the end mode), the right (for example, , 1G ream stock) may start the advantageous state again, so the expectation of the player can be heightened and the interest in the game can be improved.

Further, although not shown in FIGS. 5 to 8, in the first gaming machine, when a “fixed combination” is determined as a sub-flag at the time of winning an advantageous section (that is, “F_fixed cherry” or “F_ If "reach" is determined as an internal winning combination), and as a result of the above mode transition lottery, if it is determined to shift to heaven C mode, the probability is 1/2 (this probability is arbitrary ), a special lock effect can be executed. It should be noted that even when the advantageous section winning sub-flag "Medium Che" is determined (i.e., when "F_middle cherry" is determined as the internal winning combination), the player can set the advantageous section winning sub-flag "Fixed hand". ” is determined, so if the sub-flag “Medium Che” is determined when winning the advantageous section, it is possible to receive the same benefits as when “fixed hand” is determined as the sub-flag when winning the advantageous section. Similarly, a special lock effect may be made executable.

Here, since the "fixed combination" is a combination that also confirms the transition to the pseudo-bonus (see (c) in FIG. 7), when the special lock effect is executed, the player can transition to the pseudo-bonus and heaven C mode. It is possible to recognize that there was a problem, and the interest is greatly increased for the player. The special lock effect is, for example, an effect in which the game operation (stop operation) is disabled for about 20 seconds at the start of the game. During this period, a special reel effect may be performed in which each reel vibrates or rotates in the reverse direction, or a special image or the like that is not normally displayed may be displayed on the main effect display section 21. can be Also, a special piece of music that is not normally output may be output. Of course, it is also possible to produce an effect by combining these. In addition, the game operation is not invalidated, but these effects can be performed until the player performs the next game operation (that is, the effect can be executed to the end or canceled halfway). The player may be allowed to decide whether to proceed with the game).

However, in the first gaming machine, as shown in FIG. 16, which will be described later, for example, even if the user stays in Heaven C mode, the execution of limit processing may force the advantageous section to end. , it may not be desirable to perform the special lock effect described above many times.

Therefore, in the first gaming machine, the special lock effect is executed only once within the same series of advantageous sections. Specifically, in a series of advantageous sections, when it is decided to execute a special lock effect first, the special lock effect is executed, but after that, within the same series of advantageous sections, the same conditions apply. To control so that a special lock performance is not executed even when it is established. In addition, as a method, when the special lock effect is executed once, information indicating that fact is stored, and after that, if the information is stored in the same series of advantageous sections, the special lock effect is performed in the first place. The decision as to whether or not to execute the effect may not be made, or the decision may be made, but when the information is stored, the result of the decision indicates that the effect is to be executed. may be rewritten to indicate that it is not executed. Then, the stored information may be cleared when the advantageous section ends.

Note that the manner in which execution of the special lock effect is restricted is not limited to the above. For example, the upper limit number of times that the execution of the special lock effect is restricted may be set as "two times" or "three times" instead of "one time". That is, the execution of the special lock effect is limited, but the upper limit may be set as multiple times. This can be appropriately set according to the expected value of the number of balls to be released per special lock effect.

Further, the conditions for determining whether or not the special lock effect is to be executed are not limited to those described above. That is, in the above, the mode transition is performed with the winning of the "fixed combination" as a trigger, and on the condition that the mode is Heaven C mode, it is determined whether or not the special lock effect is to be executed. However, for example, there are cases where the transition to heaven C mode is triggered by a trigger other than the winning of the "fixed hand" (see (f) in FIG. 8), so the special lock effect is executed in these cases as well. A special lock effect is executed with a predetermined probability (the probability may be the same as in the case of winning a “fixed hand”, or the probability may be different). It may be determined that

Further, for example, it is assumed that, with the winning of the "fixed combination" as a trigger, first, whether or not the special lock effect is to be executed is determined, and when it is determined that the special lock effect is to be executed, the heaven You may make it transfer to C mode. That is, the special lock effect may be executed in response to the determination to shift to the heaven C mode, or the heaven C mode may be executed in response to the determination to perform the special lock effect. You may make it shift to .

Further, for example, the degree of progress of the game during the advantageous section may be employed as the condition for determining whether or not the special lock effect is to be executed. For example, when the value of the advantageous section game number counter or the control game number counter, which will be described later, is less than "750", or when the value of the advantageous section payout number counter, or the control game number counter, which will be described later is less than "1201". , it is determined whether or not the special lock effect is to be executed as described above, and when the value of the advantageous section game number counter or the control game number counter described later becomes "750" or more, or when the advantageous game number counter described later becomes "750" or more When the value of the section payout number counter or the payout number counter for control reaches '1201' or more, it is not determined whether or not the special lock performance is to be executed in the same series of advantageous sections thereafter. can also

Thus, in the first gaming machine, the game period of the series of advantageous sections is limited to a fixed period (see FIG. 16 described later). In the same series of advantageous sections, even if control information with a high degree of advantage for the player (for example, heaven C mode) is set multiple times, a special effect (for example, a special lock effect) is generated each time. is controlled so as not to occur. Therefore, it is possible to prevent the game from becoming less interesting while preventing the gambling aspect of the game from becoming excessively high.

Further, in the first gaming machine, in a series of advantageous sections, it is determined that control is performed in an advantageous state (for example, a pseudo-bonus) upon winning of a specific combination (for example, a "fixed combination"). , control information that is highly advantageous to the player (for example, Heaven C mode) may be set. Even if such a case occurs multiple times within the same series of advantageous sections, control is performed so that the special effect (for example, special lock effect) is not performed each time. Therefore, it is possible to prevent the game from becoming less interesting while preventing the gambling aspect of the game from becoming excessively high.

Further, in the first gaming machine, it is possible to determine secondary information (for example, a sub-flag at the time of advantageous section winning) according to the determined internal winning combination, and secondary information according to the combination of displayed symbols ( For example, it is possible to determine an advantageous zone winning sub-flag), and whether or not to give an advantageous state (for example, pseudo bonus) in which information about the player's stop operation is notified according to the determined secondary information It is determinable.

As described above, in the first gaming machine, not only when the internal winning combination is determined, but also when the combination of symbols is displayed, it is possible to give a sense of expectation regarding the provision of an advantageous state. It is possible to diversify the playability related to giving.

Further, in the first gaming machine, information corresponding to the determined internal winning combination and information corresponding to the combination of displayed symbols are both managed as common secondary information. It is possible to suppress an increase in the control load and the amount of information regarding provision.

Further, in the first gaming machine, when the gaming value bet is the first amount (for example, 3 coins), the first special role (for example, 3BB) can be won, while the second special role (for example, , 2BB) are not allowed to be won. Further, when the gaming value bet is the second amount (for example, 2), the second special combination is allowed to be won, but the first special combination is not allowed to be won. Further, when a specific combination (for example, "F_replay A") is won, if the first special permission state (for example, between 3BB flags) is displayed, a combination of predetermined symbols (for example, "rising right") is displayed. If there are 2 special permission states (for example, between 2 BB flags), it is possible to display a combination of specific symbols (for example, "parallel lips") (see FIG. 15, which will be described later).

In the first gaming machine, different secondary information can be determined depending on whether a combination of predetermined symbols is displayed or a combination of specific symbols is displayed. That is, in the first gaming machine, even when the same special role is determined, the content of the decision regarding the granting of the advantageous state can be changed according to which special permission state is in effect. It is possible to further diversify the playability while suppressing an increase in the control load and the amount of information regarding the provision of states.

Further, in the first gaming machine, it is possible to determine whether or not to provide an advantageous state at least when a specific combination is won and a combination of specific symbols is displayed.

Here, in the first gaming machine, since both the combination of the predetermined symbols and the combination of the specific symbols are combinations of symbols related to replay, even if either one is displayed, it is called an operation of replay. The same benefits will be granted.

Note that the manner in which the same privilege is granted is not limited to the above. For example, the specific winning combination is configured as a specific small winning combination for giving a game value. Then, when a specific minor combination is won, for example, in the first special permission state, one coin (this value is arbitrary, and may be another value equal to or lower than the bet gaming value, or bet display a combination of predetermined symbols (combination of symbols pertaining to the granting of game value corresponding to "rising to the right") to which a game value is awarded (which may be a value exceeding the game value of the second special permission); If so, the combination of specific symbols (combination of symbols related to the granting of game value equivalent to "parallel lip") that gives the same number of game values as when the combination of predetermined symbols is displayed is displayed. may

In addition, both the combination of predetermined symbols and the combination of specific symbols are combinations of “lost” symbols (however, since it is possible to determine whether or not to give an advantageous state, a different symbol from the case of pure “losing”) A combination of identifiable symbols may be used). Even in this case, the value remains the same.

As described above, in the first gaming machine, even when the same special combination is determined, depending on which special permission state it is in, the content of determination regarding the provision of an advantageous state can be changed. , it is possible to diversify the playability while suppressing an increase in the control load and the amount of information regarding the provision of the advantageous state. In addition, in a game in which a specific combination is determined, the same privilege is granted regardless of the special permission state, so even if the game characteristics are changed, the player will not be directly disadvantaged. It is possible to prevent it from being covered.

Further, in the first gaming machine, when the specific combination is won, when the second special permission state is established, when the stop operation is performed in the specific mode, the combination of the specific symbols can be displayed. It may be configured so as not to allow the combination of specific symbols to be displayed when the stop operation is not performed in the mode.

Then, it may be possible to decide whether or not to give an advantageous state at least when a specific combination is won and a combination of specific symbols is displayed. If the specific combination is determined as an internal winning combination, even if it is possible to make the degree of advantage in giving an advantageous state different between when the combination of specific symbols is displayed and when the combination of specific symbols is not displayed. good.

Further, when a specific combination is won, if the first special permission state is established, a combination of predetermined symbols is displayed regardless of the stop operation mode, and if the second special permission state is established, the stop operation is performed in a specific mode. is performed, a combination of specific symbols may be displayed, and when a stop operation is not performed in a specific mode, a combination of predetermined symbols may be displayed.

In this case, the specific combination is determined when the timing of the stop operation is appropriate for at least one reel (in this embodiment, this may be described as "pressed position ○" or "correct pressed position"). When a combination of specific symbols is displayed and the timing of the stop operation is not appropriate (in this embodiment, this may be described as "pressed position x" or "incorrect pressed position"), the combination of predetermined symbols is displayed. Can be configured as displayed. As a result, the degree of advantage in giving an advantageous state can be varied due to (the timing of) the player's stop operation, so the player can concentrate more on the game, and the interest in the game can be improved. can.

Further, as described above, the specific combination can also be configured as a specific small combination. In this case, when the timing of the stop operation is appropriate for at least one reel (in the case of the pressed position ◯), the specific symbol is displayed. A combination is displayed and a predetermined number of game values are awarded, and when the timing of the stop operation is not appropriate (in the case of the pressed position x), a combination of predetermined symbols is displayed and a specific number of game values are awarded. can do. In this case, the predetermined number may be the same as the specific number (that is, the same privilege). Also, a predetermined number of game values may be awarded that is greater than the specific number. Alternatively, a predetermined number of game values may be awarded that is smaller than the specific number. Also, at least one of the combination of the specific symbols and the combination of the predetermined symbols may be used as the combination of symbols when a failure occurs. That is, either the predetermined number or the specific number may be set to "0". As a result, it is possible not only to change the degree of advantage related to the provision of an advantageous state due to (the timing of) the player's stop operation, but also to directly change the content of the privilege, so that the player can The player can concentrate more on the game, further diversify the playability, and improve the amusement of the game.

Also, if there is only one type of specific combination, the timing at which the stop operation is appropriate is limited, so it is desirable to provide a plurality of specific combinations with different timings at which the stop operation is appropriate. For example, in one reel, when the timing of the stop operation is the first timing, an appropriate stop operation is performed and a combination of specific symbols is displayed, and when the timing is other than the first timing, the appropriate stop operation is performed. When the timing of the stop operation is the second timing different from the first timing, the proper stop operation is performed and the combination of the specific symbols is displayed. When the timing is other than the second timing, there is no proper stop operation and the combination of specific symbols is not displayed, and the timing of the stop operation is the first timing and the second timing. When the third timing is different, an appropriate stop operation is performed and the combination of the specific symbols is displayed, and when the timing is other than the third timing, the appropriate stop operation is not performed and the combination of the specific symbols is not displayed. A third special combination may be provided, and these may be won with the same winning probability.

Also, in this case, for the specific combination, a combination of specific symbols is displayed when the batting order is appropriate (in the case of correct pressing order), and a combination of predetermined symbols is displayed when the batting order is not appropriate (in the case of incorrect pressing order). Can be configured as displayed. As a result, the degree of advantage for giving an advantageous state can be changed due to the player's stop operation (procedure), so the player can concentrate more on the game, and the interest in the game can be improved. can.

Further, the specific combination can be configured as a specific small combination as described above. In this case, when the batting order is appropriate (in the case of the correct order), a combination of specific symbols is displayed and a predetermined number of games are played. Values are given, and when the batting order is not appropriate (in the case of incorrect answer pressing order), a combination of predetermined symbols is displayed and a specific number of game values are given. In this case, the predetermined number may be the same as the specific number (that is, the same privilege). Also, a predetermined number of game values may be awarded that is greater than the specific number. Alternatively, a predetermined number of game values may be awarded that is smaller than the specific number. Also, at least one of the combination of the specific symbols and the combination of the predetermined symbols may be used as the combination of symbols when a drop occurs. That is, either the predetermined number or the specific number may be set to "0". As a result, it is possible not only to change the degree of advantage related to the provision of an advantageous state due to the player's stop operation (procedure), but also to directly change the content of the privilege, so that the player can The player can concentrate more on the game, further diversify the playability, and improve the amusement of the game.

Also, if there is only one specific combination, the appropriate batting order is also limited, so it is desirable to provide a plurality of specific combinations with different appropriate batting orders. For example, when it is the first stop on the left, an appropriate stop operation is performed and a combination of specific symbols is displayed, and when it is the first stop on the center and right, an appropriate stop operation is not performed and the combination of specific symbols is not displayed. When it is the first specific combination and the middle first stop, the combination of specific symbols is displayed as an appropriate stop operation, and when it is the left/right first stop, the specific symbols are displayed without an appropriate stop operation. The second special combination is not displayed, and when it is the first stop on the right, it is an appropriate stop operation and the combination of specific symbols is displayed, and when it is the first stop on the left and middle, it is not an appropriate stop operation. A third specific combination in which a combination of specific symbols is not displayed is provided in the third combination, and these can be won with the same winning probability.

Up to this point, in the unit game in which the specific role is won, due to the stop operation mode (at least one or both of the timing of the stop operation and the batting order), the transition determination process to the advantageous section in the non-advantageous section, and the advantageous section (Including pseudo-bonus transition lottery, mode transition lottery, and other processing for changing the advantage of the gaming situation in the advantageous section) regarding the granting of an advantageous state. Of these, changes that are relatively disadvantageous to the player (which may be disadvantageous as a result) can be regarded as the penalties described above. Therefore, when such a change occurs, the configuration may be such that an arbitrary effect (warning notification) for calling attention can be generated.

In addition, in the first gaming machine, when a specific combination is won, the possibility of providing an advantageous state is higher when a combination of specific symbols is displayed than when a combination of predetermined symbols is displayed. It's becoming That is, assuming that three cards are bet, the second special permission state (for example, between 2BB flags) is a state in which an advantageous state is given more preferentially than the first special permission state (for example, between 3BB flags). is.

In addition, in the first gaming machine, when a predetermined combination (for example, "push order bell B" described later) is won, if the first special permission state is met, the combination of given symbols (for example, 8 payouts) regardless of the batting order While the combination of symbols to become) is displayed, in the second special permission state, if the hitting order is the predefined correct answer pressing order, the combination of the given symbols is displayed, but the hitting order is predefined If it is not in the given correct order of pressing, the combination of given symbols is not displayed, and the game value is not given, or only a smaller amount of game value is given than when the combination of given symbols is displayed. It is configured to display a combination of symbols (for example, a combination of symbols that results in one payout). That is, if the operation of the advantageous state is not taken into consideration, the first special permission state is a state in which the provision of game value is given more preferentially than the second special permission state.

That is, even if the player is in the non-recommended gaming state, if the player plays the game with three bets between the 3BB flags, the probability of giving the advantageous state is not favored, but the game value when the advantageous state is not activated is increased. Since the award probability is given preferential treatment, the game can be played in a state in which the difference in slope value between when the advantageous state is activated and when it is not activated is relatively small. In this way, a state in which the player's game value is less likely to decrease, although the possibility of the player's game value being able to increase rapidly decreases, can be defined as, for example, a "stable state".

On the other hand, if the player plays the game in the recommended game state, the probability of giving the advantageous state is preferential, but the probability of giving the game value when the advantageous state is not activated is not favored, so the advantageous state is activated. The game can be played in a state in which the difference in the tilt value between when it is activated and when it is not activated is relatively large. In this way, a state in which the player is likely to be able to rapidly increase the game value, but the game value of the player is likely to decrease can be defined as, for example, a “stormy state”.

Here, the method for creating the two states of the stable state and the rough sea state is not limited to the one described above. For example, in the "stable state", in the above-mentioned pseudo-bonus transition lottery, while raising the probability of transition of the pseudo-bonus more than "rough sea state", in the above-mentioned mode transition lottery, the probability of transition to heaven mode is higher than "rough sea state" Lower. In addition, in the "rough sea state", in the above-mentioned pseudo-bonus transition lottery, while lowering the transition probability of the pseudo-bonus than in the "stable state", in the above-mentioned mode transition lottery, the transition probability of heaven mode Increase. In this way, it is possible to create a state in which it is easy to hit the pseudo-bonus at the beginning in the "stable state" but it is difficult to make a succession. state can be created. As described above, the predetermined combination stop control may vary between the 2BB flags and the 3BB flags, or may be different (that is, no preferential treatment between the 3BB flags).

[5-2. Symbol arrangement configuration of the first gaming machine]
Next, referring to FIG. 9, the symbol arrangement configuration of the first gaming machine will be described. FIG. 9 is a diagram showing an example of the symbol arrangement table of the first gaming machine. As shown in FIG. 9, in the first gaming machine, "red 7", "BAR", "replay", "bell", "watermelon", "cherry", "red blank", "yellow blank", " 10 kinds of patterns of "white blank 1" and "white blank 2" are arranged at the positions shown in FIG. 9 on each of the reels 3L, 3C and 3R. Further, as shown in the symbol code table, symbol codes 1 to 10 are assigned to each symbol.

[5-3. Internal Winning Combination Configuration of First Gaming Machine]
Next, with reference to FIGS. 10 to 15, the internal winning combination configuration of the first gaming machine will be described. FIG. 10 is a diagram showing an example of the internal lottery table of the first gaming machine. 11 to 14 are diagrams showing an example of the symbol combination table of the first gaming machine. Also, FIG. 15 is a diagram showing an example of the correspondence relationship between the internal winning combination, the stop operation mode, the display combination, etc., of the first gaming machine.
That is, hereinafter, which symbol is selected according to the type of internal winning combination that is drawn by lottery in the first gaming machine, and the stop operation mode (that is, the batting order, stop operation timing, etc.) when each internal winning combination is won. (which can also be rephrased as a display combination, a winning combination, a stop display mode, a display result, etc.) will be displayed.

First, in the first gaming machine, in the internal lottery process (see FIG. 26) described later, each internal winning combination shown in FIG. 10 is won with the probability shown in FIG. Combinations of symbols permitted to be displayed when each internal winning combination is won are as shown in "corresponding symbol combination" in FIG. In FIGS. 11 to 14, "BB" indicates a combination of symbols for a bonus combination, "REP" indicates a combination of symbols for a replay combination, and "FRU" indicates a combination of symbols for a minor combination. is shown.

"F_2BB" can be determined as an internal winning combination when a game is played in a non-bonus state (more specifically, between non-flags) in a 2-coin bet state, while a game is played in a 3-coin bet state. It is configured not to be determined as an internal winning combination when the winning combination is determined. In a game in which "F_2BB" is won in a two-bet state, or in a game in which "losing" between 2BB flags, "BB01" is displayed if the pressed position is ○ for each reel, and a 2BB state (based on 2BB) is displayed. bonus status). On the other hand, even between two BB flags, "BB01" is not displayed when three cards are bet.

"F_3BB" can be determined as an internal winning combination when a game is played in a non-bonus state (more specifically, between non-flags) in a 3-coin bet state, while a game is played in a 2-coin bet state. It is configured not to be determined as an internal winning combination when the winning combination is determined. In a game in which "F_3BB" is won in a 3-bet state, or in a game in which "losing" between 3BB flags, "BB02" is displayed if the pressed position is ○ for each reel, and the 3BB state (based on 3BB) is displayed. bonus status). On the other hand, even between the 3BB flags, "BB02" is not displayed when two cards are bet.

In the 2BB state and the 3BB state, the lottery value in the "bonus state" column in FIG. 10 is referred to determine the internal winning combination (the number of possible coins to start the game is only 3 bets). During the 2BB state and the 3BB state, it is controlled to the state (RB state) in which the RB, which is the first class special bonus, is always in operation. In addition, in the RB state, control is repeated such that when winning occurs twice or the game is played twice after activation, the control is once terminated and then activated again. In addition, in the first gaming machine, the condition for ending the 2BB state is that more than one medal has been paid out in the 2BB state, and the condition for ending the 3BB state is that more than 176 medals have been paid out in the 3BB state. has been paid out.

Here, when the 2BB state or the 3BB state ends, special mode transition processing is performed. For example, if the current mode is the "start mode", the transition destination mode is "start mode". Also, if the current mode is one of the "normal A mode", "normal B mode", "paradise preparation mode", and "chance mode", the transition destination mode is the "normal A mode". Also, if the current mode is either "end A mode" or "end B mode", the transition destination mode is "end A mode". Also, if the current mode is any one of "guaranteed mode", "heaven A mode", "heaven B mode", and "heaven C mode", the destination mode will be "guaranteed mode".

"F_Replay A" is configured to be determined as an internal winning combination regardless of the number of bets in the non-bonus state. If it is determined as an internal winning combination, between non-flags and between 2BB flags, regardless of the stop operation mode, one of "REP64" to "REP72" Since these are to be displayed, they can be collectively called “parallel lips.” Also, “REP64” to “REP71” can be collectively called “lower stage lips.” ) is displayed and replay is awarded. On the other hand, between the 3BB flags, regardless of the stop operation mode, "REP73" (because this is to display the "Replay" symbol in an upward-sloping manner, this can be called an "upward-sloping lip"). It is displayed and replay is granted.

"F_Replay B" is configured to be determined as an internal winning combination regardless of the number of bets in the non-bonus state. It should be noted that the internal winning combination can be determined in the 3-coin bet state, but it can be configured so that the internal winning combination is not determined in the 2-coin bet state. When the internal winning combination is determined, "parallel replay" is displayed regardless of the stop operation mode in any state, and a replay is awarded.

"F_Cherry" is configured to be determined as an internal winning combination regardless of the number of bets in the non-bonus state. It should be noted that the internal winning combination can be determined in the 3-coin bet state, but it can be configured so that the internal winning combination is not determined in the 2-coin bet state. When the internal winning combination is determined, in the double-bet state, the "middle stage reply" is displayed regardless of the stop operation mode, and a replay is awarded. In the 3-card bet state, any one of "REP28", "REP60" to "REP63" if the pressed position is ○ for at least the left reel 3L (these are for displaying the "cherry" symbol on the lower row of the left reel 3L). Therefore, these can be collectively referred to as "cherry lips") are displayed, and a replay is granted. On the other hand, if the pressed position is x, other replies (for example, "REP57" to "REP59") are displayed and a replay is granted.

"F_definite cherry" is configured to be determined as an internal winning combination regardless of the number of bets in the non-bonus state. It should be noted that the internal winning combination can be determined in the 3-coin bet state, but it can be configured so that the internal winning combination is not determined in the 2-coin bet state. When the internal winning combination is determined, in the double-bet state, the "middle stage reply" is displayed regardless of the stop operation mode, and a replay is awarded. In the 3-card bet state, if the pressing order is any of "batting order 1" to "batting order 4", at least for the left reel 3L, if the pressing position is ○, any of "REP42" to "REP56" (these are The symbol "Cherry" is displayed in the lower part of the left reel 3L. For example, symbols such as "REP42" are also displayed on the other reels to increase the expectation of the player. (which can be collectively referred to as "determined cherry slip") is displayed, and a replay is granted. On the other hand, if the pressed position is x, other replies (for example, the above-mentioned "Cherry Lip" or "REP29" to "REP41") are displayed, and a replay is awarded. In addition, when the pressing order is either "Battering order 5" or "Battering order 6", the "middle stage reply" is displayed regardless of the stop operation mode, and a replay is awarded.

"F_middle cherry" is configured to be determined as an internal winning combination regardless of the number of bets in the non-bonus state. It should be noted that the internal winning combination can be determined in the 3-coin bet state, but it can be configured so that the internal winning combination is not determined in the 2-coin bet state. When the internal winning combination is determined, in the double-bet state, the "middle stage reply" is displayed regardless of the stop operation mode, and a replay is awarded. In the 3-card bet state, if the pressing order is any of "batting order 1" to "batting order 4", at least for the left reel 3L, if the pressing position is ○, any of "REP15" to "REP19" (these are Since the "cherry" symbol is displayed in the middle row of the left reel 3L, these can be generically called "middle stage cherry lips") are displayed, and a replay is awarded. On the other hand, if the pressed position is x, other replies (for example, "REP20" to "REP27") are displayed, and a replay is granted. In addition, when the pressing order is either "Battering order 5" or "Battering order 6", the "middle stage reply" is displayed regardless of the stop operation mode, and a replay is awarded.

"F_Reach" is configured to be determined as an internal winning combination regardless of the number of bets in the non-bonus state. It should be noted that the internal winning combination can be determined in the 3-coin bet state, but it can be configured so that the internal winning combination is not determined in the 2-coin bet state. When the internal winning combination is determined, in the double-bet state, the "middle stage reply" is displayed regardless of the stop operation mode, and a replay is awarded. In the 3-bet state, if the pressing order is any of "batting order 1" to "batting order 4", regardless of the stop operation mode, any one of "REP01" to "REP14" (these are customarily used by players It is configured as a combination of symbols that can confirm (or suggest) a transition to a state that is advantageous to the player, and these can be collectively referred to as "reach eyes") is displayed, and replay is possible. Granted. In addition, when the pressing order is either "Battering order 5" or "Battering order 6", the "middle stage reply" is displayed regardless of the stop operation mode, and a replay is awarded.

"F_Watermelon" is configured to be determined as an internal winning combination regardless of the number of bets in the non-bonus state. If it is determined as an internal winning combination, if the pressed position is ◯ for each reel, one of “FRU10” to “FRU12” (since these are displayed side by side with “watermelon” symbols, these are selected). "watermelon") is displayed, and three medals are paid out if three medals are bet, and two medals are paid out if two medals are bet. On the other hand, if the pressed position is x, either "FRU08" or "FRU09" (because these are not displayed with "watermelon" symbols side by side, they can be collectively called "watermelon spill"). is displayed and one medal is paid out. It should be noted that, in the case of the pressed position x, it is also possible to cause a dropout to occur so that no medals are paid out.

"F_bell 123A1", "F_bell 123A2", "F_bell 132A1", "F_bell 132A2", "F_bell 213A1", "F_bell 213A2", "F_bell 231A1", "F_bell 231A2", "F_ "Bell 312A1", "F_Bell 312A2", "F_Bell 321A1", and "F_Bell 321A2" can be determined as internal winning combinations regardless of the number of bets in the non-bonus state. It should be noted that these can be collectively referred to as "push order bell A".

As shown in FIG. 15, "push order bell A" is a small push order combination with 6 choices (any one of "hitting order 1" to "hitting order 6" is the correct hitting order). , and when it is determined as an internal winning combination, when the stop operation is performed in the corresponding correct order of pressing, "Right falling bell" ("FRU03"), "Upper bell" ("FRU01" and "FRU02") ), "middle bell" ("FRU04"), "right rising bell" ("FRU05"), "mountain bell" ("FRU06"), and "lower bell" ("FRU07") is displayed, and 8 medals are paid out if 3 medals are bet, and 2 medals are paid out if 2 medals are bet. On the other hand, when the stop operation is not performed in the corresponding correct order of pressing, if the first stop operation is correct, the rest of the stop operations have a probability of 1/2 at the pressed position ◯, and at the pressed position ◯. If there is, one of the winning "one-coin" ("FRU13" to "FRU116") is displayed, and one medal is paid out. On the other hand, if the pressed position is x, a drop occurs and medals are not paid out. In addition, if the first stop operation is not correct, the rest of the stop operations have a probability of 1/8 that the pressed position will be ◯, and if the pressed position is ◯, any of the winning “one-card roles” will be displayed. , one medal is paid out. On the other hand, if the pressed position is x, a drop occurs and medals are not paid out.

"F_bell 123B1", "F_bell 123B2", "F_bell 132B1", "F_bell 132B2", "F_bell 213B1", "F_bell 213B2", "F_bell 231B1", "F_bell 231B2", "F_ "Bell 312B1", "F_Bell 312B2", "F_Bell 321B1", and "F_Bell 321B2" can be determined as internal winning combinations regardless of the number of bets in the non-bonus state. It should be noted that these can be collectively referred to as "push order bell B".

As shown in FIG. 15, the "push order bell B" does not have a small push order win between the 3BB flags in the 2-bet state and the 3-bet state. When an internal winning combination is determined, one of the above-described "bells" is displayed regardless of the stop operation mode, and if 3 medals are bet, 8 medals are paid out, and if 2 medals are bet, 2 medals are paid out. medals are paid out.

Further, as shown in FIG. 15, the "push order bell B" is pressed in states other than between the 3BB flags in the 3-bet state (between the non-flags in the 3-bet state and between the 2BB flags in the 3-bet state). If the winning combination is determined as an internal winning combination, and if the stop operation is performed in the corresponding correct order, one of the above-described "bells" will be displayed and eight medals will be awarded. paid out. On the other hand, when the stop operation is not performed in the corresponding correct order of pressing, if the first stop operation is correct, the rest of the stop operations have a probability of 1/2 at the pressed position ◯, and at the pressed position ◯. If there is, one of the winning "one-coin roles" is displayed, and one medal is paid out. On the other hand, if the pressed position is x, a drop occurs and medals are not paid out. In addition, if the first stop operation is not correct, the rest of the stop operations have a probability of 1/8 that the pressed position will be ◯, and if the pressed position is ◯, any of the winning “one-card roles” will be displayed. , one medal is paid out. On the other hand, if the pressed position is x, a drop occurs and medals are not paid out.

"F_RB combination 8 cards" is configured to be determinable as an internal winning combination in the bonus state. When the internal winning combination is determined, one of the above-described "bells" is displayed regardless of the stop operation mode, and 8 medals are paid out.

"One F_RB combination" is configured to be determinable as an internal winning combination in the bonus state. When it is determined as an internal winning combination, one of the above-mentioned "one-card combinations" (more specifically, "FRU117" to "FRU120" are added) is displayed regardless of the stop operation mode, and one card is displayed. medals are paid out.

The internal lottery table shown in FIG. 10, the symbol combination table shown in FIGS. 11 to 14, and the correspondence relationship between the internal winning combination, the stop operation mode, and the display combination shown in FIG. It is not limited to the embodiment.

For example, in the first gaming machine, in a 2-bet state in which ``BB01'' can be displayed when ``losing'', ``BB02'' can be displayed when ``BB01'' is missed and ``losing''. In the 3-bet state, when ``BB02'' is missed and ``losing'' occurs, and when ``losing'' occurs due to 3-betting between 2BB flags, it is 2-betting between 3BB flags. "Loss" may occur in various situations, such as when "losing" due to an event, or "losing" due to missing a "lower winning combination". Therefore, in order to make the combinations of symbols displayed as "lost" different in some or all of these cases, combinations of these different symbols are defined in advance in the symbol combination table, and the determined internal winning combinations are determined. By allowing these to be displayed as ``combination of corresponding symbols'' depending on the condition, the combination of symbols related to ``missing'' to be displayed according to the state or the like can be changed.

[5-4. Limit processing configuration of the first gaming machine]
Next, with reference to FIG. 16, the limit processing configuration of the first gaming machine will be described. FIG. 16 is a diagram for explaining an example of each limit process in the first gaming machine. As shown in FIG. 16, in the first gaming machine, normal limit processing (number of games), normal limit processing (number of payouts), special limit processing (number of games), special limit processing (number of payouts), semi-limit processing ( Number of games) and semi-limit processing (number of payouts) are executed. Note that this is an example of executable limit processing, and limit processing other than each of these limit processing can be executed. You can also prevent it from happening.

The normal limit process (the number of games) is executed when the value of the advantageous interval game number counter becomes "1500" or more (that is, when the game in the advantageous interval is played 1500 times in succession). In addition, the advantageous section game number counter starts counting the number of games played when the advantageous section (including the effect section) starts, and when the advantageous section ends (including the end due to the operation of the limit process) It is designed to be cleared (initialized) after completing the counting. Also, the number-of-games-in-advantage-zone counter counts whether the number of bets is two or three. In addition, the advantageous section game number counter performs the counting even in the 2BB state and the 3BB state.

When the normal limit processing (number of games) is executed (activated), regardless of whether it is during the production section or during the increase section (pseudo bonus), the advantageous section is forcibly ended, and the non-advantageous section move to Also, at this time, information about the advantageous section (for example, information for controlling the effect section or the increase section, information regarding the current mode, information regarding the game period of the pseudo bonus, information regarding the number of ceiling games and whether or not the ceiling is shortened) Information, various information obtained during the advantageous interval such as the value of the 1G ream stock counter, and various information necessary for controlling the advantageous interval) are all cleared (initialized).

The normal limit process (number of payouts) is executed when the value of the advantageous section payout number counter becomes "2401" or more (that is, when the number of medals paid out during the advantageous section exceeds 2400). The advantageous section payout number counter starts counting the number of medals paid out (here, for example, "net increase (difference number)") from the start of the advantageous section (including the performance section). When the interval ends (including the end due to the operation of the limit processing), the count is ended and cleared (initialized). Also, the advantageous section payout number counter counts both when the number of bets is 2 and 3. In addition, the advantageous section payout number counter performs the counting even in the 2BB state and the 3BB state. In addition, the advantageous section payout number counter counts appropriately according to the actual number of payouts (for example, "-2" or "-3") when, for example, "lose" or "dropout" occurs during the advantageous section. value is subtracted. Therefore, if the number of medals does not increase and decreases after the advantageous section starts, the value may be negative (or if the value is negative, "0" is always maintained). can also be configured to be That is, the advantageous section payout number counter can count the number of medals paid out in the advantageous section from the lowest point to the defined highest point (difference number: 2400 medals).

When the normal limit processing (number of payouts) is executed (actuated), regardless of whether it is in the production section or in the increase section (pseudo bonus), the advantageous section is forcibly terminated, and the non-advantageous section move to Also, at this time, all the information about the above-mentioned advantageous section is cleared (initialized).

The special limit process (the number of games) is executed when the value of the control game number counter becomes "1445" or more (that is, when the games in the advantageous section are played 1445 times in succession). In addition, the control game number counter starts counting the number of games played when the advantageous section (including the performance section) starts, and when the advantageous section ends (including the end due to the operation of the limit process) It is designed to be cleared (initialized) after completing the counting. Also, the control game number counter counts when the number of bets is three, and does not count when the number of bets is two. In addition, the control game number counter performs the counting in the non-bonus state, and does not perform the counting in the 2BB state and 3BB state. Of course, the control game number counter may have the same configuration as the advantageous section game number counter.

When the special limit processing (the number of games) is executed (activated), if it is during the pseudo bonus (that is, if it is during the increase section), the pseudo bonus is performed without forcibly ending the pseudo bonus in the middle. is terminated, the advantageous section is forcibly terminated and shifted to the non-advantageous section. Also, at this time, all the information about the above-mentioned advantageous section is cleared (initialized).

On the other hand, if it is not during the pseudo-bonus (that is, if it is during the performance section), first, it is forced to shift to the pseudo-bonus. That is, even if the pseudo-bonus transfer lottery is not won, the special limit process (the number of games) is executed to transfer to the pseudo-bonus. Then, when the transferred pseudo-bonus is finished, the advantageous section is forcibly ended and transferred to the non-advantageous section. Also, at this time, all the information about the above-mentioned advantageous section is cleared (initialized).

Here, the value of the advantageous section game number counter for which the normal limit process (number of games) is executed (activated) is "1500", whereas the special limit process (number of games) is executed (activated). Focusing on the point that the value of the control game number counter is "1445", the maximum number of games (continuable period) during the pseudo-bonus is "55 games" in the first gaming machine (Fig. 5), this difference takes into consideration the playable period during the pseudo bonus.

That is, the normal limit processing (the number of games) is executed when the game is played for a predetermined regulation period in the advantageous section in order to suppress the gambling nature of the game from becoming excessively high. However, for example, if this normal limit processing (the number of games) is executed immediately after or during the start of the pseudo-bonus, the player will have a sense of distrust and loss, and the interest in the game will decrease. Sometimes. Therefore, in the first gaming machine, the special limit processing (the number of games) is performed in the game that is before the game in which the normal limit processing (the number of games) is executed by the continuation possible period (55 games) per increase section. By executing this, it is possible to prevent the player from having a sense of distrust or a sense of loss due to the fact that the pseudo bonus ends in the middle.

From this point of view, the timing at which the special limit process (the number of games) is executed (activated) is not limited to the above. For example, the special limit processing (number of games) is executed in the game that is before the normal limit processing (number of games) by the continuation possible period (55 games x 2 sets = 110 games) per two increases. may be made.
In addition, for example, in order to give a slight grace period, the continuation possible period (55 games) + grace period (2 games) per increase section is before the game in which the normal limit processing (number of games) is executed. Special limit processing (the number of games) may be executed in the game of . Also, for example, in the case of specifications such as passing through a precursor state before transitioning to a pseudo bonus, and if the maximum number of games in this precursor state is "4 games", normal limit processing (number of games) is executed. The special limit process (the number of games) may be executed in a game that is before the game in which the continuation possible period (55 games) per increase section + the maximum sign period (4 games) is before the game. That is, the timing at which the special limit processing (number of games) is executed (actuated) may be any timing before the timing at which the normal limit processing (number of games) is executed. It is assumed that it can be set as appropriate according to the game specifications.

The special limit process (number of payouts) is executed when the value of the number-of-payouts counter for control becomes "2126" or more (that is, when the number of medals paid out during the advantageous interval exceeds 2125). Note that the payout number counter for control starts counting the number of medals paid out (here, for example, "net increase (difference number)") from the start of the advantageous section (including the performance section). When the interval ends (including the end due to the operation of the limit processing), the count is ended and cleared (initialized). Also, the control payout counter counts when the number of bets is 3, and does not count when the number of bets is 2. Also, the control payout number counter performs the counting in the non-bonus state, and does not perform the counting in the 2BB state and 3BB state.

In addition, the control payout number counter is decremented by a value that is appropriately counted according to the actual payout number (for example, "-3", etc.) when a "loss" occurs during the advantageous interval. However, the control payout number counter does not cause a "dropout" (or a difference) when a "dropout" occurs during the advantageous section (at least when a difference occurs from the maximum value of the medal payout number). count the number of medals paid out. Specifically, for example, in a game in which "push order bell A" is won with a 3-coin bet, if the batting order is appropriate, the payout number (maximum value) of medals is "8" (the difference is "8"). +5”), while if the batting order is not appropriate, if the pressing position is appropriate, the number of medals paid out will be “1” (“-2” as the difference), and if the pressing position is not appropriate. The number of medals to be paid out becomes "0" ("-3" as the number of difference) due to the occurrence of a dropout, but the control payout counter indicates the number of medals to be paid out in any case. +5 sheets" are counted.

Further, for example, when the value of the advantageous section payout counter becomes larger than the value of the control payout counter due to the activation of the 2BB state or the 3BB state, etc., the value of the control payout counter becomes the advantageous section payout counter. Corrected to the value of the section payout number counter. It should be noted that the control payout number counter may have the same configuration as the advantageous section payout number counter.

When the special limit processing (the number of payouts) is executed (actuated), if it is during the pseudo bonus (that is, if it is during the increase section), the pseudo bonus is not forcibly terminated in the middle. is terminated, the advantageous section is forcibly terminated and shifted to the non-advantageous section. Also, at this time, all the information about the above-mentioned advantageous section is cleared (initialized).

On the other hand, if it is not during the pseudo-bonus (that is, if it is during the performance section), first, it is forced to shift to the pseudo-bonus. That is, even if the pseudo-bonus transfer lottery is not won, the special limit process (the number of payouts) is executed to transfer to the pseudo-bonus. Then, when the transferred pseudo-bonus is finished, the advantageous section is forcibly ended and transferred to the non-advantageous section. Also, at this time, all the information about the above-mentioned advantageous section is cleared (initialized).

Here, the value of the advantageous section payout number counter for which the normal limit process (payout number) is executed (operated) is "2401", whereas the special limit process (payout number) is executed (operated). Focusing on the fact that the value of the number-of-control-games counter is "2126", in the first gaming machine, the maximum number of coins obtained in the pseudo bonus (amount of game value that can be given) is "275". (See FIG. 5), this difference takes into consideration the amount of game value that can be given in the pseudo bonus.

That is, the normal limit processing (the number of payouts) is performed when a predetermined amount of game value is granted in the advantageous section in order to suppress the gambling nature of the game from becoming excessively high. However, for example, if this normal limit processing (payout amount) is executed immediately after the start of the pseudo-bonus or during it, the player will have a sense of distrust and loss, and the interest in the game will decrease. may be lost. Therefore, in the first gaming machine, a game value amount that is less than the game value amount for which the normal limit processing (payout number) is executed is given by the amount of game value that can be given per increase section (275 coins). By executing special limit processing (the number of payouts) at times, it is possible to prevent the player from having a sense of distrust or loss due to the pseudo bonus ending in the middle.

From this point of view, the timing at which the special limit process (number of payouts) is executed (actuated) is not limited to the above. For example, when a game value amount that is less than the game value amount for which normal limit processing (payout number) is executed is given by the amount of game value that can be granted per two increases (275 coins x 2 sets = 550 coins) A special limit process (number of payouts) may be executed. Also, for example, in order to give a slight grace period, the amount of game value that can be granted per increase section (275 coins) + grace period is greater than the amount of game value for which normal limit processing (number of payouts) is executed. The special limit process (the number of games) may be executed when a game value amount that is less than the game value amount (8 cards) to be played is awarded. That is, the timing at which the special limit processing (payout amount) is executed (actuated) may be any timing before the timing at which the normal limit processing (payout amount) is executed. It is assumed that it can be set as appropriate according to the game specifications.

In semi-limit processing (the number of games), the value of the control game number counter is added to the value of the 1G consecutive counter (if the ceiling reduction lottery is won and the ceiling is shortened, "1" is added). ) is multiplied by “55” (that is, the period during which the pseudo bonus can be continued), and the result is “1390” or more. For example, if the value of the 1G run counter is "1" and "the ceiling is shortened", the value of the latter is "55×2=110", so the value of the control game number counter is "1280". , semi-limit processing (number of games) is executed (activated).

In the semi-limit process (number of payouts), the value of the control payout counter is added to the value of the 1G counter (if the ceiling reduction lottery is won and the result is "with ceiling reduction", "1" is added ) is multiplied by “275” (that is, the amount of gaming value that can be imparted with the pseudo bonus), and is executed when the result of the addition becomes “1851” or more. For example, if the value of the 1G counter is ``1'' and ``with ceiling reduction'', the value of the latter is ``275×2=550'', so the value of the payout number counter for control is ``1301''. ”, the quasi-limit process (the number of payouts) is executed (activated). In addition, since the semi-limit process (number of games) and the semi-limit process (number of payouts) both regulate the same content, after one operating condition is satisfied and activated, the other operating condition Even if is established, it is not necessary to operate redundantly.

When semi-limit processing (number of games) or preparation limit processing (number of payouts) is executed (activated), the above-mentioned 1G consecutive lottery and ceiling reduction lottery are executed during the pseudo bonus in a series of subsequent advantageous sections. will not be. That is, the extension of the game period in the increasing section is suppressed. Note that the method of suppressing the extension of the game period in the increasing interval is not limited to this. For example, in the above-mentioned 1G run lottery, the winning probability of the 1G run may be lower than usual, and in the above-mentioned ceiling reduction lottery, the winning probability of the ceiling reduction may be lower than usual. . That is, although the above-described 1G consecutive lottery and ceiling reduction lottery itself are executed, it may be made difficult to win these lotteries. Further, for example, in the performance section after execution of the semi-limit process (the number of games), the lottery value to be won in the pseudo-bonus transition lottery may be lowered to make it difficult to shift to the pseudo-bonus. Alternatively, the lottery value for determining a mode transition advantageous to the player in the mode transition lottery may be lowered to make it difficult for the pseudo bonuses to continue.

In addition, when semi-limit processing (number of games) or semi-limit processing (payout number) is executed (operated), in a series of subsequent advantageous sections, during the production section, the "fixed hand" (( Special processing is performed when a) is won. In the following, this special processing will be described by taking as an example a case where the "fixed hand" is "F_fixed cherry" (hereinafter sometimes simply referred to as "fixed cherry").

When neither the semi-limit process (number of games) nor the semi-limit process (number of payouts) is activated, if the "fixed cherry" is won during the production section (may be during the increase section), a pseudo-bonus transition lottery At , "win (next game)" is determined (see (c) in FIG. 7). In addition, in the first gaming machine, since the "cherry" symbol on the left reel 3L is a symbol that the player has a high degree of expectation for, in a game in which the information of the stop operation is not reported, the player is left first. It is a general procedure to perform a stop operation with one stop and aiming at a "cherry" symbol (aiming at a "BAR" symbol as a guideline). Therefore, when a game is played according to a general procedure, when a "fixed cherry" is won, first, the "cherry" symbol is stopped on the lower stage of the left reel 3L at the left first stop. In addition, when neither the semi-limit process (number of games) nor the semi-limit process (number of payouts) is activated, if the "fixed cherry" is won, the left first stop ("batting order 1" and "batting order 2") ”) may be notified. Further, "win (next game)" is not limited to the pseudo bonus starting from the next game, but may be the pseudo bonus starting from the next game.

Here, a skillful player stops aiming at the "BAR" symbol on the middle reel 3C and the right reel 3R, for example, in order to further determine whether it is a "weak che" or a "determined cherry". perform an operation. As a result, the "BAR" symbols are aligned in the middle of each reel, and it can be recognized that the "definite cherry" has been won (see, for example, "REP42" in FIG. 11). On the other hand, an unskilled player, for example, does not perform the stop operation aiming at the "BAR" symbols on the middle reel 3C and the right reel 3R, or is unable to perform the stop operation, and is thus "weak" from the stop display mode. In some cases, it may not be possible to determine whether it is a "fixed cherry" (see, for example, "REP28" in FIG. 11).

In the first gaming machine, when neither the semi-limit process (number of games) nor the semi-limit process (number of payouts) is in operation, the "fixed cherry" is won and the "fixed cherry" is won. symbol combination is displayed, a special winning sound is output. In addition, when "Definite Cherry" was won, the combination of "Definite Cherry Lip" symbols was not displayed, but even if the combination of "Cherry Lip" symbols was displayed, the special winning sound It is designed to be output. Note that the special winning sound may be output with a probability of 100%, or may be output with a predetermined probability (for example, a probability of 50%).

In any case, when neither semi-limit processing (number of games) nor semi-limit processing (number of payouts) is activated, if the "fixed cherry" is won, "red 7 matching" will be performed at the start of the next game. ' effect is performed to inform that the pseudo bonus is to be started, and the pseudo bonus is to be started.

On the other hand, after either the semi-limit process (number of games) or the semi-limit process (payout number) has been activated, if the "fixed cherry" is won during the production section (may be during the increase section), the pseudo-bonus transition Although "winning (next game)" is determined once in the lottery (see (c) in FIG. 7), this determination result is rewritten to "winning (current game)" by executing special processing. Then, at the start of the game this time, it is notified that the pseudo bonus is started by performing the "red 7 matching" effect, and the pseudo bonus is started.

At this time, in this game, the stop operation for displaying the symbol combination of "middle stage" without displaying the combination of "determined cherry lips" (including the combination of "cherry lips"). Information notification (special notification) is performed. For example, in the first gaming machine, a special notice to the effect that the right first stop ("batting order 5" and "batting order 6") should be made (see FIG. 15). As a result, when neither semi-limit processing (number of games) nor semi-limit processing (number of payouts) is in operation, the flow of the game such as "Determined Cherry Lip" is displayed → Pseudo bonus starts from the next game. After either the quasi-limit process (number of games) or the quasi-limit process (number of payouts) has been activated, a pseudo-bonus will start from the current game → a stop operation will be performed according to the special notification, resulting in a game called "middle rep" display. is changed to the flow of Note that the special notification may be performed under the control of the main (main control board 71) side. It may be controlled only by the sub (sub control board 72) side.

In addition, after either the semi-limit process (number of games) or the semi-limit process (number of payouts) is activated, even if the "fixed cherry" is won, the "fixed cherry" is issued despite the special notification. When the symbol combination of "cherry lips" is displayed, no special winning sound is output.

Further, in the first gaming machine, when "F_Replay A" or "F_Replay B" is determined as an internal winning combination, basically, the stop operation procedure is not reported. For this reason, assuming that the stop operation procedure is notified and the "middle comment" is displayed only when the above-mentioned special notification is performed, if such a state occurs, one of the The player clearly recognizes that the quasi-limit processing has been activated, and as a result, there is a possibility that the interest in the game may be reduced. Therefore, during the advantageous section, regardless of whether any semi-limit process is in operation (or after any semi-limit process has been activated), "F_replay A" or When "F_Replay B" is determined as the internal winning combination, the same notification as the special notification may be made with a predetermined probability. By doing so, it is possible to prevent the player from feeling unnatural about the special notification. Also, when "F_Replay A" or "F_Replay B" is determined as an internal winning combination, the notification similar to the special notification may be performed when the pseudo-bonus transition lottery is won. Further, in this case, in the pseudo-bonus shift lottery when "F_Replay A" or "F_Replay B" is determined as the internal winning combination, "winning (current game)" may be determined with a predetermined probability. good.

So far, in order to operate the normal limit process, the special limit process, and the semi-limit process, the explanation has been made by taking as an example the game period of the advantageous section using the "number of games" and the "number of payouts". The conditions for executing each limit process are not limited to those described above, and can be changed as appropriate. For example, the value of the advantageous section game number counter, the value of the advantageous section payout number counter, the value of the control game number counter, the value of the control payout number counter, and the value of the 1G run counter, when each limit process is executed. And whether or not to shorten the ceiling (that is, variables for activating the semi-limit process) can be appropriately changed according to game specifications, market trends, and the like.

Also, the method for monitoring the game period of the advantageous section is not limited to the one described above. For example, if the "navigation count" is used to monitor the game period of the advantageous section, normal limit processing (navigation count), special limit processing (navigation count), or semi-limit processing (navigation count) number of times) can also be executed. That is, any element (parameter) can be adopted as long as it is an element (parameter) whose value can be counted in order to monitor the gaming period of the advantageous section, and the adopted element is the value for which normal limit processing is performed. , a value for which special limit processing is executed, and a value for which semi-limit processing is executed, each limit processing can be executed in the same manner as described above.

As described above, in the first gaming machine, the advantageous state (for example, pseudo-bonus) and the specific state (for example, production section) are controlled as a series of advantageous sections, and the game period in this series of advantageous sections is a predetermined period (for example, , the value of the advantageous interval game number counter is "1500" or more), or the gaming value given in the series of advantageous intervals reaches a predetermined amount (for example, the value of the advantageous interval payout number counter is "2401" or more). ), this series of advantageous intervals is forcibly ended, but the game period in this series of advantageous intervals is a specific period shorter than a predetermined period (for example, the value of the control game number counter is "1445"). or more), or when the amount of gaming value given in this series of advantageous intervals becomes a specific amount smaller than a predetermined amount (for example, the value of the control payout number counter is "2126" or more), If it is in an advantageous state, the series of advantageous sections is terminated when shifting to a specific state.

That is, in the first gaming machine, the series of advantageous intervals is not forcibly ended in the middle of the advantageous state, and the series of advantageous intervals is ended within a certain period of time in a natural flow upon termination of the advantageous state. It is possible to let As a result, it is possible to prevent the player from having a sense of distrust or loss while suppressing the gambling nature from becoming excessively high, so it is possible to consider the player's emotions. and

In addition, in the first gaming machine, the advantageous state (for example, pseudo-bonus) and the specific state (for example, production section) are controlled as a series of advantageous sections, and the game period in this series of advantageous sections lasts for a predetermined period (for example, advantageous When the value of the section game number counter is "1500" or more), or when the amount of gaming value given in the series of advantageous sections is a predetermined amount (for example, the value of the advantageous section payout number counter is "2401" or more). When this occurs, the series of advantageous intervals is forcibly terminated, but the game period in the series of advantageous intervals is a specific period shorter than a predetermined period (for example, the value of the control game number counter is "1445" or more). , or when the amount of game value awarded in this series of advantageous intervals reaches a specific amount smaller than a predetermined amount (for example, the value of the control payout number counter is "2126" or more), the advantageous state is reached. If not, it is shifted to an advantageous state, and when the shifted advantageous state ends and shifts to a specific state, the series of advantageous sections is terminated.

That is, in the first gaming machine, the series of advantageous intervals is not forcibly ended in the middle of the advantageous state, and the series of advantageous intervals is ended within a certain period of time in a natural flow upon termination of the advantageous state. It is possible to let In addition, when ending a series of advantageous sections in this way, if it is not in an advantageous state, it is ended after shifting to an advantageous state. As a result, it is possible to prevent the player from having a sense of distrust or loss while suppressing the gambling nature from becoming excessively high, so it is possible to consider the player's emotions. and

In addition, in the first gaming machine, the specific period or specific amount is set in consideration of the period during which the advantageous state can be continued (for example, "55 games") or the amount of game value that can be given (for example, "275 cards"). Therefore, it is possible to prevent the amount of game value given to the player from being extremely restricted while considering the player's emotions.

In addition, in the first gaming machine, the advantageous state may be extended by granted rights (for example, "1G consecutive stock" and "ceiling reduction"), but the game period in a series of advantageous sections is limited to a specific period When a special period set according to the number of granted rights is reached (for example, when the value of the control game number counter reaches a value at which semi-limit processing (number of games) is executed), Or when the amount of gaming value granted in a series of advantageous sections is less than a specific amount and becomes a special amount set according to the number of rights granted (for example, the value of the payout number counter for control is a semi-limit When the processing (the number of payouts) reaches a value to be executed), granting of rights is suppressed in a series of subsequent advantageous intervals. As a result, for example, the player is given more rights than they can consume, and as a result of the forced termination of a series of advantageous sections in such a state, the player feels distrust and loss. Therefore, it is possible to prevent the gambling nature from becoming excessively high and to consider the emotions of the player.

In addition, in the first gaming machine, in counting the above-mentioned "specific amount" and "special amount", for example, due to the player's operation error or ignoring the instruction, etc. Even if there is a difference between the amount of game value that was actually given and the amount of game value that was actually given, the calculation is based on the amount of game value that was originally supposed to be given without considering this difference. It is supposed to be done. As a result, a series of advantageous intervals may be extended more than necessary due to such behavior of the player, and unfairness may arise between the player who has performed such behavior and the player who has not. Since it is possible to prevent the game from being put away, it is possible to consider the emotions of the player while suppressing the gambling nature from becoming excessively high.

In addition, in the first gaming machine, a winning combination (for example, "certain cherry") in which the transition to an advantageous state is confirmed in a state where granting of rights is suppressed (for example, after semi-limit processing is activated) is won. When the player does, a special notification is made so as not to display a combination of special symbols (for example, "Determined Cherry Lip") that clearly recognizes the winning of the determined combination. As a result, it is possible to prevent the player from feeling that the winning of the fixed combination was a useless win, for example. In other words, by preventing the player from clearly recognizing the trigger of the start of the advantageous state in a state where the granting of rights is suppressed, it is possible to prevent the gambling nature from becoming excessively high. It also makes it possible to consider people's emotions. Note that any effect executing means may be used to perform the special notification.

In addition, in the first game machine, when the special notification is performed, the advantageous state that should have been originally started from the next game is started from the current game. As a result, the player can naturally perform the stop operation according to the special notification, thereby preventing the player from having a sense of incongruity even when such a special notification is given. can.

Further, in the first gaming machine, when a winning combination of special symbols is displayed in a state in which granting of rights is not suppressed, a special notification (e.g., output of a special winning sound) is performed. On the other hand, in a state in which the granting of the right is suppressed, it is not possible to make a special notification when a winning combination is won and a combination of special symbols is displayed. As a result, it is possible to prevent the player from feeling that the winning of the fixed combination was a useless win, for example. In other words, by preventing the player from clearly recognizing the trigger of the start of the advantageous state in a state where the granting of rights is suppressed, it is possible to prevent the gambling nature from becoming excessively high. It also makes it possible to consider people's emotions. Note that any effect execution means may be used to perform the special notification.

Further, in the first gaming machine, it is determined whether or not a special notification is to be made, depending on whether or not a winning combination has been won, whether or not a combination of special symbols has been displayed, and whether or not a special notification has been made. I am trying to decide. This makes it possible to more appropriately manage the situation in which the special notification is made.

In addition, in the first gaming machine, the advantageous interval game number counter and the advantageous interval payout number counter perform counting regardless of the amount of game value betted. Normal limit processing (number of games) and normal limit processing (payout number) can be executed.

In addition, in the first gaming machine, the control game number counter and the control payout number counter perform counting in the 3-coin bet state, but do not count in the 2-coin betting state. Therefore, in the three-bet state, special limit processing (number of games) and special limit processing (payout number) can be executed, but in the two-bet state, special limit processing (number of games) and special limit It does not allow the transaction (payout number) to be performed. Therefore, in the two-coin bet state, the execution of the normal limit process (number of games) or the normal limit process (number of payouts) may forcibly end a series of advantageous intervals even during the pseudo bonus.

In the first gaming machine, for example, the odds of winning a small combination and the number of medals to be paid out are different between the 3-coin bet state and the 2-coin bet state (see FIGS. 10 to 15). Playing a game with two bets is more disadvantageous to the player than playing a game with . However, the method in which the player is more disadvantaged when playing a game with two bets is not limited to this. For example, if a game is played with two bets during the pseudo bonus, the procedure for the stop operation may not be reported, thereby disadvantageous to the player.

As described above, in the first gaming machine, when a game is played with a first amount (for example, "three") of game value betted, a series of advantageous intervals are forced to be performed in the middle of an advantageous state. A series of advantageous intervals can be ended within a certain period of time in a natural flow following the end of an advantageous state without being terminated suddenly. As a result, it is possible to prevent the player from having a sense of distrust or loss while suppressing the gambling nature from becoming excessively high, so it is possible to consider the player's emotions. and On the other hand, when a game is played with a second amount of gaming value (for example, "two") betted, a series of advantageous intervals may be forcibly terminated in the middle of an advantageous state. Therefore, it is possible to make the player realize that he or she did not play the game by the intended game method, so that the player can be urged to play the game by the intended game method.

It should be noted that, in the series of advantageous intervals, the case where the game is played with the second amount of game value betted is more disadvantageous to the player than the case where the game is played with the first amount of game value betted. Therefore, by enabling such a warning, it is possible to encourage the player to play the game in a more advantageous state, and to prevent the player from playing the game in a game method not intended by the player. It is possible to prevent the interest of the game from being lowered due to.

[5-5. Storage area configuration of the first gaming machine]
Next, referring to FIGS. 17 to 22, the storage area configuration of the first game machine will be described. FIG. 17 is a diagram showing an example of a winning flag storage area, a winning operation flag storage area, and a symbol code storage area of the first gaming machine. Also, FIG. 18 is a diagram showing an example of the carryover combination storing area of the first gaming machine. Also, FIG. 19 is a diagram showing an example of a game state flag storage area of the first game machine. Also, FIG. 20 is a diagram showing an example of the mode flag storage area of the first gaming machine. Also, FIG. 21 is a diagram showing an example of the operation stop button storage area of the first gaming machine. Also, FIG. 22 is a diagram showing an example of the pressing order storage area of the first gaming machine.

(Winning flag storage area, winning operation flag storage area, and pattern code storage area)
First, with reference to FIG. 17, the configuration of the winning flag storage area (internal winning combination storage area), winning operation flag storage area (display combination storage area), and symbol code storage area will be described. In addition, in the first game machine, the winning flag storage area, the winning operation flag storage area, and the symbol code storage area have the same data structure.

Each storage area described above is composed of storage areas 1 to 26 each represented by 1-byte data. The data stored in each storage area is only 1-byte data in the "data" column in FIG. 17, but for convenience of explanation, in FIG. (In FIG. 17, the symbols of the reel 3L, the symbols of the reel 3C, and the symbols of the reel 3R are described in this order) and the contents thereof (see FIGS. 11 to 14) are also described.

The data stored in the winning flag storage area allows the main CPU 101 to identify the type of symbol combination corresponding to the internal winning combination (that is, the type of symbol combination permitted to be displayed in the current game). is used to For example, when 2BB is won in the current game (when it is carried over), bit 0 of the storage area 1 is stored with "1".

The data stored in the winning operation flag storage area allows the main CPU 101 to identify the type of combination of symbols corresponding to the display combination (that is, the type of combination of symbols displayed on the activated line in the current game). used to For example, when a combination of 2BB symbols is displayed on the active line in the current game, bit 0 of the storage area 1 is stored with "1".

The data stored in the symbol code storage area enables the main CPU 101 to identify the types of symbol combinations that can still be displayed on the active line in the current game, at least while any of the reels is spinning. used for For example, when at least one of the reels is spinning in the current game, if a combination of symbols related to 2BB can be displayed on the active line, bit 0 of the storage area 1 is set to "1". is stored.

(Storage area for carryover combination)
Next, referring to FIG. 18, the configuration of the carryover combination storing area will be described. The carryover combination storage area is composed of a storage area represented by 1-byte data.

As a result of the internal lottery process, when a bonus combination of "F_2BB" (2BB) or "F_3BB" (3BB) is determined as an internal winning combination, these bonus combinations are stored as carryover combinations in the carryover combination storage area ( "1" is stored in the corresponding bit). The carryover combination stored in the carryover combination storage area is held without being cleared until the corresponding symbol combination is displayed on the activated line. In addition, while the carryover combination is stored in the carryover combination storage area, the carryover combination (bonus combination) is stored in the winning flag storage area in addition to the internal winning combination (small combination/replay combination) determined by the internal lottery process. be done.

(Game state flag storage area)
Next, with reference to FIG. 19, the configuration of the game state flag storage area will be described. The game state flag storage area is composed of a storage area represented by 1-byte data. For example, if the current gaming state is the 2BB state, "1" is stored in bit 0 of the storage area.

In addition, since the RT state is not provided in the first gaming machine, the area indicating the type of the RT state is not provided in the game state flag storage area shown in FIG. If so, "1" is stored in the bit of the storage area corresponding to the current RT state. In the first game machine, data indicating the type of game state (mode) during the advantageous section is separately stored in a mode flag storage area, which will be described later. You can also The same applies to the non-advantageous and advantageous game sections. It can be managed by providing an advantageous section flag storage area (not shown), or it can be stored and managed in this game state flag storage area. The same applies to game states such as AT state and ART state. An AT state (ART state) flag storage area (not shown) may be provided for management, or may be stored and managed in this game state flag storage area.

(mode flag storage area)
Next, the configuration of the mode flag storage area will be described with reference to FIG. The mode flag storage area is composed of a storage area 1 and a storage area 2 each represented by 1-byte data. For example, if the current mode is the start mode, "1" is stored in bit 0 of storage area 1; Also, for example, if the current mode is the heaven A mode, "1" is stored in bit 0 of the storage area 2. FIG. In the first gaming machine, the pseudo-bonus state is also managed as one of the modes.

(operation stop button storage area)
Next, referring to FIG. 21, the configuration of the operation stop button storage area will be described. The operation stop button storage area is composed of a storage area represented by 1-byte data. Bits 0 to 2 of the operation stop button storage area store data indicating the type of stop button that has already been operated (type of reel that has stopped), and bits 4 to 6 store data indicating the type of stop button that has not yet been operated. Stores data indicating the type (type of spinning reel).

For example, if the stop button 8L is the stop button pressed this time, ie, the operation stop button, "1" is stored in bit 0 of the operation stop button storage area. Further, for example, if the stop button 8L is a stop button that has not been pressed yet, that is, if it is a valid stop button, bit 4 stores "1". The main CPU 101 identifies the stop button that has been pushed this time and the stop button that has not been pushed yet based on the data stored in the operation stop button storage area.

(Press order storage area)
Next, referring to FIG. 22, the configuration of the pressing order storage area will be described. The pressing order storage area is composed of a storage area represented by 1-byte data. The pressing order indicates the pressing order of the stop buttons, that is, the pressing order (hitting order).

For example, when all the reels are rotating, "1" is stored in bits 0 to 5 of the pressing order storage area. Then, when the stop button 8L is pressed (because it is the "left" first stop), bits 0 and 1 will still contain "1", but bits 2-5 will contain "0". will be stored. Next, when the stop button 8C is pressed (because of the "left" first stop and the "middle" second stop), bit 0 remains stored with "1", but bit 1 "0" is stored. The main CPU 101 identifies the pressing order of the current game based on the data stored in the pressing order storage area.

[6. Processing by main control circuit]
Next, contents of various processes executed by the main CPU 101 of the main control circuit 100 using each program will be described with reference to FIGS. 23 to 32. FIG. In addition, in the explanation of various processes shown below, a specific example of the contents of the processes may be explained using the specifications of the first game machine, but the contents of the various processes shown below are limited to this. not a thing

[6-1. Main processing]
First, with reference to FIG. 23, main processing (main operation processing) executed by main CPU 101 of main control circuit 100 will be described. Note that FIG. 23 is a flowchart showing an example of the procedure of the main processing. FIG. 23 also shows power-on processing that is executed prior to the start of the main processing.

First, when power is supplied to the pachi-slot machine 1 (when the power is turned on), the main CPU 101 performs power-on processing (S1). In this process, various processes required when the power is turned on are performed. The details of the power-on processing will be described later.

Subsequently, the main CPU 101 performs initialization processing when one game ends (S2). In this process, the data in the designated storage area in the main RAM 103 is cleared. Here, the designated storage area is, for example, a storage area such as a winning flag storage area or a winning operation flag storage area that requires data to be erased for each unit game (game).

Subsequently, the main CPU 101 performs medal acceptance/start check processing (S3). In this process, for example, the input states of the medal sensor 31S, the bet switch 6S, the start switch 7S, etc. are checked, and various processes necessary at the start of the game are performed. The details of the medal acceptance/start check process will be described later.

Subsequently, the main CPU 101 performs random number acquisition processing (S4). In this process, random numbers for internal lottery (for example, the range of 0 to 65535) and random numbers for effects used in various lotteries related to game characteristics (other random numbers for lottery) (for example, the range of 0 to 65535, or 0 to 255 range), etc., and stores the various extracted random numbers in a random number storage area (not shown) provided in the main RAM 103 . It should be noted that the manner in which various random numbers are obtained is not limited to the one described above. A necessary number of random numbers can be appropriately obtained from each predetermined numerical range (for example, the range of 0 to 65535, the range of 0 to 32767, the range of 0 to 255, or the range of 0 to 127). .

Subsequently, the main CPU 101 performs internal lottery processing (S5). In this process, various processes necessary for determining the internal winning combination are performed based on the internal lottery table and the internal lottery random number value corresponding to the current gaming state and the like. Details of the internal lottery process will be described later.

Subsequently, the main CPU 101 performs a game start state control process (S6). In this processing, when a transition condition is satisfied (for example, based on a determined internal winning combination) at the start of a game, the game state is transitioned according to the satisfied transition condition. Alternatively, various processes necessary for managing the game period of the current game state are performed. The details of the game start state control process will be described later.

Subsequently, the main CPU 101 performs start command generation and storage processing (S7). In this process, start command data to be transmitted to the sub-control circuit 200 is generated, and the generated data is stored in a communication data storage area (not shown) provided in the main RAM 103 . The data stored in the communication data storage area is transmitted from the main control circuit 100 to the sub control circuit 200 in the communication data transmission process (see S204 in FIG. 32), which will be described later. Also, the methods of generating, storing, and transmitting data for other commands are basically the same.

Subsequently, the main CPU 101 performs a game start main effect control process (S8). In this process, when various effects are to be performed under the control of the main control circuit 100 side (main side) when the game is started, various processes necessary for performing the effects are performed. For example, when a lock effect is performed at the start of a game, execution of the lock effect is controlled. Also, if this includes a pseudo-game, it controls the progress of the pseudo-game (or notification about the pseudo-game). Further, for example, in the AT state, when the information of the stop operation is notified by the instruction monitor, the notification mode is controlled. Although details are omitted, when a lock effect is performed, a lock command generation and storage process is performed in this process.

Subsequently, the main CPU 101 performs reel stop initialization processing (S9). In this process, based on the internal winning combination, game state, etc., various information necessary for stop control such as the type of stop table used in the current game and the type of attraction priority table are set.

Subsequently, the main CPU 101 performs reel rotation start processing (S10). This processing requests the start of rotation of all reels. When all the reels are requested to start rotating, the reel control process (see S203 in FIG. 32), which will be described later, controls the driving of the stepping motors 51L, 51C, and 51R, thereby causing the reels 3L, 3C, and 3R to rotate. rotation is started. Each reel that has started to rotate is accelerated and controlled until its rotational speed reaches a constant speed, after which the constant speed is maintained. Although details are omitted, reel rotation start command generation and storage processing is performed in this processing.

Subsequently, the main CPU 101 performs attraction priority storage processing (S11). In this process, for each symbol (symbol position) of the spinning reel (all reels in this case), the set internal winning combination and the set attraction priority table are referred to determine the attraction priority. The data shown is acquired and stored in an attraction priority data storage area (not shown). Although illustration is omitted, a pattern code storage process, which will be described later, is performed prior to this process.

Subsequently, the main CPU 101 performs reel stop control processing (S12). In this process, the rotation of the relevant reel is stopped based on the determined internal winning combination (or information related to various stop controls set accordingly) and the stop operation mode of each stop button 8L, 8C, 8R. perform various processing necessary for Details of the reel stop control process will be described later.

Subsequently, the main CPU 101 performs winning operation determination processing (S13). In this process, it is determined whether or not the combination of symbols displayed on the activated line is any combination of symbols defined in the symbol combination table. For example, it is determined whether or not there is a bit in which "1" is stored in the winning operation flag storage area. Although the details are omitted, in this process, a winning actuation command generating and storing process is performed.

Subsequently, the main CPU 101 performs medal payout/re-game operation processing (S14). In this process, if the combination of symbols determined in the above-described winning operation determination process is a combination of symbols related to a minor combination, the corresponding number of medals is paid out. Various processes necessary for activating a replay in a game are performed. It should be noted that, for example, if the combination of symbols determined in the above-described winning operation determination process is the combination of symbols related to the replay combination, the same value as the number of bets in the current game is set in the automatic insertion medal counter, which will be described later. process. Also, in this process, a medal payout signal corresponding to the number of medals to be paid out is output from the external centralized terminal board 55 .

Subsequently, the main CPU 101 performs a game end state control process (S15). In this processing, when a transition condition is satisfied (for example, based on a combination of displayed symbols) when a game ends, the game state is transitioned according to the satisfied transition condition. Alternatively, various processes necessary for managing the game period of the current game state are performed. The details of the state control process at the time of game end will be described later.

Subsequently, the main CPU 101 performs a main effect control process at the end of the game (S16). In this process, when various effects are performed under the control of the main control circuit 100 side (main side) when the game ends, various processes necessary for performing the effects are performed. For example, when the lock effect is performed at the end of the game, the execution of the lock effect is controlled. Also, if this includes a pseudo-game, it controls the progress of the pseudo-game (or notification about the pseudo-game). Although details are omitted, when a lock effect is performed, a lock command generation and storage process is performed in this process.

Thus, in the pachi-slot machine 1, one unit game is controlled by performing the processes of S2 to S16 described above, and progress of the game is controlled by repeating these processes. It should be noted that it is possible to configure so that processes other than these processes are appropriately performed as necessary, or it is possible to configure so that some of these processes are not performed. In other words, the various types of processing described above are merely examples.

(Processing at power-on)
Next, with reference to FIG. 24, the power-on process performed in S1 of the main process described above will be described. Note that FIG. 24 is a flowchart showing an example of the procedure of the power-on process.

First, the main CPU 101 performs a write test of the main RAM 103 after performing initialization processing (not shown) when power is turned on, and determines whether or not writing to the main RAM 103 has been performed normally as a result of the test ( S21). That is, the main CPU 101 determines whether or not an abnormality has occurred in the main RAM 103 .

When the main CPU 101 determines that writing to the main RAM 103 has been performed normally (YES in S21), the main CPU 101 determines whether or not the setting key-shaped switch 52 is in the ON state (S22). That is, the main CPU 101 determines whether or not the setting change is possible.

When the main CPU 101 determines that the setting key-shaped switch 52 is in the ON state (YES in S22), the main CPU 101 performs initialization processing when changing the setting (S23). In this process, the data in the designated storage area in the main RAM 103 is cleared. The designated storage area here is, for example, a storage area for carryover combinations, a game state flag storage area, a mode flag storage area, or the like, in which data must be erased when settings are changed.

Subsequently, the main CPU 101 performs initialization command generation and storage processing (S24). In this process, data of an initialization command to be transmitted to the sub-control circuit 200 indicating that the setting change process has started is generated, and the generated data is stored in the communication data storage area.

Subsequently, the main CPU 101 performs setting change processing (S25). In this process, after the main RAM 103 is initialized by accepting the above-described set value determination operation or set value confirmation operation, a new set value is set (stored) in a set value storage area (not shown) of the main RAM 103. be done. Subsequently, the main CPU 101 determines whether or not the setting key-type switch 52 is turned off (S26). That is, the main CPU 101 determines whether or not the setting changeable state has ended after the setting value is newly set.

When the main CPU 101 determines that the setting key-shaped switch 52 is not in the OFF state (NO in S26), the main CPU 101 waits the processing until the setting key-shaped switch 52 is in the OFF state. On the other hand, if it is determined that the setting key-type switch 52 is turned off (YES in S26), an initialization command generation and storage process is performed (S27). In this process, the data of the initialization command to be transmitted to the sub-control circuit 200 indicating that the setting change process is completed is generated, and the generated data is stored in the communication data storage area. After this process, the main CPU 101 ends the power-on process.

When the main CPU 101 determines in S22 that the setting key-shaped switch 52 is not in the ON state (NO in S22), it determines whether or not the backup data is normal (S28). That is, the main CPU 101 determines whether or not the various information backed up when the power supply to the pachi-slot machine 1 is interrupted (at the time of power failure) is normal.

When the main CPU 101 determines that the backup data is normal (YES in S28), the main CPU 101 performs game return processing (S29). In this process, the process of restoring the pachi-slot machine 1 to the state before the power interruption is performed. After this process, the main CPU 101 ends the power-on process.

If the main CPU 101 determines in S21 that the writing to the main RAM 103 was not performed normally (S21 is NO), and if it determines in S28 that the backup data is not normal (S28 is NO), an error occurs when the power is turned on. Processing is performed (S30). An error generated by this power-on error processing is not resolved by the reset operation described above, but is resolved by setting a new set value. Therefore, after the power-on error processing, the main CPU 101 turns off the power of the pachi-slot machine 1 once, and thereafter, until the setting value is newly set (until the above-described processing of S22 to S26 is performed), the main CPU 101 operates normally. It does not move to the processing (from S2 in FIG. 23).

(Medal reception/start check processing)
Next, referring to FIG. 25, the medal acceptance/start check process performed in S3 of the main process described above will be described. Note that FIG. 25 is a flow chart showing an example of the medal reception/start check process procedure.

First, the main CPU 101 determines whether or not the value of the automatically inserted medal counter is "0" (S41). That is, the main CPU 101 determines whether or not a replay combination has been won in the previous unit game (whether or not a replay has been activated).

When the main CPU 101 determines that the value of the automatically inserted medal counter is not "0" (NO in S41), the main CPU 101 performs automatic inserted medal processing (S42). In this process, the same number of medals as the medals inserted in the previous unit game are automatically inserted. Also, although the details are omitted, when automatic insertion is performed, a medal insertion command generation and storage process is performed in this process. Also, in this process, a medal insertion signal is output from the external centralized terminal board 55 .

When the main CPU 101 determines in S41 that the value of the automatically inserted medal counter is "0" (YES in S41), and after the processing in S42, the main CPU 101 performs medal auxiliary storage switch check processing (S43). In this process, it is determined whether or not the auxiliary medal storage switch 33S is in the ON state (that is, whether or not a certain number or more of medals are stored in the auxiliary medal storage 33). If it is determined to be on, a medal auxiliary storage error is generated. In this case, the processing waits until the error is resolved. Also, if it is determined that the medal auxiliary storage switch 33S is not in the ON state, this processing is terminated.

Subsequently, the main CPU 101 performs medal insertion state check processing (S44). In this process, the current number of bets and the number of credits are checked. A state in which acceptance is possible (a state in which betting operations can be accepted) is established (acceptance of medals is permitted). If a selector error has occurred, the process waits until the error is resolved.

Subsequently, the main CPU 101 determines whether or not medals can be accepted (S45). When the main CPU 101 determines that medals can be accepted (YES in S45), the main CPU 101 performs medal insertion check processing (S46). In this process, the number of bets and the number of credits are updated based on the detection result of the medal sensor 31S and the detection result of the bet switch 6S. Further, although the details are omitted, when a bet operation is performed, a medal insertion command generation and storage process is performed in this process. Also, in this process, a medal insertion signal is output from the external centralized terminal board 55 .

Subsequently, the main CPU 101 determines whether or not it is possible to insert medals or credit (S47). That is, the main CPU 101 determines whether or not the number of bets is "3" and the number of credits is not "50". When the main CPU 101 determines that medal insertion or credit is not possible (that is, the number of bets is "3" and the number of credits is also "50") (NO in S49). , the reception of medals is prohibited (S48). That is, the main CPU 101 sets a state in which it is not possible to accept medals (a state in which it is not possible to accept betting operations).

If the main CPU 101 determines in S45 that medals cannot be accepted (NO in S45), if it determines in S47 that medals can be inserted or credited (YES in S47), and After the process of S48, it is determined whether or not the number of inserted coins is the game startable number (S49). In the case of the first gaming machine, in this process, for example, it is determined whether or not the current number of bets is "2" or "3".

When the main CPU 101 determines that the number of inserted coins is the game-startable number (YES in S49), it determines whether or not the start switch 7S is turned on (S50). That is, the main CPU 101 determines whether or not the player has performed a start operation.

When the main CPU 101 determines that the start switch 7S is turned on (YES in S50), it prohibits acceptance of medals (S51). After this process, the main CPU 101 ends the medal acceptance/start check process.

When the main CPU 101 determines in S49 that the number of inserted cards is not the number of game startable cards (NO in S49), and when it determines in S50 that the start switch 7S is not in the ON state (NO in S50), the main CPU 101 processes is returned to S44.

(Internal lottery process)
Next, with reference to FIG. 26, the internal lottery process performed in S5 of the main process described above will be described. Note that FIG. 26 is a flow chart showing an example of the procedure of the internal lottery process.

First, the main CPU 101 performs setting value/number of inserted medal check processing (S61). In this process, the set value and the number of bets in the current unit game are checked. Subsequently, the main CPU 101 sets an internal lottery table according to the set values, the number of bets, the game state, etc. (S62). Subsequently, the main CPU 101 acquires a random number for internal lottery from the random number storage area (S63). That is, the main CPU 101 acquires the internal lottery random number data acquired in S4 of the main processing described above. In this process, if it is determined that the set value is other than "1" to "6" or the number of bets is other than "1" to "3", the main CPU 101 determines that a serious error has occurred. Then, the above-described power-on error processing (see S30 in FIG. 24) is executed.

Subsequently, the main CPU 101 performs internal winning combination determination processing (S64). In this process, the acquired random number for internal lottery is sequentially updated (for example, updated by addition) using the lottery value of each internal winning combination specified in the set internal lottery table, and the update result becomes a predetermined result. (for example, overflow). When a predetermined result is obtained, the internal winning combination is determined as the internal winning combination of the current unit game. It should be noted that, if the predetermined result is not obtained even if all the internal winning combinations are determined, the result of the current unit game is "loss" ("loss" is determined as the internal winning combination).

Subsequently, the main CPU 101 determines whether or not an internal winning combination has been determined (S65). When the main CPU 101 determines that the internal winning combination has not been determined (NO in S65), the process returns to S64. That is, the main CPU 101 sequentially updates the internal winning combinations to be determined (and also sequentially updates the random number for the internal lottery) until determination is made for all internal winning combinations (or until the internal winning combination is determined halfway through). The process of S64 is repeated until it is determined).

If the main CPU 101 determines that an internal winning combination has been determined (YES in S65), the main CPU 101 determines whether the determined internal winning combination is a non-carryover combination (i.e., not a bonus combination that is a carryover combination, but a small combination or a replay combination). (S66). When the main CPU 101 determines that the determined internal winning combination is the carryover non-target combination (YES in S66), it updates the winning flag storage area (S67). In this process, the data in the winning flag storage area is updated based on the internal winning combination determined in the process of S64. That is, the main CPU 101 stores "1" in the bit of the data corresponding to the combination of symbols allowed to be displayed corresponding to the determined internal winning combination in the winning flag storage area.

When the main CPU 101 determines in S66 that the determined internal winning combination is not the carryover non-target combination (NO in S66), and after the process of S67, determines whether the determined internal winning combination is the carryover target combination ( That is, it is determined whether or not it is a bonus combination that is a carryover combination (S68).

When the main CPU 101 determines that the determined internal winning combination is the carryover combination (YES in S68), the main CPU 101 determines whether or not the data in the carryover combination storage area is "0" (S69). That is, the main CPU 101 determines whether or not any bonus combination has been carried over. When the main CPU 101 determines that the data in the carryover combination storing area is "0" (YES in S69), the main CPU 101 updates the carryover combination storing area (S70). In this process, the data in the carryover combination storage area is updated based on the internal winning combination determined in the process of S64. That is, the main CPU 101 stores "1" in the bit of the data corresponding to the combination of symbols whose display is permitted corresponding to the determined internal winning combination in the carryover combination storing area.

When the main CPU 101 determines in S68 that the determined internal winning combination is not the carryover-target combination (NO in S68), or determines in S69 that the data in the carryover combination storing area is not "0" (NO in S69). ), and after the processing of S70, it is determined again whether or not the data in the carryover combination storing area is "0" (S71).

When the main CPU 101 determines that the data in the carryover combination storing area is not "0" (NO in S71), it updates the winning flag storing area (S72). In this process, the data stored in the carryover combination storing area is reflected in the data in the winning flag storing area. That is, when a bonus combination is carried over (or a win is made in the current unit game), the main CPU 101 stores data corresponding to the combination of symbols permitted to be displayed corresponding to the bonus combination in the winning flag storage area. store "1" in the bit.

When the main CPU 101 determines in S71 that the data in the carryover combination storing area is "0" (YES in S71), and after the processing in S72, the main CPU 101 performs sub-flag setting processing (S73). In the case of the first gaming machine, in this process, for example, a non-advantageous interval sub-flag and an advantageous interval-winning sub-flag are set based on the internal winning combination. In this process, for example, information corresponding to the stop operation information notified by the instruction monitor may be set in the AT state. After this process, the main CPU 101 terminates the internal lottery process.

(State control process at game start)
Next, with reference to FIG. 27, the game start state control process performed in S6 of the main process described above will be described. FIG. 27 is a flow chart showing an example of the procedure of the game start state control process.

First, the main CPU 101 performs a game state transition condition satisfaction check process (S81). In this processing, when starting a game, it is checked whether or not a transition condition for shifting from one game state to another game state is established. For example, in the case of shifting to a flag state as a predetermined RT state based on winning of a predetermined bonus combination, whether or not a predetermined bonus combination has been won is checked in this process. In the case of the first gaming machine, the interval between flags is not configured as an RT state (that is, as a game state stored in the game state flag storage area), so checking here is unnecessary. Also, for example, if there is a specific RT state that starts or ends by playing a specific number of games after a specific transition condition is established, this specific number of games can be managed in this process.

Subsequently, the main CPU 101 determines whether or not a transition condition for transitioning to any game state is established (S82). When the main CPU 101 determines that the transition condition for shifting to any game state is established (YES in S82), it updates the game state flag storage area (S83). That is, the main CPU 101 sets the game state according to the established transition condition. Subsequently, the main CPU 101 performs setting processing according to the set game state (S84). In this processing, it is necessary to set, for example, the game period of the game state, or set the lottery value (lottery table) in various lottery processing other than the internal lottery processing, in accordance with the transition of the game state. In this case, such setting processing is performed as appropriate.

When the main CPU 101 determines in S82 that the transition condition for transitioning to one of the game states is not established (NO in S82), and after the processing in S84, the current game section is a non-advantageous section. It is determined whether or not there is (S85). When the main CPU 101 determines that the current game section is a non-advantageous section (YES in S85), the main CPU 101 performs advantageous section start condition satisfaction check processing (S86). In this process, when starting a game, it is checked whether or not a transition condition (advantageous section start condition) for shifting from a non-advantageous section to an advantageous section is established. In the case of the first gaming machine, in this process, for example, the above-described advantageous interval transition lottery is performed, and it is checked whether or not the lottery result is for starting the advantageous interval.

Subsequently, the main CPU 101 determines whether or not the condition for starting the advantageous section is satisfied (S87). When the main CPU 101 determines that the conditions for starting the advantageous interval are not satisfied (NO in S87), the main CPU 101 ends the state control process at the start of the game. Further, when the main CPU 101 determines that the conditions for starting the advantageous interval are satisfied (YES in S87), the main CPU 101 performs setting processing at the start of the advantageous interval (S88). That is, the main CPU 101 starts (sets) an advantageous section. In this process, in response to the start of the advantageous interval, for example, various counters (see FIG. 16) relating to various limit processes start counting (that is, start monitoring the game period of a series of advantageous intervals). is set as appropriate.

Subsequently, the main CPU 101 updates the mode flag storage area (S89). That is, the main CPU 101 sets the mode (game state) during the advantageous section that has started. In the case of the first gaming machine, in this processing, for example, the transition destination mode determined according to the lottery result of the above-described advantageous zone transition lottery is set.

Subsequently, the main CPU 101 performs setting processing according to the set mode (S90). In this process, depending on the set mode, the game period of the mode (including the number of ceiling games, etc.) is set, and the lottery value (lottery table) in various lottery processes other than the internal lottery process is set. Such setting processing is appropriately performed when necessary. In the case of the first gaming machine, in this processing, for example, when shifting to the pseudo bonus according to the set destination mode, "55 games" is set as the game period, and the processing shifts to the end mode. In this case, "32 games" is set as the game period, and in the case of shifting to other modes, the number of ceiling games corresponding to each mode is set. In addition, lottery values (lottery table) in various lotteries (see FIGS. 7 and 8) are set. After this process, the main CPU 101 ends the game start state control process.

When the main CPU 101 determines in S85 that the current game section is not a non-advantageous section (that is, it is an advantageous section) (NO in S85), the main CPU 101 performs a game start processing during an advantageous section (S91). The details of the processing at the start of the game during the advantageous interval will be described later.

Subsequently, the main CPU 101 performs advantageous section end condition satisfaction check processing (S92). In this processing, when starting a game, it is checked whether or not a transition condition (advantageous section end condition) for shifting from an advantageous section to a non-advantageous section is established. In the case of the first gaming machine, in this process, for example, if the operation conditions for various limit processes are satisfied based on the number of games in the advantageous section (see FIG. 16), or if the current mode is the end mode, , it is checked whether 32 games have passed.

Subsequently, the main CPU 101 determines whether or not the condition for ending the advantageous section is satisfied (S93). When the main CPU 101 determines that the condition for ending the advantageous section is satisfied (YES in S93), the main CPU 101 performs an initialization process at the end of the advantageous section (S94). That is, the main CPU 101 ends the advantageous section and sets the non-advantageous section. In this process, depending on the end of the advantageous interval, for example, various counters (see FIG. 16) related to various limit processing, the mode (game state) during the advantageous interval, and the game period of the mode (the number of ceiling games, etc.) ) etc. (that is, information on the advantageous section) is cleared. After this process, the main CPU 101 ends the game start state control process. Further, when the main CPU 101 determines that the condition for ending the advantageous section is not satisfied (NO in S93), the main CPU 101 ends the state control process at the start of the game.

(Processing at the start of the game during the advantageous section)
Next, with reference to FIG. 28, the process at the start of the game during the advantageous interval, which is performed in S91 of the above-described state control process at the time of game start, will be described. Note that FIG. 28 is a flow chart showing an example of the procedure of the process at the start of a game during an advantageous interval.

First, the main CPU 101 performs various counter updating processes (at the start of the game) (S101). In this process, for example, various counters (see FIG. 16) related to various limit processes based on the number of games played during the advantageous interval, various counters for managing the game period such as various modes (game states) during the advantageous interval, or other counters Various counters for managing the degree of advantage are updated according to predetermined update conditions (for example, decrement (add) 1 each game).

Subsequently, the main CPU 101 determines whether or not it is in the specific mode (AT state) (S102). When the main CPU 101 determines that it is in the specific mode (YES in S102), the main CPU 101 performs AT period management processing (at the start of the game) (S103). In this process, for example, when the AT state game period can be extended (for example, the number of games to be extended, the number of sets to be added, etc.) at the start of the game, it is determined whether or not such an extension execution condition is established. or extend the game period based on this determination result (if the game period in the AT state can be shortened, the shortening process is performed). In addition, in this process, the AT state game period may be managed regardless of whether it is extended, or the AT state game period is managed in the process of S101 described above, and only the process related to extension is performed in this process. may be performed. In the case of the first gaming machine, in this process, for example, the above-described 1G consecutive lottery is performed based on the sub-flag at the time of winning the advantageous section, the 1G consecutive lottery is performed, and the pseudo bonus is extended according to the lottery result. processing is performed.

Subsequently, the main CPU 101 performs navigation setting processing (S104). In this process, information corresponding to the stop operation information notified by the instruction monitor, information corresponding to the stop operation information to be included in the start command, and the like are set. In addition, in this process, it may be possible to determine whether to generate navigation. That is, when the notification target role is won in the AT state, there may be cases where navigation does not necessarily occur. occurrence probability).

If the main CPU 101 determines in S102 that the specific mode is not in progress (NO in S102), and after S104, the main CPU 101 determines whether or not the mode transition condition is satisfied (S105). In the case of the first gaming machine, in this process, for example, it is determined whether or not the transition destination mode is determined according to the lottery result of the mode transition lottery described above based on the sub-flags at the time of winning the advantageous section.

When the main CPU 101 determines that the mode transition condition is satisfied (YES in S105), the main CPU 101 updates the mode flag storage area (S106). That is, the main CPU 101 sets the mode (game state) during the transferred advantageous section. In the case of the first gaming machine, in this process, for example, the transition destination mode determined according to the lottery result of the above-described mode transition lottery based on the sub-flag at the time of winning the advantageous section is set.

Subsequently, the main CPU 101 performs setting processing according to the set mode (S107). In this process, depending on the set mode, the game period of the mode (including the number of ceiling games, etc.) is set, and the lottery value (lottery table) in various lottery processes other than the internal lottery process is set. Such setting processing is appropriately performed when necessary. In addition, in the case of the first gaming machine, in this process, for example, the same process as the above-described process of S90 is performed. After this process, the main CPU 101 ends the game start process during the advantageous interval. Further, when the main CPU 101 determines that the mode transition condition is not satisfied (NO in S105), the main CPU 101 ends the processing at the time of starting the game during the advantageous section.

27, the state control processing at the end of the game shown in FIG. 30, the processing at the start of the game during the advantageous interval shown in FIG. 28, and the processing at the end of the game during the advantageous interval shown in FIG. Basically, they have almost the same processing configuration. This process may be performed either when the game is started or when the game is finished (for example, a game state or mode transition, etc., which refers to a determined internal winning combination. As for the processing that should be reflected until the current game ends (or until the next game starts), it means that it can be performed on either side, and the same applies to both. It does not mean that the processing of is performed redundantly. Therefore, such processing may be performed either when the game is started or when the game is finished.

On the other hand, those that need to be processed when starting the game (for example, the above-mentioned navigation setting processing, etc.) are assumed to be executed when the game starts, and when the game ends. Those that need to be processed (for example, the process of referring to the combination of displayed symbols, etc.) may be performed when the game ends. Further, for example, a process that needs to be performed at a predetermined time after the start of the game but before the end of the game, or a process that should be performed (for example, a process that refers to the stop operation mode of the first stop operation, etc.) ) can be assumed to be performed at that time.

(reel stop control process)
Next, referring to FIG. 29, the reel stop control process performed in S12 of the main process described above will be described. Note that FIG. 29 is a flowchart showing an example of the procedure of the reel stop control process.

First, the main CPU 101 determines whether or not the rotational speeds of all the reels have reached a predetermined constant speed (for example, 80 rpm/1 minute) (that is, whether they are rotating at a constant speed) (S111). When the main CPU 101 determines that all the reels are not rotating at a constant speed (NO in S111), the main CPU 101 waits until all the reels are rotating at a constant speed. On the other hand, when it is determined that all the reels are rotating at a constant speed (YES in S111), each reel is permitted to stop (S112). That is, the main CPU 101 activates each stop button. Also, along with this, the operation stop button storage area is updated (in the case of the first game machine, for example, bits 4 to 6 of the operation stop button storage area are stored with "1").

Subsequently, the main CPU 101 determines whether or not a valid stop button has been operated (S113). When the main CPU 101 determines that a valid stop button has not been operated (NO in S113), the main CPU 101 waits for processing until a valid stop button is operated. In the case of performing automatic stop control, it is possible to measure this standby time and perform automatic stop control when the measurement result reaches a predetermined time.

When determining that a valid stop button has been operated (YES in S113), the main CPU 101 updates the operation stop button storage area and the pressing order storage area (S114). In the case of the first gaming machine, for example, when the first stop operation is performed on the reel 3L (when the stop button 8L is pressed), in this process, the operation stop button storage area bit "1" is stored in 0, and bit 4 is updated to "0". Also, bits 2 to 5 of the pressing order storage area are updated to "0".

Subsequently, the main CPU 101 determines the reel to be controlled from the operation stop button (S115). In this process, for example, when the stop button 8L is pressed, the reel 3L is determined as the reel to be controlled.

Subsequently, the main CPU 101 stores the stop start position from the symbol counter (S116). The symbol counter is configured as a counter for grasping symbol position data (for example, "0" to "19"). In this process, for example, when the stop button 8L is pressed, the symbol position data of the middle area of the reel 3L when the stop button 8L is pressed is stored as the stop start position.

Subsequently, the main CPU 101 performs the number of sliding symbols determination process (S117). In this process, for example, the number of sliding symbols specified in the above-mentioned stop table and the data in the above-mentioned attraction priority data storage area are referred to determine the most appropriate number of sliding symbols (symbol movement amount).

Subsequently, the main CPU 101 stores the expected stop position from the stop start position and the number of sliding symbols (S118). In this process, the symbol position data of the position where the symbol finally stops is stored as the expected stop position based on the stop start position stored in the process of S116 described above and the number of sliding symbols determined in the process of S117 described above. .

Subsequently, the main CPU 101 performs reel stop command generation and storage processing (S119). In this process, the reel stop command data to be transmitted to the sub-control circuit 200 is generated, and the generated data is stored in the communication data storage area provided in the main RAM 103 . Note that the reel stop command can include parameters that can specify not only the expected stop position but also the stop start position and the number of sliding symbols.

Subsequently, the main CPU 101 performs pattern code storage processing (S120). In this process, the symbol code storage area is updated while also referring to the symbol type (symbol code) of the expected stop position on the reel for which the expected stop position has already been determined. Subsequently, the main CPU 101 determines whether or not there is a valid stop button (S121). That is, the main CPU 101 determines whether or not there is still a spinning reel (whether or not all the reels have been stopped).

When the main CPU 101 determines that there is a valid stop button (YES in S121), the main CPU 101 performs control change processing (S122). In this process, according to the player's stop operation mode so far, for example, when it is necessary to change the stop table or attraction priority table set in the above-described reel stop initial setting process, such a Reconfigure various information necessary for stop control.

Subsequently, the main CPU 101 performs attraction priority storage processing (S123). In this process, each symbol (symbol position) on the rotating reel is set as a set internal winning combination while also referring to the symbol type at the expected stop position on the reel whose expected stop position has already been determined. The attraction priority order table is referenced to obtain data indicating the attraction priority order, and the acquired data is stored in the attraction priority order data storage area. After this process, the main CPU 101 returns the process to S113. Further, when determining that there is no effective stop button (NO in S121), the main CPU 101 ends the reel stop control process.

(State control process at game end)
Next, with reference to FIG. 30, the state control process at the end of the game, which is performed in S15 of the main process described above, will be described. Note that FIG. 30 is a flow chart showing an example of the procedure of the state control process at the end of the game.

First, the main CPU 101 performs a game state transition condition establishment check process (S131). In this processing, it is checked whether or not a transition condition for shifting from one game state to another game state is established when the game ends. For example, when shifting to a predetermined RT state or a predetermined bonus state based on the display of a predetermined combination of symbols, it is checked in this process whether or not the predetermined combination of symbols has been displayed. In addition, in the case of a predetermined RT state or a predetermined bonus state, it is checked in this process whether or not conditions for terminating these game states are established. In the case of the first gaming machine, in this processing, for example, it is checked whether or not a combination of 2BB or 3BB symbols is displayed. Further, for example, in the case of the 2BB state or the 3BB state, it is checked whether or not the end condition of these game states is established by paying out medals.

Subsequently, the main CPU 101 determines whether or not a transition condition for transitioning to any game state is established (S132). When the main CPU 101 determines that the transition condition for shifting to any game state is established (YES in S132), it updates the game state flag storage area (S133). That is, the main CPU 101 sets the game state according to the established transition condition. In the case of the first gaming machine, in this process, for example, when a combination of symbols related to 2BB or 3BB is displayed, "1" is stored in bit 0 or bit 1 of the gaming state flag storage area, and 2BB is displayed. Set state or 3BB state. Further, for example, in the case of the 2BB state or the 3BB state, if the end conditions for these game states are met, bit 0 or bit 1 of the game state flag storage area is updated to "0".

Subsequently, the main CPU 101 performs setting processing according to the set game state (S134). In this processing, it is necessary to set, for example, the game period of the game state, or set the lottery value (lottery table) in various lottery processing other than the internal lottery processing, in accordance with the transition of the game state. In this case, such setting processing is performed as appropriate. In the case of the first gaming machine, in this process, for example, if the 2BB state is set, the number of payouts as the termination condition is set to "1", and if the 3BB state is set, the number of payouts is set to "1". If so, "176" is set as the number of payouts as the termination condition.

When the main CPU 101 determines in S132 that the transition condition for transitioning to one of the game states is not established (NO in S132), and after the processing in S134, the current game section is a non-advantageous section. It is determined whether or not there is (S135). When the main CPU 101 determines that the current game section is a non-advantageous section (YES in S135), the main CPU 101 performs advantageous section start condition establishment check processing (S136). As described above, only the process referring to the determined internal winning combination is possible in the non-advantageous section, so this process is the same as the above-described process of S86 (game start state control process).

Subsequently, the main CPU 101 determines whether or not the conditions for starting the advantageous section are satisfied (S137). When the main CPU 101 determines that the conditions for starting the advantageous interval are not satisfied (NO in S137), the main CPU 101 ends the state control process at the end of the game. Further, when the main CPU 101 determines that the condition for starting the advantageous interval is satisfied (YES in S137), the main CPU 101 performs setting processing at the start of the advantageous interval (S138). As described above, only the process referring to the determined internal winning combination is possible in the non-advantageous section, so this process is the same as the above-described process of S88 (game start state control process).

Subsequently, the main CPU 101 updates the mode flag storage area (S139). That is, the main CPU 101 sets the mode (game state) during the advantageous section that has started. As described above, only the process referring to the determined internal winning combination is possible in the non-advantageous section, so this process is the same as the above-described process of S89 (game start state control process).

Subsequently, the main CPU 101 performs setting processing according to the set mode (S140). In this process, depending on the set mode, the game period of the mode (including the number of ceiling games, etc.) is set, and the lottery value (lottery table) in various lottery processes other than the internal lottery process is set. Such setting processing is appropriately performed when necessary. As described above, only the process referring to the determined internal winning combination is possible in the non-advantageous section, so this process is the same as the above-described process of S90 (game start state control process).

When the main CPU 101 determines in S135 that the current game section is not a non-advantageous section (that is, it is an advantageous section) (NO in S135), the main CPU 101 performs processing at the end of the game during the advantageous section (S141). The details of the processing at the end of the game during the advantageous section will be described later.

Subsequently, the main CPU 101 performs advantageous section end condition satisfaction check processing (S142). In this process, when the game ends, it is checked whether or not a transition condition (advantageous section end condition) for shifting from an advantageous section to a non-advantageous section is established. In the case of the first gaming machine, in this process, for example, if the operating conditions for various limit processes are satisfied based on the number of payouts in the advantageous section (see FIG. 16), or if the current mode is the end mode , it is checked whether 32 games have passed.

Subsequently, the main CPU 101 determines whether or not the condition for ending the advantageous section is satisfied (S143). When the main CPU 101 determines that the condition for ending the advantageous section is satisfied (YES in S143), the main CPU 101 performs an initialization process at the end of the advantageous section (S144). That is, the main CPU 101 ends the advantageous section and sets the non-advantageous section. In this process, depending on the end of the advantageous interval, for example, various counters (see FIG. 16) related to various limit processing, the mode (game state) during the advantageous interval, and the game period of the mode (the number of ceiling games, etc.) ) etc. (that is, information on the advantageous section) is cleared. After this process, the main CPU 101 ends the game end state control process. Further, when the main CPU 101 determines that the end condition of the advantageous section is not satisfied (NO in S143), the main CPU 101 ends the state control process at the end of the game.

(Processing at the end of the game during the advantageous section)
Next, referring to FIG. 31, the process at the end of the game during the advantageous interval performed at S141 of the above-described state control process at the time of game end will be described. Note that FIG. 31 is a flowchart showing an example of the procedure of the process at the end of the game during the advantageous interval.

First, the main CPU 101 performs various counter updating processes (at the end of the game) (S151). In this process, for example, various counters (see FIG. 16) related to various limit processes based on the number of payouts during the advantageous interval, various counters for managing the game period such as various modes (game states) during the advantageous interval, or other Various counters for managing the degree of advantage are updated according to predetermined update conditions (for example, the number of payouts, the number of times a combination of predetermined symbols is displayed, the mode of stop operation, etc.).

Subsequently, the main CPU 101 determines whether or not it is in the specific mode (AT state) (S152). When the main CPU 101 determines that it is in the specific mode (YES in S152), the main CPU 101 performs AT period management processing (at the end of the game) (S153). In this process, for example, when the game period in the AT state is allowed to be extended (for example, the number of games to be extended or the number of sets to be added) at the end of the game, it is determined whether or not such an extension execution condition is established. or extend the game period based on this determination result (if the game period in the AT state can be shortened, the shortening process is performed). In addition, in this process, the AT state game period may be managed regardless of whether it is extended, or the AT state game period is managed in the process of S151 described above, and in this process, only the process related to the extension is managed. may be performed. In the case of the first gaming machine, in this process, for example, the above-described 1G consecutive lottery is performed based on the sub-flag for winning the advantageous section, and the process for extending the pseudo bonus is performed according to the lottery result.

When the main CPU 101 determines that it is not in the specific mode (NO in S152), and after S153, it determines whether or not the mode transition condition is satisfied (S154). In the case of the first gaming machine, in this process, for example, it is determined whether or not the transition destination mode is determined according to the lottery result of the mode transition lottery described above based on the sub-flag at the time of advantageous zone winning.

When the main CPU 101 determines that the mode transition condition is satisfied (YES in S154), the main CPU 101 updates the mode flag storage area (S155). That is, the main CPU 101 sets the mode (game state) during the transferred advantageous section. In the case of the first gaming machine, in this process, for example, the transition destination mode determined according to the lottery result of the above-described mode transition lottery based on the advantageous zone winning sub-flag is set.

Subsequently, the main CPU 101 performs setting processing according to the set mode (S156). In this process, depending on the set mode, the game period of the mode (including the number of ceiling games, etc.) is set, and the lottery value (lottery table) in various lottery processes other than the internal lottery process is set. Such setting processing is appropriately performed when necessary. In addition, in the case of the first gaming machine, in this process, for example, the same process as the above-described process of S140 is performed. After this process, the main CPU 101 ends the game end process during the advantageous interval. Further, when the main CPU 101 determines that the mode transition condition is not satisfied (NO in S154), the main CPU 101 ends the processing at the end of the game during the advantageous interval.

[6-2. Periodical interrupt processing]
First, with reference to FIG. 32, the periodic interrupt processing executed by the main CPU 101 of the main control circuit 100 will be described. Note that FIG. 32 is a flow chart showing an example of the procedure of the periodic interrupt process.

Here, in the present embodiment, the periodic interrupt process cycle (one interrupt time) is set to "1.1172 ms". However, the periodic interrupt processing cycle is not limited to this. For example, the periodic interrupt processing may be executed at a cycle different from this, or even if the same cycle is set as this, some or all of the processing may be interrupted by an actual processing. By setting the number of times of interruption to "2" or more, the periodical interruption process may be executed at a period different from this.

First, the main CPU 101 saves a register (S201). Subsequently, the main CPU 101 performs input port check processing (S202). In this process, the input states (on state or off state) of various sensors and switches connected to the main control board 71 (including those connected via the main relay board 73) are checked. For example, the input state at the time of the previous interrupt is compared with the input state at the time of the current interrupt to check whether or not there has been a change in the input state. The change is stored in the port storage area 0 (not shown), and the input state not related to the change is stored in the input port storage area 1 (not shown) of the main RAM 103 as it is.

Subsequently, the main CPU 101 performs reel control processing (S203). In this processing, the stepping motors 51L, 51C, 51R are controlled to be driven, and the reels 3L, 3C, 3R are controlled to rotate and stop. Subsequently, the main CPU 101 performs communication data transmission processing (S204). In this process, each parameter of each command stored in the communication data storage area is transmitted to the sub control circuit 200 . In this process, if no command data is stored in the communication data storage area, the data stored in the input port storage areas 0 and 1 are sent to the sub control circuit 200 as an input state command.

In this embodiment, various command data are temporarily stored in the communication data storage area and then transmitted to the sub control circuit 200 in the periodic interrupt process. Alternatively, the data may be directly stored in a communication circuit (not shown) provided in the main control circuit 100 and transmitted to the sub control circuit 200 without being stored. Further, although detailed description is omitted in this embodiment, various command data are transmitted to the sub control circuit 200 by serial communication. may be configured to be transmitted to

Subsequently, the main CPU 101 performs 7-segment LED drive processing (S205). In this process, the display contents of, for example, the information display device 14 connected to the main control board 71 (including those connected via the main relay board 73) are controlled. Subsequently, the main CPU 101 performs timer update processing (S206). In this process, various timers managed by the main control circuit 100 are updated.

Subsequently, the main CPU 101 performs error detection processing (S207). In this process, it is detected whether or not various error states have occurred based on the input state and the like checked in S202 described above. Subsequently, the main CPU 101 performs door open/close check processing (S208). In this process, for example, based on the input state of the door opening/closing monitoring switch 56, the opening/closing state of the lower door mechanism DD is checked. A security signal is output from the external centralized terminal board 55 when various error states occur and when the input state of the door opening/closing monitoring switch 56 is in the open state (off state).

Subsequently, the main CPU 101 performs register restoration processing (S209). After this process, the main CPU 101 terminates the periodic interrupt process.

[7. Processing by sub control circuit]
Next, with reference to FIG. 33, an overview of the sub-side control processing executed by the sub-CPU 201 of the sub-control circuit 200 using each program will be described. FIG. 33 is a flowchart illustrating an example of an outline of sub-side control processing.

In the pachi-slot machine 1, various restrictions are placed on the main control circuit 100 side (including the main control board 71 and the main control board case) from the viewpoint of preventing fraudulent acts and unauthorized modifications. The 200 side (including the sub-control board 72 and the sub-control board case) is not so restricted. Therefore, the sub-control board 72 (and the sub-control circuit 200) can be used in various ways depending on the type and number of connected production devices, the type of production performed by the production device, and the manufacturing cost. configuration can be used. This is the reason why the term "outline" is used in FIG.

First, when the power is turned on, the sub CPU 201 performs the power-on processing similarly to the main CPU 101 (S301 and S302). In this process, it detects whether or not an abnormality has occurred when the power is turned on, initializes the data stored in the sub RAM 203, and performs various tasks necessary for performing various production execution control processes described later. is executed.

Further, when receiving a command transmitted from the main control circuit 100, the sub CPU 201 performs control processing for effect execution at the time of command reception (S303 and S304). In this processing, for example, when an initialization command is received, the parameter information of the received initialization command is referred to, and if the setting has been changed, the initialization processing is executed as appropriate on the sub side, and the setting has not been changed. If so, the sub-side also performs a process of returning to the state before the power failure.

Also, for example, when a start command is received, the parameter information of the received start command is referred to, and if the non-AT state, the content of the effect that suggests or notifies the internal winning combination, game state, etc. (as necessary (by lottery), and controls various production devices so that the production of the decided content is executed. In addition, if it is in the AT state, it determines the content of the effect for notifying the advantageous stop operation mode, and controls various effect devices so that the determined content of the effect is executed.

In addition, for example, when a lock command is received, the parameter information of the received lock command is referred to, the content of the effect linked with the content of the lock effect is determined, and various effects are performed so that the effect of the determined content is executed. control the device. Also, for example, when a reel stop command is received, the parameter information of the received reel stop command is referred to, and the stop start position and the planned stop position (or simply what stop operation was performed, etc.). To determine the content of performance and control various performance devices so that the performance of the determined content is executed. Further, for example, when a winning operation command is received, the parameter information of the received winning operation command is referred to, and when a privilege is granted, the content of the effect linked with the privilege to be granted is determined, and the determined content Control various production devices so that the production of is executed.

Further, the sub CPU 201 is connected to the sub-control board 72 (including those connected via the sub-relay board 74), for example, when the production buttons 10a and 10b are operated, the production is executed when the production button is operated. Control processing is performed (S305 and S306). In this process, for example, when an effect button is operated in accordance with the effect during execution of the operation-linked effect, various effect devices are controlled so that the content of the operation-linked effect changes. Further, for example, when a presentation button is operated to call up a user menu, which will be described later, during a non-game, control is performed to display the user menu. Also, when a presentation button is operated for selection/decision operation while the user menu is being displayed, control is performed according to these operations.

In addition, the sub CPU 201 performs other effect execution control processing when a trigger other than the above-described trigger is established (S307). In this process, for example, when the non-operation period during which no game-related operation or user-menu-related operation is performed reaches a predetermined period (for example, about 30 seconds), the content of the effect related to the demonstration state notification is determined and determined. Various production devices are controlled so that the production of the content is executed.

[8. Other functions of the pachislot machine]
As described above, the pachi-slot machine 1 has various functions for controlling games, various functions for controlling effects, and various configurations for realizing these functions. It can also have functions. An example of other functions on the player side and an example of other functions on the amusement arcade side will be described below.

[8-1. Player side]
For example, when a user menu is displayed by a player's performance operation, a desired menu is selected in the user menu, and further selection/decision operations are performed on the selected menu as appropriate, the player can obtain various information. , various settings can be made.

For example, when the "arrangement/payout table" is selected and determined, it is possible to confirm the game information indicating the arrangement of symbols in the pachislot machine 1, the specified combination of symbols, and the payout (details of benefits) at the time of winning. is displayed in the effect display section.

Also, for example, when "volume/light intensity adjustment" is selected/determined, the brightness of various display devices in the pachislot machine 1, the volume of sound output from the speaker group, or the light intensity of the lamp/LED group, etc. are set. A possible setting screen is displayed in the effect display section. In order to enable more detailed settings or to accept operations related to settings more easily at the time of such settings, various operation units for receiving the game operations of the player are can be used as a part of the operation unit that receives the operation related to (that is, the operation unit that receives the effect operation).

Further, for example, when "custom" is selected and determined, the performance mode in the pachislot machine 1 (for example, the type of character used for the performance (the type of the character (display mode) itself, the voice corresponding to the character or the type of costume or item (individual display mode) related to the character), the probability of occurrence of production (including the type of expectation at the time of occurrence of production, etc.), or the mode of suggestion or notification (performance execution timing etc.) is displayed in the effect display section. In order to enable more detailed settings or to accept operations related to settings more easily at the time of such settings, various operation units for receiving the game operations of the player are can be used as a part of the operation unit that receives the operation related to (that is, the operation unit that receives the effect operation).

Also, for example, when "Unimemo" is selected and determined, it is possible to receive information providing services using the player's portable terminal (for example, mobile phone, smart phone, etc.). In such an information providing service, for example, a player performs a login operation to start a game (the game may be started without a login operation), and when the game ends, a logout operation is performed to obtain game history information (for example, , how many games have been played in total, how many times an advantageous game state has occurred, how many cards have been obtained at the maximum, etc.).

In addition, for example, the game history information includes information indicating the types of characters that can be displayed during the game and the types of music that can be output according to the result of the game (satisfaction of the release condition). It also includes information about accompanying benefits, such as information indicating the types of characters that can be displayed on the mobile terminal and the types of music that can be output.

It should be noted that various methods can be employed for the login/logout method in such an information providing service. For example, login/logout may be performed by using the player's terminal and having the player read a two-dimensional code displayed on the effect display unit, or the player may enter a password. or store the password (specifically, for example, when logging out at the end of the game, instead of the two-dimensional code, a character string of about 4 to 10 digits can be displayed as the password for the next input, and The password can be obtained by the player taking notes on paper or taking a picture with a mobile terminal, etc., and the password obtained in this way can be entered at the next login before the start of the game). - Logout may be performed. Further, it is also possible to perform login/logout by appropriately combining these methods.

[8-2. Amusement store side]
For example, a hall menu is displayed by a setting confirmation operation (setting change operation or other operation by the amusement hall manager) by the manager of the game parlor, and a desired menu is selected in the hall menu. Furthermore, when the selection/decision operation is performed as appropriate for the selected menu, the manager of the game parlor can obtain various information and make various settings.

For example, when "time setting" is selected and determined, a setting screen is displayed on the effect display section, which enables setting of the date and time in the pachi-slot machine 1. FIG. Note that the date and time can be configured to be automatically updated, for example, in the sub-side power-on process (see S302 in FIG. 33).

Further, for example, when the "total medal information" is selected and determined, history information indicating the number of inserted and the number of paid out during a predetermined period (for example, each business day for 7 business days) in the pachi-slot machine 1 is displayed. An information screen that can be confirmed is displayed in the effect display section. Note that such a menu can also be configured as a menu in the user menu.

Also, for example, when "setting change/confirmation history" is selected/determined, the number of setting change operations and setting confirmation operations within a predetermined period (for example, each business day for seven business days) in the pachislot machine 1 An information screen is displayed in the effect display section, in which history information indicating is recognizable. In addition, for example, when "error information history" is selected and determined, history information indicating the date and time of occurrence of an error in the pachislot machine 1 within a predetermined period (for example, each business day for 7 business days) and the content of the error. is displayed in the effect display section.

Further, for example, when "monitoring history" is selected and determined, the history information indicating the date and time when the door is opened within a predetermined period (for example, each business day for seven business days) in the pachi-slot machine 1 and the period thereof is displayed. An information screen that can be confirmed is displayed in the effect display section. Further, for example, when "warning setting" is selected and determined, a setting screen is displayed on the effect display section, which enables setting of various warning notification modes and frequencies in the pachi-slot machine 1 .

Further, for example, when the "power saving mode setting" is selected and determined, a setting screen is displayed on the effect display section to allow setting of whether or not to activate the power saving function of the pachi-slot machine 1, and the like. Note that such a menu can also be configured as a menu in the user menu. In addition, in order to enable more detailed settings at the time of such settings, or to enable reception of operations related to settings more easily, various operation units for receiving game operations of the player may be can be used as a part of the operation unit that receives the operation related to (that is, the operation unit that receives the effect operation).

Further, for example, when "stop setting" is selected/determined, a setting screen is displayed on the effect display section to enable setting of whether or not to activate the stop function of the pachi-slot machine 1, and the like. It should be noted that the stop function is a function that, when a predetermined operating condition is met, disables the game until the manager of the game parlor performs a release operation (for example, a reset operation). Further, the predetermined operating condition may be satisfied, for example, when the advantageous interval is forcibly terminated by executing the limit process described above, or may be established in a specific state (for example, a bonus state, an increase interval, or an advantageous condition). It may be established when the section (any of the sections (including the effect section)) ends. Further, when the stop function is set to ON state, an automatic settlement function, which will be described later, may be set to ON state in conjunction with this.

Further, for example, when "automatic settlement setting" is selected/determined, a setting screen is displayed in the effect display section, enabling setting of whether or not to activate the automatic settlement function in the pachi-slot machine 1, and the like. Note that the automatic settlement function is a function of automatically settlement of credits (that is, all of the credited gaming value is automatically returned) when a predetermined operating condition is satisfied. Further, the predetermined operating condition may be satisfied, for example, when the advantageous interval is forcibly terminated by executing the limit process described above, or may be established in a specific state (for example, a bonus state, an increase interval, or an advantageous condition). It may be established when the section (any of the sections (including the effect section)) ends. Further, when the automatic settlement function is set to ON state, the stop function may also be set to ON state in conjunction with this.

In addition, when setting the stop function and automatic settlement function, in order to enable more detailed settings, or to enable reception of operations related to settings more easily, various operation units that accept game operations of the player can be used as part of the operation unit that receives the operation related to the setting (that is, the operation unit that receives the effect operation). However, in this case, it is not desirable to unnecessarily increase the number of operation units that can be accepted, so only a specific operation unit (for example, a stop button) should be used as part of the operation unit that accepts operations related to the setting. It is good to be able to do it.

[9. Extension example]
So far, the pachislot machine 1 has been described as an example of a gaming machine to which the invention according to the present embodiment can be applied, but the gaming machine to which the invention according to the present embodiment can be applied is not limited to this. For example, the present invention can be applied to gaming machines such as so-called "pachinko machines" and "slot machines", and similar effects can be obtained. That is, the invention according to the present embodiment can be applied to all gaming machines as long as they are capable of performing a game (performing game control) in accordance with a game action (operation) of a player. Also, the configuration and functions of the gaming machine including the pachi-slot machine 1 are not limited to those described above, and various modifications and extensions are possible. Although it is only an example, such an extension example will be described below.

(pachinko machine)
A pachinko machine includes, for example, a game board having a game area where game balls can roll and flow down, a glass door including a protective glass that protects the game area while making it visible from the outside, and an effect display device provided in a predetermined area of the game area. (It may be provided outside the game area), a payout unit that pays out game balls, and a board unit including various control boards that perform various controls related to games and effects. (sometimes simply referred to as a “frame” or the like).

In addition, on the front side of the pachinko machine, for example, there are a shooting handle as one of the player's operation means, an upper tray capable of storing game balls to be played, and a lower tray capable of storing paid-out game balls. etc. are provided. It should be noted that many of them are provided with the above-described production buttons and movable production devices. In addition, the game area includes, for example, a starting area through which a game ball can pass (sometimes referred to as a "starting opening"), a specific area (sometimes referred to as a "V winning opening", etc.), A variable winning device (sometimes referred to as a "large winning opening") that can change between a state in which a game ball is easy to win and a state in which it is difficult to win, and identification information (referred to as "symbols" A variable display device that can variably display (including "special design" and "normal design") is provided.

In the pachinko machine, a player operates a shooting handle to shoot game balls into a game area to play a game. For example, when the launched game ball passes through the starting area, the variable display is started. Also, at this time, the current state (for example, whether the probability variation game state is relatively high hit probability) and the probability according to the type of the start region, etc., whether to transition the game state (for example, game It is determined whether or not to shift to a big hit game state or a small hit game state that is advantageous to the player (that is, it is determined by lottery (or determination) whether or not to shift the game state). After that, when a condition for stopping the variable display (for example, the end of the set variable time period) is established, the variable display is stopped in a stop mode according to the determination result. At this time, if the determination result is to shift the game state (hit), the stop mode to be stopped also becomes a display result corresponding to the hit, and when the display result is displayed, it corresponds to the hit. Move to the game state to play. On the other hand, if the determination result does not cause the game state to shift (loss), the stop mode to be stopped will also be a display result corresponding to the loss, and the game state will not shift. In addition, for example, when the launched game ball passes through a specific area (the specific area is usually placed in a state where it is difficult for the game ball to pass through), the game state is displayed regardless of the variable display device. It is decided to migrate.

That is, in the pachislot machine 1, the game is started when the player bets the required medals and the player performs a start operation, whereas in the pachinko machine, the player operates the handle to shoot the required game balls. For example, the game is started when the game ball passes through the starting area, but both are common in that the game is started by the player's game action. In addition, the pachislot machine 1 and the pachinko machine are common in that when the start opportunity is established, the final stop mode permitted to be displayed (in other words, the content of the privilege to be given) is determined. .

In addition, in the pachislot machine 1, the variable display is basically stopped by the player's stop operation, whereas in the pachinko machine, the variable display is stopped when the stop condition is met (not by the player's stop operation). Although they are different in that the variable display is stopped, they are common in that the variable display is stopped according to the result of determination made in advance, and a benefit is given according to the stopped mode. In addition, the pachislot machine 1 and the pachinko machine are common in that they can execute effects related to games. For example, the effect display device functions as the effect display section and the information display section described above. Also, in the pachinko machine, it is of course possible to provide an effect execution means such as the above-mentioned lamp, speaker, or other effect device, and to execute the effect by means of these means.

In many pachinko machines, decorative patterns (which may also be referred to as "identification information" or the like) are variably displayed in the effect display device. As described above, the original game result is displayed on the variable display device, but the variable display device is configured to be small, and the display result is also displayed by the lighting pattern of a plurality of LEDs. Therefore, in many cases, it is difficult for the player to recognize the game result. For this reason, in pachinko machines, it is the mainstream to play a game by variably displaying (and stopping) decorative symbols on the performance display device so as to interlock with the variable display of the variable display device. . In addition, such a variable display of decorative patterns may be performed after a certain period of delay when the start opportunity is met, or may be temporarily stopped before the stop condition is met. However, basically, similar to the above-mentioned variable table device, identification information is displayed variably or stopped according to the progress of the game (for example, in the case of winning, decorative patterns are displayed in a special stop mode (for example, ) is stopped and displayed, and in the case of a failure, the decorative pattern is stopped and displayed in a non-special stop mode (for example, loose stitches)). It is also possible to apply the invention according to the embodiment.

That is, in the present embodiment, the various matters described as the configuration of the external structure or internal structure of the pachi-slot machine 1 have characteristics unique to the pachi-slot machine 1 (for example, medals are essential and cannot be replaced with game balls, etc.). ), it can be applied as the configuration of the external structure or the internal structure of the pachinko machine.

Also, in the pachinko machine, various controls related to the game are performed by a main control circuit as a game control unit mounted on the main control board (part of the control related to payout is (Although it may be performed by the payout control circuit mounted on the payout control board, including this), various controls related to the effect are performed by the sub control circuit as the effect control unit mounted on the sub control board. Various items described as the electrical configuration of the pachi-slot machine 1 can be applied to the electrical configuration of the pachinko machine, except for items that are unique to the pachi-slot machine 1 (for example, items related to the stop operation, etc.).

In the pachi-slot machine 1, as described above, the bonus state, RT state, AT state, It is possible to provide an ART state or the like in which these are combined. For example, in the bonus state, by making the lottery mode of the minor winning combination more advantageous than in the non-bonus state, it is possible to continue the state in which medals are easily awarded (increase) for a certain period of time, and in the RT state, the replay winning combination is made possible. By making the lottery mode more advantageous than the non-RT state, it is possible to continue for a certain period of time a state in which it is difficult to lose (as a result, medals are difficult to decrease), and in the AT state, an advantageous stop operation mode By being notified, it is possible to continue the state in which medals are easily awarded (increase) for a certain period of time.

On the other hand, in a pachinko machine, it is possible to provide various game states having properties similar to these. For example, in a big win game state or a small win game state, the variable winning device is controlled differently than usual, so that the game ball can be changed to a state where it is easy to win, thereby giving the game ball. It is possible to continue the state of easy (increase) for a certain period of time. Also, for example, in a time-saving game state (sometimes referred to as an "electric sapo state"), normal symbols are controlled differently than usual, making it easier for game balls to pass through the starting area. This makes it possible to increase the lottery frequency of the variable display device and to maintain a state in which the number of game balls is difficult to decrease for a certain period of time. Also, for example, in the probability variable gaming state, the special symbol is controlled differently than usual, so that the winning probability by the variable display device is increased (as a result, the number of game balls tends to increase) The state is continued for a certain period of time. is possible.

That is, in the present embodiment, as the game characteristics of the pachi-slot machine 1, the various items described as the configuration of control relating to the transition (or transition) of the game state have characteristics unique to the pachi-slot machine 1 (for example, the It can be applied as a control configuration related to the transition (or transition) of the game state of the pachinko machine, excluding those accompanied by transition. In addition, the same applies to various other matters described as the game characteristics of the pachi-slot machine 1.

In addition, although it is a time-saving game state, even in pachinko machines, it is possible to shift to a time-saving game state when the number of games during a non-time-saving game state (normal game state) reaches a specified number of times. there is That is, even in a pachinko machine, when a disadvantageous state (for example, normal game state) continues for a predetermined period (for example, 900 games (rotation)) without shifting to a ceiling function (advantageous state (for example, jackpot game state)) Since it is possible to install a function that can shift to an advantageous state (for example, a time-saving gaming state) as a remedy for addiction, various items described as the configuration related to the ceiling function of the pachislot machine 1 are the configurations related to the ceiling function of the pachinko machine. can be applied as

In addition, although it is a time-saving game state, even in a pachinko machine, in a non-time-saving game state (normal game state), if the stop mode of the variable display device becomes a display result corresponding to a specific loss, this It is possible to shift to a time-saving game state with this as an opportunity. That is, even in pachinko machines, it is possible to transition (transition) the game state (not triggered by the transition to the jackpot game state) by displaying a specific display result (combination of specific symbols). , The various items described as the configuration related to the transition (transition) of the RT state by displaying a specific combination of symbols of the pachinko machine 1 are the configurations related to the transition (transition) of the time-saving game state by displaying a specific display result of the pachinko machine can be applied.

(Medalless machine)
In the pachi-slot machine 1 of the present embodiment, the betting operation of the player (that is, the operation of inserting the medals on hand into the medal insertion slot 5 to bet, or the MAX bet button 6a or the 1 bet button of the credited medals) 6b to bet) is one of the start conditions, and if medals are to be paid out when the game is over, the hopper device 32 is driven to open the medal payout port 11. Although a form in which medals are paid out or credited is explained, the configuration of the pachi-slot machine 1 is not limited to this.

For example, the game player bets the game value necessary for the game, the game is played based on the bet, and a privilege is given (for example, the game value is given) based on the result of the game. The invention according to is applicable. In other words, not only is medals physically thrown in and paid out by the action of the player, but also the gaming value possessed by the player is electromagnetically managed within the pachislot machine 1 ( Alternatively, even if it is not electromagnetic, at least it is managed in a manner that prevents the player from directly contacting the game value), and it can be applied to a game that can be played without medals. Here, such a pachi-slot machine 1 is referred to as a "medalless game machine". Note that the medal-less gaming machine is sometimes referred to as a "managed gaming machine" or an "enclosed gaming machine".

It should be noted that it may be the main control circuit 100 (main control board 71) itself that electromagnetically manages the gaming value held by the player, or it may be attached to the main control circuit 100 (main control board 71). It may be a (connected) game value management device (hereinafter, such a management device may be referred to as a "medal count control board"). An example in which this game value management device is provided will be described below.

The gaming value management device comprises at least ROM and RWM (or RAM), is provided in the pachi-slot machine 1, and is a communication device (hereinafter, when such a communication device is referred to as a "connection terminal board" ) to an external game value providing device (hereinafter, such a game value providing device may be referred to as a “communication dedicated unit”) so as to be capable of two-way communication. The gaming value management device carries out necessary communication with an external gaming value providing device to perform a gaming value lending operation (i.e., to provide the gaming value necessary for the player to bet on the gaming value). action to give the game value), action to give the game value (that is, action to provide the game value to the player in the case of winning the role (the win is established), etc.), and these It is possible to perform an operation of electromagnetically recording the game value provided by the operation of . Note that the game value providing device may be called a "game value (game medium) handling device", a "game value (game medium) lending device", or a "sandwich".

Also, the external game value providing device is connected to an external ball output management device (ball output management server). It is configured to be able to transmit the payout management information via the providing device. Here, the paid ball management information is composed of various kinds of information necessary for enabling an external paid ball management device to manage the paid balls. An example of the ball-out management information will be described later. Also, the external game value providing device and the external ball management device are connected via, for example, an internet line.

Here, "balls paid out" directly means the number of game media paid out. (for example, how much the player is positive (how much the game store is negative)), or how much the player is negative (how much the game store is positive) It is a concept that includes the degree of continuation of an advantageous state (for example, bonus state, AT state, or a series of advantageous sections, etc.), or the degree of gambling assumed by a combination of these.

Further, for example, a possessed game value number display device (not shown) for displaying the number of possessed game values is provided on the front side of the pachi-slot machine 1, and the game value management device controls the number of game values based on the management result of the number of game values. The game value number displayed on the possessed game value number display device of the lever may be managed. That is, the gaming value management device may not only record the total number of gaming values that a player can use for gaming by an electromagnetic method, but may also be configured to be able to control the display of the recording result. . In this case, the gaming value management device has the ability for the player to freely transmit a signal indicating the number of recorded gaming values to the external gaming value providing device. It has the performance that the recorded game value cannot be reduced except when it is operated directly, and the signal indicating the recorded game value can be transmitted only through a communication device. is desirable.

It should be noted that the gaming value management device not only has the function of electromagnetically managing the gaming value of the player using an external gaming value providing device, but also the number of gaming values betted by the physical actions of the player and the number of gaming values of the pachislot machine 1. It may have a function of managing the number of game values paid out by the physical action of the player. That is, it may also be possible to manage the actual insertion and payout of medals in the conventional pachi-slot machine 1 . In this way, the pachi-slot machine 1 can be controlled by a conventional method, or by a method such as the above-mentioned medalless game machine, so that the pachi-slot machine 1 can be controlled with any specification. Even if there is, it can be set as a common configuration. Further, in this case, the game value management device may employ a method of directly controlling the selector 31 and the hopper device 32, which are controlled by the main control circuit 100 (main control board 71), It is also possible to adopt a method of indirectly controlling by transmitting the control result.

In addition to the above, the pachi-slot machine 1 may be provided with various operation means necessary for the operation of the medalless game machine, such as a player-operable lending operation means and return (settlement) operation means. In addition, the game value providing device includes various devices such as an insertion slot for valuable values such as bills, an insertion slot for recording media (such as IC cards), and a non-contact communication antenna for depositing electronic money etc. from a mobile terminal. In addition, various operation means necessary for the operation of the medalless game machine, such as a lending operation means and a return operation means that can be operated by the player, may be provided (none of them are shown). Note that the insertable recording medium includes not only non-member recording media issued on the day at the game parlor, but also member recording media owned by members of the amusement parlor. The game value recorded in the non-member recording medium is valid only on the day (and becomes invalid after the next day), but the game value recorded in the member recording medium is valid from the next day.

An example of the game flow in this case will be described. For example, first, the player deposits valuable value into the game value providing device by any method. The game value providing device subtracts a predetermined number of value values in response to the operation of any of the lending operation means by the player, and provides the pachi-slot machine 1 with the game value corresponding to the value value thus subtracted. Then, the player plays the game, and repeats the above operation when the game value is required. After that, the player operates one of the return operation means when ending the game after acquiring a predetermined number of game values according to the result of the game. The game value management device transmits the number of game values to the game value providing device according to the player's operation of any of the return operation means. The game value providing device ejects the recording medium recording the transmitted game value number. The game value management device clears the game value number stored by itself when the game value number is transmitted. The player can take the ejected recording medium to a prize exchange place or the like to exchange it for a prize, or the ejected recording medium can be sent to a game value providing device corresponding to another pachi-slot machine 1. By inserting it, the board can be moved and the game can be continued. Also, if the ejected recording medium is a member's recording medium, it is valid from the next day onwards, so the game can be stopped here.

In the above example, the game value management device transmits the total number of game values to the game value providing device in response to the player's return operation. Only the number of game values desired by the player may be transmitted. That is, the game value owned by the player may be divided. In addition, although the game value providing device records the transmitted game value number on a recording medium and discharges it, the above-mentioned non-contact communication antenna or the like is used to transfer the same value to the mobile terminal of the player. For example, cash or cash equivalents may be dispensed as long as it provides something of equal value to the player.

Further, the pachi-slot machine 1 or the game value providing device is provided with lock operation means that can be operated by the player, and communication between the game value management device and the game value providing device is disabled according to the operation of the lock operation means. It may be possible to control the state (locked state). In this case, in the pachi-slot machine 1 or the gaming value providing device, for example, setting a personal identification number (and inputting the set personal identification number), issuing a one-time password (and inputting the issued one-time password), or biometric authentication and so on, and the locked state is released when the result of the authentication process is normal.

According to the medalless gaming machine described so far, compared to the case where the game medium is physically provided for the game, for example, a part of the external structure such as the medal insertion slot 5 and the medal payout opening 11, or the selector 31, etc. Since it is no longer necessary to provide some internal structures such as the hopper device 32, it is possible not only to reduce the cost and manufacturing cost of the game machine, but also to reduce the power consumption of the game machine. In addition, since it becomes more difficult to access the inside of the gaming machine, it is possible to prevent fraudulent acts on the gaming machine. Furthermore, since the player does not come into direct contact with the game medium, the game environment is improved and noise can be reduced. That is, it is possible to provide a gaming machine capable of improving various environments surrounding the gaming machine.

(Configuration example of a medalless game machine)
Next, with reference to FIG. 34, a configuration example when the pachi-slot machine 1 is configured as a medalless game machine will be described. FIG. 34 is a diagram showing an example of the configuration of a medalless gaming machine. In the following, a configuration example in which a medal count control board (game value management device) is provided will be mainly described.

As described above, the medal number control board is connected to the main control board 71 and manages the number of medals (game value number) owned by the player. Also, the medal number control board is connected to a dedicated communication unit (game value providing device) via a connection terminal board (communication device). Further, the medal number control board transmits the paid ball management information to the paid ball management device via the connection terminal board and the dedicated communication unit. A medal count control circuit (not shown) is mounted on the medal count control board. The medal number control circuit includes, for example, a medal number control CPU (not shown), a medal number control ROM (not shown), and a medal number control RWM (not shown).

Note that the ball-out management device is, for example, a server for management of ball-out management managed by (the information center of) an association to which the gaming machine maker joins, and the transmitted ball-out management information is accumulated in the ball-out management device. Thus, it is provided for the purpose of making it possible to monitor whether the gambling nature of each gaming machine is appropriate (ball output performance).

Therefore, from such a point of view, the medal number control board and the connection terminal board, like the main control board 71, have important functions in the pachi-slot machine 1. It must be provided inside the pachi-slot machine 1. Configuration example 1 and configuration example 2 shown in FIG. 34 show an example of such a mode.

<Configuration example 1>
Configuration example 1 shown in FIG. 34 shows that the medal number control board and the connection terminal board are accommodated in the main control board case, like the main control board 71 . Here, the main control board case is usually subjected to various sealing processes to make it difficult to open (or remove) or to make it possible to recognize the traces of opening (or the number of times it has been opened). (for example, sealing by crimping, affixing a sealing seal, or affixing a crimping seal that describes a record of cutting the crimping, etc.).

Therefore, if the medal number control board and the connection terminal board are accommodated in the main control board case, the same security effect as that of the main control board 71 can be obtained, and fraudulent acts and illegal modifications can be prevented appropriately.

<Configuration example 2>
In configuration example 2 shown in FIG. 34, unlike configuration example 1 described above, the medal count control board and the connection terminal plate are accommodated in a medal count control board case provided separately from the main control board case. indicates that there is The medal count control board case is configured as a transparent (or substantially transparent) resin case similar to the main control board case. The plate shall be housed in a readily visible condition.

Here, in the medal number control board case of configuration example 2, the same sealing process as in the main control board case can be performed, or at least a part of the sealing process can be performed. can also For example, the medal number control board case may be sealed by caulking in the same manner as the main control board case, but no sealing seal is attached. Also, for example, in the main control board case, it is obligatory to use a predetermined crimped seal, but in the medal number control board case, any seal may be used as the crimped seal.

<Example of accumulated data>
The accumulated data example shown in FIG. 34 shows an example of various data accumulated in the payout management device. That is, it shows an example of the payout ball management information that the medal number control board transmits to the payout ball management device via the connection terminal board and the dedicated communication unit. It should be noted that this is only an example, and it is possible to adopt a configuration in which some of the various types of information shown in FIG. 34 are not transmitted, or a configuration in which information other than the various types of information shown in FIG. 34 is transmitted. can also

Also, the timing for the medal count control board to transmit information to the communication dedicated unit is arbitrary, and the timing for the communication dedicated unit to transmit information to the payout management device is also arbitrary. It may be transmitted at any timing as long as the ball payout management device can monitor the ball payout performance of each gaming machine for at least one unit (for example, one business day of the game parlor). . For example, the timing at which the medal count control board transmits information to the communication-dedicated unit and the timing at which the communication-dedicated unit transmits information to the ball management apparatus may be different timings. Also, for example, the timing at which the medal number control board transmits information to the communication dedicated unit may be different timing depending on the type of information.

The accumulated data “total number of inserted coins” is the accumulated number of inserted coins per unit after the power of each gaming machine is turned on. For example, the medal number control board sends information on the number of game values betted by the player's betting operation to the communication dedicated unit at a predetermined timing (for example, for each unit game), excluding the bets made by the replay operation. The dedicated communication unit transmits the cumulative total of the information to the payout management device at a predetermined timing (for example, at the end of business hours of the amusement arcade).

The accumulated data "total number of payouts" is the cumulative number of payouts per unit since each gaming machine was powered on. For example, the number-of-medals control board sends the information on the number of game values given by the payout process of the gaming machine to the communication dedicated unit at a predetermined timing (for example, for each unit game), excluding those given by the operation of replaying. The dedicated communication unit transmits the cumulative total of the information to the payout management device at a predetermined timing (for example, at the end of business hours of the amusement arcade).

Accumulated data "MY" is the maximum number of difference generated during one unit after the power of each gaming machine is turned on (in other words, the number of difference obtained during the period during which the game value increases the most in one unit. (referred to as "MY"). For example, the number-of-medals control board calculates such a maximum number of difference number, and transmits the calculated information to the communication dedicated unit at a predetermined timing (for example, when the amusement arcade closes), and the communication dedicated unit receives the information is transmitted to the payout management device at a predetermined timing (for example, at the end of business hours of the amusement arcade).

The accumulated data "total payout number of accessories" is the cumulative number of payouts per unit after the power of each gaming machine is turned on, and the cumulative number of payouts paid out during the operation of various accessories. . For example, the medal number control board is dedicated to communication of information on the number of game values given by the payout process of the gaming machine during operation of various roles at a predetermined timing (for example, for each unit game during operation of various roles). unit, and the communication-dedicated unit transmits the cumulative total of the information to the pay-out management device at a predetermined timing (for example, when the amusement arcade closes its business).

Accumulated data ``total number of continuous bonuses paid out'' is the cumulative number of payouts per unit since each gaming machine was powered on, and continuous bonuses (RB, including RB during BB operation). It is the cumulative number of payouts paid out during the operation of. For example, the medal number control board is dedicated to communication of information on the number of game values given by the payout process of the gaming machine during operation of the continuous role at a predetermined timing (for example, for each unit game during operation of the continuous role). unit, and the communication-dedicated unit transmits the cumulative total of the information to the pay-out management device at a predetermined timing (for example, when the amusement arcade closes).

In addition, the medal number control board transmits various information that can be displayed on the role ratio monitor device 54 to the communication dedicated unit at a predetermined timing (for example, at the time of calculation by the role ratio monitor device 54), and the communication dedicated unit The information is transmitted to the ball management device at a predetermined timing (for example, at the time of transmission from the medal count control board). Note that the accumulated data “Role Product Ratio” corresponds to, for example, the above-mentioned role product ratio information, the accumulated data “Continuous Role Product Ratio” corresponds to, for example, the above-described continuous role product ratio information, and the accumulated data “Advantageous "Section ratio" corresponds to, for example, the above-mentioned specific section ratio information, and the accumulated data "Instructed role product ratio" corresponds to, for example, the above-mentioned role product ratio information that is subject to aggregation and calculation even during the AT state. , the accumulated data "ratio of state of accessories, etc." corresponds to the above-mentioned specific section ratio information, which is subject to aggregation and calculation even during operation of various accessories, for example.

The accumulated data “number of times played” is the accumulated number of times played per unit since each gaming machine was powered on. For example, the medal number control board transmits information on the number of games played at a predetermined timing (for example, each unit game) to the communication dedicated unit, and the communication dedicated unit calculates the cumulative total of the information at a predetermined timing ( For example, it is transmitted to the payout management device at the end of business hours of the amusement arcade.

The accumulated data "main control chip ID number" is the individual identification number (also called "CPUID", which is called "chip ID number") of the main control circuit 100 of each gaming machine. For example, when the medal number control board transmits various information to the communication dedicated unit, it transmits information including this individual identification number. Information including this individual identification number is transmitted.

The accumulated data "main control chip maker code" is a maker code recorded in the management area of the main ROM 102 of the main control circuit 100 of each gaming machine. For example, when the medal number control board transmits various information to the communication dedicated unit, it transmits information including this manufacturer code, and the communication dedicated unit transmits this transmitted information when transmitting various information to the ball management device. Send information including the manufacturer code.

The accumulated data "main control chip product code" is a product code recorded in the management area of the main ROM 102 of the main control circuit 100 of each gaming machine. For example, when the medal number control board transmits various information to the communication dedicated unit, it transmits information including this product code. Send information, including product codes.

The accumulated data "medal number control chip ID number" is the individual identification number of the medal number control circuit of each gaming machine. For example, when the medal number control board transmits various information to the communication dedicated unit, it transmits information including this individual identification number, and when the communication dedicated unit transmits various information to the ball management device, Information including this individual identification number is transmitted. If the main control board 71 is configured to transmit various information to the communication dedicated unit without providing the medal number control board, the information becomes "0".

The accumulated data "medal number control chip maker code" is a maker code recorded in the management area of the medal number control ROM of the medal number control circuit of each gaming machine. For example, when the medal number control board transmits various information to the communication dedicated unit, it transmits information including this manufacturer code, and the communication dedicated unit transmits this transmitted information when transmitting various information to the ball management device. Send information including the manufacturer code. If the main control board 71 is configured to transmit various information to the communication dedicated unit without providing the medal number control board, the information becomes "0".

The accumulated data "medal number control chip product code" is a product code recorded in the management area of the medal number control ROM of the medal number control circuit of each gaming machine. For example, when the medal number control board transmits various information to the communication dedicated unit, the information including this product code is transmitted. Send information, including product codes. If the main control board 71 is configured to transmit various information to the communication dedicated unit without providing the medal number control board, the information becomes "0".

In this way, the paid-out ball management device can store various information (discharged-ball management information) transmitted from the gaming machine. The ball management information also includes a plurality of pieces of individual identification information (for example, the above-described “main control chip ID number” to “medal number control chip product code”) that can identify individual gaming machines. Therefore, the ball management device can identify the gaming machine that is the transmission source by these pieces of individual identification information. are different, it is possible to recognize the possibility that one of the control boards has been replaced (that is, the possibility of fraud or unauthorized modification).

In addition, the put-out ball management information includes a plurality of pieces of put-out ball information (for example, the above-described “total number of inserted balls” to “number of times played”) that can identify the performance of one unit of put-out balls. Therefore, the paid-out ball management device can recognize whether the gambling nature of the gaming machine of the transmission source is within an appropriate range based on the paid-out ball information. For example, if the "total number of payouts" or "instructed accessory ratio" becomes extremely high from a certain point, there is a possibility that fraudulent acts or unauthorized modifications have been made, or that there is some flaw in the specification design in the first place. It is possible to recognize the possibility that there was

Then, when the above-mentioned possibility is recognized by the paid-out ball management device, it can be expected that the result will be notified to the game parlor or the game machine maker, and appropriate countermeasures will be taken. That is, a plurality of management gaming machines, a game value providing device (communication dedicated unit) that transmits the payout management information transmitted from the management gaming machines to the payout management device, and based on the transmitted payout management information, each By constructing a management system including a payout management device that manages the payout performance of managed gaming machines, it is possible to appropriately manage all managed gaming machines.

<Modification 1>
As described above, the medalless gaming machine can be configured so that the number of game values possessed by the player is managed by the medal number control board. Therefore, the medal count control board may be provided with a medal count monitor device (not shown) so that the administrator of the game parlor can grasp such management status or other information.

The medal count monitor device is composed of, for example, a 4-digit 7-segment LED, and is provided inside the medal count control board case. The medal number monitor device displays various information (for example, part or all of the above-described ball output management information) regarding the number of game values aggregated and calculated by the medal number control CPU (or may be the main CPU 101). Display sequentially. If the display contents of the role ratio monitor device 54 are all displayed by the medal number monitor device, the role ratio monitor device 54 may not be provided. Alternatively, the role ratio monitor device 54 may also be used as the medal count monitor device.

Further, the medal count monitor device may be mounted on the medal count control board, or may be mounted on another board (for example, a connection terminal board) connected to the medal count control board. good too. Moreover, as long as it is inside the cabinet G, it may be provided in another place. For example, it may be provided on the medal count control board case. Also, a management switch may be provided in the cabinet G for starting the display on the medal number monitor device or for switching the content, and various information may be displayed when this switch is operated. Further, on the premise of using such a management switch, for example, the information display device 14 may also be used as a medal number monitor device.

The medal number monitor device may display the type of error state that has occurred when various error states related to itself have occurred. For example, when a communication error occurs with the main control board 71, when a communication error occurs with the connection terminal board, when a communication error occurs with the game value providing device, or when an abnormality occurs in the token number control RWM. In some cases, the corresponding numerical value may be displayed. In this case, in order to make it possible for the manager of the game parlor to easily recognize which error state the displayed numerical value corresponds to, the corresponding relationship is displayed in or near the medal number control board case. It is sufficient to provide a descriptive section (affixing a sticker, printing, etc.) to indicate.

<Modification 2>
As described above, in the medalless game machine, the medal number control board can be configured to transmit the ball output management information to the outside via the connection terminal board. Here, in this embodiment, an external collective terminal board 55 is additionally provided for transmitting information to the outside. Therefore, the connection terminal plate and the external collective terminal plate 55 can be configured as follows, for example.

For example, the connection terminal board and the external collective terminal board 55 are configured as a common terminal board. As a result, not only can the number of parts be reduced, but also the number of wires directed to the outside can be reduced, so that the security effect can be enhanced.

Also, for example, the connection terminal plate and the external collective terminal plate 55 are configured as one unit. Further, for example, the connection terminal plate and the external collective terminal plate 55 are arranged at least in the cabinet G in close proximity. As a result, the working efficiency at the time of connection can be improved. In addition, the length of the wiring can be made constant, and the wiring locations can be limited, so that the security effect can be enhanced.

<Modification 3>
As described above, the medalless gaming machine can be configured to transmit the paid ball management information to the paid ball management device. In addition, in the payout management device, it is possible to appropriately manage the payout performance of each medalless game machine based on the received payout management information. Therefore, on the premise that ball output performance can be appropriately managed in this manner, the above-described limiter may not be provided. That is, it may not have the function of forcibly ending the advantageous section based on the establishment of a certain regulation condition.

Alternatively, the medal number control board may be provided with a function to appropriately manage the ball payout performance, and on the premise that the ball payout performance can be appropriately managed in this manner, the above limiter may not be provided. . That is, it may not have the function of forcibly ending the advantageous section based on the establishment of a certain regulation condition.

For example, the medal count control board is configured to include a ball-out monitoring RWM (which may be the medal count control RWM described above, or may be another RWM). The ball-out monitoring RWM is initialized, for example, when the setting is changed, but is not initialized at the end of the advantageous section to monitor the ball-out. Then, when the monitored ball output exceeds a certain threshold, for example, the advantage section itself is not forcibly terminated, but the navigation occurrence probability is reduced, the AT state is extended probability is reduced, Alternatively, it is assumed that the AT state itself can be terminated to reduce the ball output performance. Even in this way, it is possible to appropriately manage the ball output performance. In this case, it may be possible to transmit such a control result to the paid ball management device as the paid ball management information. That is, both the medal number control board and the ball management device may be configured to manage the ball output performance of each medalless game machine.

(Configuration example of the main control board of a pachislot machine)
Next, a configuration example of the main control board 71 of the pachi-slot machine 1 will be described with reference to FIG. FIG. 35 is a diagram showing an example of the configuration of the main control board 71. As shown in FIG. In the following, a configuration example for reusing the main control board 71 will be mainly described.

As described above, in the pachi-slot machine 1, there are various restrictions on the specifications of the main control board 71, one of which is that the manufacturer's name and board control number must be printed on the main control board 71. It's becoming The manufacturer name is the name of the gaming machine manufacturer that manufactures the pachi-slot machine 1, and the control number is a number for identifying the model of the main control board 71. FIG.

<Configuration example 1>
Configuration example 1 shown in FIG. 35 indicates that the manufacturer's name and the board management number are printed in characters on the main control board 71 as in the conventional art. Here, in configuration example 1 shown in FIG. 35, first, it is assumed that BB Co., Ltd. manufactures the pachi-slot machine 1 (hereinafter referred to as "model A") on which the main control board 71 is mounted. At this time, only the name of the manufacturer "BB Co., Ltd." and the board control number "BB-00-11-22" are printed at the beginning. After that, when model A is removed from the amusement arcade, for example, when AA Co., Ltd. reuses the main control board 71 to manufacture a different pachislot machine 1 (hereinafter referred to as "model B"), the company AA deletes the printed manufacturer name and board control number in the lower row by laser engraving, and inserts the manufacturing number and board control number (for example, the upper manufacturer in the configuration example 1 shown in FIG. 35) in a different space. The name “AA Co., Ltd.” and board control number “AA-00-11-22”) must be newly printed.

After that, model B was withdrawn from the amusement arcade, and, for example, BB Co., Ltd. attempted to reuse the main control board 71 to manufacture a different pachislot machine 1 (hereinafter referred to as "model C"). In this case, BB Co., Ltd. has to delete the printed manufacturer name and board control number by laser engraving, and newly print the manufacturing number and board control number related to the company in a different space. However, in the configuration example 1 shown in FIG. 35, since there is no more empty space, the main control board 71 can be reused due to the restrictions described above, although the hardware can still be sufficiently reused. There was a problem that it may not be possible.

This is the same even when a plurality of manufacturer names and board control numbers are printed from the beginning. For example, even if the serial number and board control number for both AA Co., Ltd. and BB Co., Ltd. are printed in advance, the serial number and board control number for AA Co., Ltd. will be laser-engraved when model A is manufactured. This is because it will be deleted. Therefore, although there is a possibility that BB Co., Ltd. can reuse it, AA Co., Ltd. cannot reuse it. On the other hand, in Configuration Examples 2 and 3 described below, it can be expected that the problems described above can be resolved. That is, the reusability of a board used for game control, such as the main control board 71, can be enhanced.

<Configuration example 2>
Configuration example 2 shown in FIG. 35 indicates that a code including the manufacturer's name and board control number is printed. In configuration example 2 shown in FIG. 35, a QR code (registered trademark), which is a two-dimensional code, is used as an example of a code containing a manufacturer name and a board management number. code can be used. That is, the code may be of any kind as long as it includes information that enables the confirmer to uniquely identify the manufacturer name and board control number by some means (e.g., mobile terminal, etc.). good too.

In configuration example 2 shown in FIG. 35, first, assuming that model A is manufactured by BB Corporation, the first code from the right is printed. The first code from the right contains information that can identify the manufacturing number and board control number of BB Corporation. After that, when model A is withdrawn from the amusement arcade and, for example, AA Co., Ltd. intends to manufacture model B, the second code from the right is printed and the first code from the right is deleted by laser engraving. The second code from the right contains information that can identify the serial number and board control number of AA Co., Ltd.

After that, when the model B is withdrawn from the amusement arcade and, for example, BB Co., Ltd. tries to manufacture the model C, the third code from the right is printed and the second code from the right is deleted by laser engraving. The third code from the right contains information that can identify the manufacturing number and board control number of BB Corporation. After that, even when model C was withdrawn from the amusement arcade and, for example, AA Co., Ltd. reused the main control board 71 to manufacture a different pachislot machine 1, AA Co., Ltd. was the third from the right. The code of is deleted by laser engraving, the fourth code from the right is printed, and the fourth code from the right contains information that can identify the manufacturing number and board control number related to AA Co., Ltd. If so, it becomes possible to reuse the main control board 71 in a new pachi-slot machine 1 .

That is, in the configuration example 2 shown in FIG. 35, by printing the code including the manufacturer name and the board control number, the manufacturer name and the board control number are printed (printed) per one on the surface of the main control board 71. ) Since the space can be saved, it is possible to improve the reusability as compared with the configuration example 1 shown in FIG.

<Configuration example 3>
Configuration example 3 shown in FIG. 35 indicates that a code including a manufacturer name and a board control number is printed in the same manner as in configuration example 2 described above. Note that, in configuration example 3 shown in FIG. 35, a plurality of (for example, four) codes are printed from the beginning. For example, it is assumed that two each of AA Co., Ltd. and BB Co., Ltd. are printed. In addition, on the surface of the main control board 71 (or on the corresponding main control board case), the code is read by crimping a portion corresponding to each code with, for example, a belt-like member. It makes it possible to fix an impossible state. Further, for example, by cutting the belt-like member or the like, it is possible to release the fixation and make the code readable.

In configuration example 3 shown in FIG. 35, first, assuming that model A is manufactured by BB Co., Ltd., only the first code from the right is readable, and the second to fourth codes from the right are readable. is rendered unreadable. The first code from the right contains information that can identify the manufacturing number and board control number of BB Corporation. After that, when model A was withdrawn from the amusement arcade, for example, when AA Co., Ltd. tried to manufacture model B, only the second code from the right was made readable, and the first, third, and fourth codes from the right were made readable. The second code is rendered unreadable. The second code from the right contains information that can identify the manufacturing number and board control number of AA Co., Ltd.

After that, when model B was withdrawn from the amusement arcade, for example, when BB Co., Ltd. tried to manufacture model C, only the third code from the right was made readable, and the first, second, and fourth codes from the right were made readable. The second code is rendered unreadable. The third code from the right contains information that can identify the manufacturing number and board control number of BB Corporation. After that, even if model C was withdrawn from the amusement arcade and, for example, AA Co., Ltd. reused the main control board 71 to manufacture a different pachislot machine 1, AA Co., Ltd. would be the fourth from the right. can be read, and the first to third codes from the right cannot be read, the main control board 71 can be reused in a new pachi-slot machine 1.

Further, in the configuration example 3 shown in FIG. 35, at least one code can be read and the other codes cannot be read. can be reused by game machine manufacturers. Also in the configuration example 3 shown in FIG. 35, only caulking holes may be provided, and a code may be printed at a location corresponding to the caulking holes each time the device is reused.

[10. Second gaming machine]
Next, with reference to FIGS. 36 to 120, another specific example of the specifications relating to game performance of the pachi-slot machine 400 will be described as a "second game machine". In the following explanation, the second gaming machine is a pachislot machine dedicated to 3BET. That is, the start lever 7 and the start switch 7S in the second gaming machine can detect the start operation when three medals are bet.

[Structure of pachislot machines]
First, referring to FIG. 36, the structure of the pachi-slot machine 400, which is the second game machine, will be described. 36 is a diagram showing the external structure of the pachi-slot machine 400. As shown in FIG.

[Chassis]
The housing 500 of the pachi-slot machine 400 shown in FIG. and a lower door mechanism DD2 arranged in the front lower part of the. Since the cabinet G and the upper door mechanism UD are the same as those of the pachi-slot machine 1 (see FIG. 1), the description thereof is omitted.

The lower door mechanism DD2 has a main display window 4 provided substantially in the center of its upper portion, and a reel unit RU2 attached to the inside of the cabinet G behind the main display window 4. there is

The reel unit RU2 is mainly composed of four reels 3A (first reel), 3B (second reel), 3C (third reel), and 3D (fourth reel). Each of the reels 3A, 3B, 3C, and 3D includes, for example, a cylindrical reel body and a translucent reel band attached to the peripheral surface of the reel body. , 20) are drawn at predetermined intervals along the rotation direction of the reel. The reels 3A, 3B, 3C, and 3D are arranged in parallel (in a row) so that they can rotate vertically at a constant speed. The main display window 4 is configured as, for example, a transparent panel made of resin, and allows at least a portion (for example, three) of the symbols on the peripheral surfaces of the reels 3A, 3B, 3C, and 3D to be visible. Further, inside each of the reels 3A, 3B, 3C, and 3D, a light source (a reel lamp included in lamps and LEDs described later) is provided at a position where the pattern can be visually recognized from at least the main display window 4, and at least each reel When 3A, 3B, 3C, and 3D are rotating, they are illuminated from the inside with a constant brightness to ensure the visibility of the pattern.

Further, the lower door mechanism DD has four stop buttons 8A, 8B, 8C, 8D provided substantially in the center below the base. Each stop button 8A, 8B, 8C, 8D is provided corresponding to each reel 3A, 3B, 3C, 3D, and is an operation unit that receives a game operation (stop operation) by the player for stopping the rotation of each reel. be.

Sub effect display unit 22, effect button 10b, MAX bet button 6a, 1 bet button 6b, checkout button 9, effect button 10a, medal slot 5, information display device 14, start lever 7, locking mechanism 15, waist panel 13, the medal receiving tray 12, the medal payout port 11, and the sound transmission holes 24a and 24b are the same as those of the above-described pachislot machine 1 (see FIG. 1), so description thereof will be omitted.

In this embodiment, the upper door mechanism UD and the lower door mechanism DD2 are provided in correspondence with the fact that the inside of the cabinet G is partitioned into an upper space and a lower space. As long as it can be opened and closed, it can be configured as a single door mechanism, or it can be configured as three or more door mechanisms. Moreover, it can also be configured as a double door mechanism (for example, an outer door and an inner door) in the front-rear direction. Further, the upper door mechanism UD and the lower door mechanism DD2 can be simply referred to as "doors" or "doors", and since they function as members capable of opening and closing the opening in the cabinet G, they can be called "opening/closing members" or "doors." It can also be called a "member", or a "door member" or the like.

[Variation display part]
Each of the reels 3A, 3B, 3C, and 3D rotates by driving and controlling stepping motors 51A, 51B, 51C, and 51D, which will be described later, when the start lever 7 is operated (when the player performs a start operation). to start. As a result, the pattern displayed on the main display window 4 is displayed in a variable manner. Further, when each stop button 8A, 8B, 8C, 8D is operated (when the player performs a stop operation), the reels 3A, 3B, 3C, 3D are driven by stepping motors 51A, 51B, 51C, which will be described later. 51D is driven and controlled to stop each rotation. As a result, the symbols displayed in the main display window 4 are stopped and displayed.

That is, each of the reels 3A, 3B, 3C, 3D and the main display window 4 has a variable display unit (means) that can variably display (and stop display) a plurality of symbols in a plurality of rows, or a variable display (and A plurality of variable display units (means) capable of stop display are configured. The variable display section (means) can also be referred to as a "symbol display section (means)" or a "variable display section (means)". The pattern can also be referred to as "picture" or "pattern", or it can be referred to as "identification information" or the like in that sense, as long as it is information that can be visually identified by the player.

Further, the main display window 4 is constructed so that when the reels 3A, 3B, 3C, and 3D stop rotating, three symbols arranged in succession are displayed within the frame. there is That is, the main display window 4 displays one pattern (three in total) in each of the upper, middle, and lower regions of each column (the frame of the main display window 4 displays 3 rows×4 columns). The pattern is displayed in the form of ). Note that the main display window 4 is sometimes referred to as a "design display area", a "window", or the like.

A valid line is defined in the main display window 4 . The effective line is a line for determining whether or not a prescribed combination of symbols is displayed when symbols of all rows are stopped and displayed in response to a player's stop operation. In that sense, the activated line can also be referred to as a "win line" or a "decision line". Also, the effective line is configured as a line connecting any of the regions of each column. That is, when the main display window 4 is configured to display patterns in the form of 3 rows×4 columns, it is possible to define a maximum of 81 effective lines. However, in practice, one or more of the lines can be defined as valid lines, and the other lines can be defined as invalid lines that are not valid lines. In the second gaming machine, the activated line is a line (middle-middle -middle-low) only.

In addition, in order for the activated line to be activated, it is necessary to bet the required amount of medals for the current game (the number of medals that can be used to start the game) prior to the player's start operation. The number of activated lines to be converted may be the same regardless of the number of bets, or may vary according to the number of bets.

In the present embodiment, the variable display section has four reels 3A, 3B, 3C, and 3D, and a main display window 4 capable of displaying three symbols in each column. Although the symbols are displayed in the manner of ×4 rows, the manner of displaying the symbols in the variable display section is not limited to this. For example, the number of reels is 1, 2, 3, or 5 or more, and the number of symbols displayed in each row is 1, 2, or 4 or more. can also display symbols in different ways. In this case, the number of valid lines that can be defined also increases or decreases as appropriate.

Further, in the present embodiment, the variable display section variably displays the symbols by rotating the reels 3A, 3B, 3C, and 3D, but the configuration of the variable display section is not limited to this. For example, a configuration using an image display device similar to the main display device 210 and the sub display device 220 may be used, or a configuration using other display devices (eg, organic EL, 7-segment LED, etc.) may be used. Also, for example, a configuration using other physical devices (for example, a belt or the like) may be used. Also, the arrangement, size, etc. of the variable display section can be changed as appropriate.

Further, in the present embodiment, the variable display section functions as a main side display section that is directly related to the game and is controlled by the main control circuit 100, which will be described later. A variable display section may be provided as a sub-side display section related to an effect not directly related to the game, which is controlled by the game. Note that the sub-side display section can be configured using the main display device 210 and the sub-display device 220, for example. That is, a variable display unit that variably displays symbols in accordance with a player's start operation (or other start conditions are met), and stops and displays symbols in response to a player's stop operation (or other stop conditions are met). As such, not only the main side display section but also the sub side display section may be provided. In this case, in order to allow the player to identify whether or not the variable display section is directly related to the game, characters such as "pachislot" or "main reel" are displayed near the main side display section. It is sufficient that an identification mark indicating is attached so that it is possible to identify that the variable display portion is the main side display portion. Note that such an identification display may be displayed on the main display device 210 or the sub display device 220 .

[Stop button]
As described above, the pachi-slot machine 400 is provided corresponding to each of the reels 3A, 3B, 3C and 3D, and each stop button 8A, 8B, 8C and 8D receives a player's stop operation for stopping the rotation of each reel. Prepare. Moreover, such a start operation is detected by a stop switch 8S, which will be described later. Therefore, each of the stop buttons 8A, 8B, 8C, 8D and the stop switch 8S constitute a stop operation detector (means) capable of detecting the player's stop operation. It should be noted that the stop button only needs to be able to detect the player's stop operation, and its shape, arrangement, size, and the like can be changed as appropriate.

[Electrical Configuration of Pachislot Machine]
Next, the electrical configuration of the pachi-slot machine 400 will be described with reference to FIG. 37 is a block diagram showing the electrical configuration of the pachi-slot machine 400. As shown in FIG.

As described above, the pachi-slot machine 400 has the main control board 71, the sub-control board 72, the main relay board 73, and the sub-relay board 74. The main control board 71, sub-control board 72, main relay board 73, and sub-relay board 74 are the same as those of the above-described pachi-slot machine 1 (see FIG. 1), so description thereof will be omitted.

The main control board 71 includes stepping motors 51A, 51B, 51C, and 51D, a setting key switch 52, a reset switch 53, a role ratio monitor device 54, an external collective terminal plate 55, a hopper device 32, and an auxiliary medal storage switch 33S. , the power supply 34 is electrically connected. In addition, the main control board 71 is electrically connected to the door opening/closing monitoring switch 56, the medal sensor 31S, the bet switch 6S, the start switch 7S, the stop switch 8S, the checkout switch 9S, and the information display device 14 via the main relay board 73. It is connected to the. If the tester first interface board 301 and the tester second interface board 302 are mounted, they are electrically connected to the main control board 71 via the main relay board 73, for example.

Stepping motors 51A, 51B, 51C, and 51D are connected to the reels 3A, 3B, 3C, and 3D through gears each having a predetermined reduction ratio, and are driven to rotate the reels 3A, 3B, 3C, and 3D. and stop. Since each reel 3A, 3B, 3C, 3D rotates at a constant angle each time one pulse is output to each stepping motor 51A, 51B, 51C, 51D, the main CPU 101 The number of times pulses are output to the stepping motors 51A, 51B, 51C and 51D is counted, and the symbol positions of the respective reels 3A, 3B, 3C and 3D are managed based on the counting results. Each of the reels 3A, 3B, 3C, and 3D has a reel index (not shown) that determines the initial position for such management, and an index sensor (not shown) for detecting the position of the reel index. be provided.

[Second game machine]
Next, with reference to FIGS. 38 to 120, a specific example of the specifications relating to game characteristics of the pachi-slot machine 400 will be described as a "second game machine". It should be noted that various specifications, functions, etc., described as the second gaming machine in this embodiment can be partially or wholly applied to other gaming machines described in this embodiment, and Various specifications, functions, and the like, which are described as other gaming machines in this embodiment, can be partially or wholly applied to the first gaming machine as described in this embodiment. In other words, an appropriate combination of these can be used as the invention according to the present embodiment.

In the second gaming machine, a non-bonus state and a bonus state are provided as game states. Further, the non-bonus state is a state between RB flags in which "RB" (regular bonus) described later is carried over, and a state between BB flags in which "BB" (big bonus) described later is carried over. It is configured including a non-flag interval where a winning combination is not won (not carried over). It should be noted that the non-flag period is a normal state. Also, the bonus state is the RB operating state that shifts in accordance with the display of the symbol combination related to "RB", and the BB operating state that shifts in response to the display of the symbol combination related to "BB". and

Also, in the second gaming machine, it is possible to play a game with three medals bet (three bet state). The "bet" means that the player inserts three medals into the medal insertion slot 5 for use in the game, and the player operates the MAX bet button 6a or the 1 bet button 6b to It includes both the betting of three medals and the automatic betting of three medals by winning a replay combination.

[RT state transition]
Subsequently, transition of the RT state in the second gaming machine will be described with reference to FIG. FIG. 38 is a diagram for explaining the RT state transition in the second gaming machine.

As shown in FIG. 38, in the second gaming machine, as the RT state, four types of states, RT0 to RT3, are provided in which the types of internal winning combinations for replay and their winning probabilities are different from each other. The RT state is set to the RT0 state when initialization is performed by a setting change operation, when other initialization conditions are satisfied, or when the device is shipped from the factory.

The second gaming machine is provided with a first class special role (RB) and a continuous operating device (BB) for the first class special role as a bonus combination. The RB operating state is a game state that ends when a predetermined number of winnings (for example, the upper limit is 8 times) or a predetermined number of games (for example, the upper limit is 12 times) is played. configured as The BB operating state is configured as a game state in which the game ends when the payout of medals exceeds an arbitrary predetermined number (for example, the upper limit is 55). Also, in the BB operating state, the RB is configured to automatically operate, and is controlled so that the RB is always operating while the BB is operating. In addition, although BB and RB are provided in the second game machine, only RB may be provided.

In the RT0 state, when "RB" is won and the state between RB flags is entered, the RT state shifts from the RT0 state to the RT2 state. In the RT2 state and in the advantageous section described later, the main display device 210 and the instruction monitor notify a stop operation mode (for example, push order navigation, etc.) for avoiding the display of the combination of symbols related to "RB". conduct. Also, in the RT0 state, when "BB" is won and the state between BB flags is entered, the state is shifted from the RT0 state to the RT2 state. In the state between BB flags, a lottery relating to payout balls (same as "payout balls" described in the first gaming machine) is not performed. In the normal state, if "BB" is won, the main display device 210 displays "preparing" or "waiting" until the operation and termination of the BB and transition to the state between RB flags, and when the state shifts to the state between RB flags. , terminate the display of preparation or waiting.

When the symbol combination related to "RB" is displayed and the RB operation state is entered, the RT state is changed from the RT2 state to the RT3 state. Further, when the symbol combination related to "BB" is displayed and the BB operating state is entered, the RT state is changed from the RT2 state to the RT3 state.

When the RB active state or BB active state ends, it transitions to the general state, and the RT state transitions from the RT2 state to the RT1 state. Thereafter, the RT0 state is not entered until initialization is performed by a setting change operation or other initialization conditions are satisfied. That is, in the RT1 state, when "RB" is won and the state between RB flags is entered, the RT state shifts from the RT1 state to the RT2 state. Also, in the RT1 state, when "BB" is won and the state between BB flags is entered, the state is shifted from the RT1 state to the RT2 state.

It should be noted that the initialization by the setting change operation determines whether to clear all the data in the designated storage area or to clear a part of the game state according to the game state and the ON/OFF state of the reset switch 53. You may make it Further, when the power is turned on while the setting key-shaped switch 52 and the reset switch 53 are in the ON state, all data may be cleared regardless of the game state. Further, when the setting key-type switch 52 is in the ON state and the reset switch 53 is in the OFF state when the power is turned on, the RB carryover flag may not be initialized if it is between RB flags. Also, if the state is between BB flags, all data including the BB carryover flag may be cleared.

[Pattern Arrangement Configuration of Second Gaming Machine]
Next, referring to FIG. 39, the symbol arrangement configuration of the second gaming machine will be described. FIG. 39 is a diagram showing an example of the symbol arrangement table of the second gaming machine. As shown in FIG. 40, in the second gaming machine, "Red 7", "BAR", "Replay", "Bell", "Scroll", "Cherry", "Blank 1", "Blank 2", " 10 kinds of patterns of "upper symbol" and "lower symbol" are arranged at the positions shown in FIG. 39 on each of the reels 3A, 3B, 3C and 3D. Further, as shown in the symbol code table, symbol codes 1 to 10 are assigned to each symbol.

[Second Internal Winning Combination Configuration of Gaming Machine]
Next, the internal winning combination structure of the second gaming machine will be described with reference to FIGS. 40 to 49. FIG. 40 and 41 are diagrams showing an example of the internal lottery table of the second gaming machine. 42 and 43 are diagrams showing an example of the symbol combination table of the second gaming machine. 44 to 49 are diagrams showing an example of the correspondence relationship between the internal winning combination, the stop operation mode, the display combination, etc. of the second gaming machine. That is, hereinafter, which symbol is selected according to the type of internal winning combination that is drawn by lottery in the second gaming machine, and the stop operation mode (that is, the batting order, stop operation timing, etc.) when each internal winning combination is won. (which can also be rephrased as a display combination, a winning combination, a stop display mode, a display result, etc.) will be displayed.

First, in the second gaming machine, in the internal lottery process, each internal winning combination shown in FIGS. 40 and 41 is won with the probability shown in FIGS. 40 and 41 (lottery value/probability denominator: 65536). Combinations of symbols permitted to be displayed when each internal winning combination is won are as shown in "corresponding symbol combinations" in FIGS. In FIGS. 42 and 43, "RB" and "BB" shown in "contents" indicate a combination of symbols relating to bonus hands, "RP" indicates a combination of symbols relating to replay hands, and "NM". indicates a combination of symbols relating to a small winning combination.

"F_Normal Rep 1" is configured to be determined as an internal winning combination in non-bonus states (RT0, RT1, inside RB (state between RB flags), inside BB (state between BB flags)). As shown in FIGS. 44, 46, and 48, when "F_Normal Lip 1" is determined as the internal winning combination, if the first stop operation is the first reel 3A (reel A), "RP01" ( CL description) or "RP04" (XU description) is displayed, and replay is granted. Also, if the first stop operation is the second reel 3B (reel B), the third reel 3C (reel C), or the fourth reel 3D (reel D), "RP02" (TL reel), "RP03" ( TL description), [RP05] (XD description), or "RP06" (XD description) is displayed, and replay is granted.

"RP01" can be called a "middle row (CL)" because it displays the "replay" symbols in a straight line in the middle of the first reel 3A to the third reel 3C. In addition, "RP04" displays the "replay" symbol on the first reel 3A to the third reel 3C upward to the right. ``RP02'' and ``RP03'' display the ``Replay'' symbols in a straight line on the first reel 3A to the third reel 3C. can. [RP05] and "RP06" display the "Replay" symbol on the 1st reel 3A to the 3rd reel 3C downward to the right, so this is collectively called "Rip right down (XD Rip)". can be done.

"F_Normal Lip 2" is configured to be determinable as an internal winning combination in the non-bonus state. As shown in FIGS. 44, 46 and 48, when "F_Normal Rep 2" is determined as the internal winning combination, if the first stop operation is reel A, "RP01" (CL Rep) is displayed. , Replay is awarded. Also, if the first stop operation is reel B, reel C, or reel D, "RP02" (TL descriptor), "RP03" (TL descriptor), [RP05] (XD descriptor), "RP06" (XD descriptor) ) is displayed, and replay is granted.

"F_Normal Lip 3" is configured to be determinable as an internal winning combination in the non-bonus state. As shown in FIGS. 44, 46 and 48, when "F_Normal Rep 3" is determined as the internal winning combination, if the first stop operation is reel A, "RP01" (CL Rep) is displayed. , Replay is granted. Further, if the first stop operation is reel B, reel C, or reel D, either "RP02" (TL description) or "RP03" (TL description) is displayed, and a replay is awarded.

"One in F_RB" is configured to be determined as an internal winning combination in the bonus state (RB operating state and BB operating state). In the bonus state, if "one in F_RB" is determined as an internal winning combination, one of "NM30" to "NM80" is displayed regardless of the stop operation mode, and one medal is paid out. be.

"Bell in F_RB" is configured to be determinable as an internal winning combination in the bonus state. In the bonus state, if "Bell in F_RB" is determined as an internal winning combination, one of "NM01" to "NM29" is displayed regardless of the stop operation mode, and 15 medals are paid out. .

"F_Common Bell" is configured to be determined as an internal winning combination in a non-bonus state. As shown in FIGS. 44, 46, and 48, when "F_common bell" is determined as an internal winning combination, one of "NM13" to "NM15" is displayed regardless of the stop operation mode, and 15 cards are displayed. medals are paid out.

"F_batting order bell 01" to "F_batting order bell 24" are configured to be determined as internal winning combinations in the non-bonus state. As shown in FIGS. 44, 46, and 48, "F_batting order bell 01" to "F_batting order bell 24" are 24 options (24 options) composed of selections of the first, second, and third stop operations. any one of the batting order is the correct hitting order), and if it is determined as an internal winning combination, if the stop operation is performed in the corresponding correct hitting order. , one of “NM01” to “NM12” is displayed, and 15 medals are paid out. On the other hand, when the stop operation is not performed in the corresponding correct order, one of "NM30" to "NM58" is displayed and one medal is paid out. For example, when "F_batting order bell 01" is determined as an internal winning combination, if the first stop operation is reel A, the second stop operation is reel B, and the third stop operation is reel C, then the correct pressing order is determined. "NM01" (C_12 bell) is displayed, and 15 medals are paid out. On the other hand, if the first stop operation is not reel A, the second stop operation is reel B, and the third stop operation is not reel C, either "NM30" (S_batting order error 01) or "NM34" (S_batting order error 03) is displayed, and one medal is paid out.

"F_Middle Che 1" is configured to be determinable as an internal winning combination in the non-bonus state. As shown in FIGS. 44, 46, and 48, when "F_middle check 1" is determined as an internal winning combination, if the first stop operation is reel A or reel D, "NM17" (S_middle check) 1), either "NM18" (S_middle tier 2) is displayed, and 15 medals are paid out. If the first stop operation is reel B, "NM04" (C_21 bell) is displayed and 15 medals are paid out. Also, if the first stop operation is reel C, "NM09" (C_34 bell) is displayed and 15 medals are paid out.

"F_Middle Che 2" is configured to be determinable as an internal winning combination in the non-bonus state. As shown in FIGS. 44, 46, and 48, when "F_middle Che 2" is determined as an internal winning combination, if the first stop operation is reel A or reel D, "NM16" (S_determined combination) ), “NM17” (S_middle check 1), or “NM18” (S_middle check 2) is displayed, and 15 medals are paid out. If the first stop operation is reel B, "NM04" (C_21 bell) is displayed and 15 medals are paid out. Also, if the first stop operation is reel C, "NM09" (C_34 bell) is displayed and 15 medals are paid out.

"F_Weak Che" is configured to be determined as an internal winning combination during the RB, during the BB, or in the bonus state. When "F_Weak Che" is determined as an internal winning combination, regardless of the stop operation mode, "NM19" (C_Weak Che A), "NM20" (S_Weak Che B), "NM22" (S_Strong Che2) , "NM47" (S_batting order error 11), or "NM55" (S_batting order error 19A). As shown in FIGS. 45 and 47, if the first stop operation is reel A, reel B, or reel C while in the bonus state or inside RB, there is a probability of 19/20 that "NM20" (S_ Weak Choi B), ``NM22'' (S_Heavy Choi 2), ``NM47'' (S_Batting order error 11), or ``NM55'' (S_Batting order error 19A) is displayed and one medal is paid out, With a probability of 1/20, "NM19" (C_weak Che A) is displayed and two medals are paid out. If the first stop operation is Reel D, the probability is 18/20: "NM20" (S_Weak Che B), "NM22" (S_Heavy Che2), "NM47" (S_Battering order error 11), "NM55" Either (S_bading order error 19A) is displayed and one medal is paid out, and with a probability of 2/20, "NM19" (C_Weak Che A) is displayed and two medals are paid out. In the present embodiment, the pressing order is the fourth reel D, the third reel C, the second reel B, and the first reel A, and the stop operation on the fourth reel D is pressed so that a cherry is displayed in the lower row. If the timing is right, "NM19" (C_Weak Che A) is displayed and two medals are paid out. As shown in FIG. 49, when inside the BB, regardless of the stop operation mode, there is a probability of 1/2 that "NM20" (S_Weak Che B), "NM22" (S_Strong Che2), "NM47". Either (S_batting order error 11) or "NM55" (S_batting order error 19A) is displayed, one medal is paid out, and "NM19" (C_weak Che A) is displayed with a probability of 1/2. 2 medals will be paid out.

"F_Strong Che 1" is configured to be determined as an internal winning combination during the inside of the RB, inside the BB, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_Strong Che 1" is determined as an internal winning combination, if the first stop operation is reel A or reel D, "NM21" (S_Strong Che 1), one of "NM22" (S_High Challenge 2) and "NM23" (S_High Challenge 3) is displayed, and one medal is paid out. If the first stop operation is Reel B or Reel C, one of "NM20" (S_Weak Che B), "NM30" (S_Batting order error 01), and "NM47" (S_Batting order error 11) is displayed, One medal is paid out.

"F_Strong Chase 2" is configured to be determined as an internal winning combination during the RB, during the BB, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_Strong Chase 2" is determined as an internal winning combination, if the first stop operation is Reel A or Reel D, "NM22" (S_Strong Chase 2) is displayed and one medal is paid out. If the first stop operation is Reel B or Reel C, one of "NM20" (S_Weak Che B), "NM30" (S_Batting order error 01), and "NM47" (S_Batting order error 11) is displayed, One medal is paid out.

"F_weak watermelon 1" is configured to be determined as an internal winning combination during the RB, during the BB, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_weak watermelon 1" is determined as an internal winning combination, if the first stop operation is reel A or reel D, "NM26" (C_BL watermelon 1 ), or “NM28” (C_CL Watermelon 1) is displayed, and one medal is paid out. If the first stop operation is reel B or reel C, "NM30" (S_batting order error 01) is displayed and one medal is paid out.

"F_weak watermelon 2" is configured to be determined as an internal winning combination in the RB, BB, or bonus state. As shown in FIGS. 45, 47 and 49, when "F_weak watermelon 2" is determined as an internal winning combination, if the first stop operation is reel A or reel D, "NM24" (C_XU watermelon 1 ), or “NM28” (C_CL Watermelon 1) is displayed, and one medal is paid out. If the first stop operation is reel B or reel C, "NM30" (S_batting order error 01) is displayed and one medal is paid out.

"F_strong watermelon 1" is configured to be determined as an internal winning combination during the inside of the RB, inside the BB, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_strong watermelon 1" is determined as an internal winning combination, if the first stop operation is reel A or reel D, "NM26" (C_BL watermelon 1 ), “NM27” (C_BL watermelon 2), “NM28” (C_CL watermelon 1), or “NM29” (C_CL watermelon 2) is displayed, and one medal is paid out. If the first stop operation is reel B or reel C, "NM30" (S_batting order error 01) is displayed and one medal is paid out.

"F_strong watermelon 2" is configured to be determined as an internal winning combination during the inside of the RB, inside the BB, or in the bonus state. As shown in FIGS. 45, 47 and 49, when "F_Strong Watermelon 2" is determined as an internal winning combination, if the first stop operation is Reel A or Reel D, "NM24" (C_XU Watermelon 1 ), “NM25” (C_XU watermelon 2), “NM28” (C_CL watermelon 1), or “NM29” (C_CL watermelon 2) is displayed, and one medal is paid out. If the first stop operation is reel B or reel C, "NM30" (S_batting order error 01) is displayed and one medal is paid out.

"F_RB 1 card 01" to "F_RB 1 card 12" are configured to be determined as internal winning combinations inside the RB or inside the BB. As shown in FIG. 47, when the RB is inside, ``F_RB 1 sheet 01'' to ``F_RB 1 sheet 12'' are four choices (any one of the four batting orders) consisting of the selection of the first stop operation. If the stop operation is performed in the corresponding correct order, then "NM30" to "NM33", "NM56" to " NM61" is displayed and one medal is paid out. On the other hand, when the stop operation is not performed in the corresponding correct pressing order (the stop operation is performed in the incorrect pressing order), "RB" (C_RB) may be displayed. For example, when "F_RB 1 card 01" is determined as an internal winning combination, if the first stop operation is reel A, the correct pressing order is "NM30" (S_batting order error 01), "NM56" (C_batting order error). 19B) or "NM59" (C_batting order error 20B) is displayed, and one medal is paid out. On the other hand, if the first stop operation is not reel A, the pressing order is incorrect, and the probability of 1/3 is "NM30" (S_missing batting order 01), "NM56" (C_missing batting order 19B), "NM59" ( C_batting order error 20B) is displayed, and one medal is paid out. If none of "NM30", "NM56", and "NM59" could be displayed, "RB" (C_RB) is displayed.

As shown in FIG. 49, when "F_RB 1 card 01" to "F_RB 1 card 12" are determined as internal winning combinations when the BB is inside, "NM30" to "NM33" regardless of the stop operation mode. , "NM56" to "NM61" are displayed, and one medal is paid out. For example, if "F_RB 1 card 01" is determined as an internal winning combination, any of "NM30" (S_batting order error 01), "NM56" (C_batting order error 19B), or "NM59" (C_batting order error 20B) is displayed and one medal is paid out.

"F_exclusive 1 card 1" is configured to be determined as an internal winning combination inside the RB or inside the BB. As shown in FIGS. 47 and 49, when "F_exclusive 1 card 1" is determined as an internal winning combination, regardless of the stop operation mode, there is a probability of 1/3 that "NM31" (C_batting order error 02A), One of "NM37" (C_batting order error 06A) is displayed and one medal is paid out. Also, there is a probability of 2/3 that none of the display combinations will be displayed.

"F_exclusive 1 card 2" is configured to be determined as an internal winning combination inside the RB or inside the BB. As shown in FIGS. 47 and 49, when "F_exclusive 1 card 2" is determined as an internal winning combination, regardless of the stop operation mode, there is a probability of 1/3 that "NM32" (C_bad order error 02B), One of "NM38" (C_batting order error 06B) is displayed and one medal is paid out. Also, there is a probability of 2/3 that none of the display combinations will be displayed.

"F_exclusive 1 card 3" is configured to be determined as an internal winning combination inside the RB or inside the BB. As shown in FIGS. 47 and 49, when "F_Exclusive 1 card 3" is determined as an internal winning combination, regardless of the stop operation mode, there is a probability of 1/3 that "NM33" (C_Battering order error 02C), One of "NM39" (C_batting order error 06C) is displayed and one medal is paid out. Also, there is a probability of 2/3 that none of the display combinations will be displayed.

"F_common 1 card A" is constructed so as to be determined as an internal winning combination during the inside of the RB, inside the BB, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_common 1 card A" is determined as an internal winning combination, regardless of the stop operation mode, "NM31" (C_wrong batting order 02A), "NM32" (C_batting order error 02B), "NM33" (C_batting order error 02C), "NM37" (C_batting order error 06A), "NM38" (C_batting order error 06B), or "NM39" (C_batting order error 06C) It is displayed and one medal is paid out.

"F_Common 1 card B" is configured to be determined as an internal winning combination during the RB, during the BB, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_common 1 card B" is determined as an internal winning combination, regardless of the stop operation mode, "NM34" (S_batting order error 03), "NM40" Any one of (C_batting order error 07A), "NM41" (C_batting order error 07B), and "NM42" (C_batting order error 07C) is displayed and one medal is paid out.

"F_batting order BB01" to "F_batting order BB10" are configured to be determined as internal winning combinations in the RB, BB or bonus state. As shown in FIGS. 45 and 47, when "F_batting order BB01" to "F_batting order BB10" are determined as internal winning combinations during the RB or in the bonus state, regardless of the stop operation mode, " NM40”, “NM41”, “NM44”, “NM45”, “NM62” to “NM80” are displayed, and one medal is paid out. For example, when "F_batting order BB01" is determined as an internal winning combination, "NM44" (C_batting order error 08B), "NM45" (S_batting order error 09), "NM62" (C_BBFLW), "NM63" (C_BBK1A) ), “NM64” (C_BBK1B), “NM65” (C_BBK1C), “NM76” (C_BBK common 2), and one medal is paid out.

As shown in FIG. 49, when "F_batting order BB01" to "F_batting order BB09" are determined as internal winning combinations in the middle of the BB, it consists of selection of first and second stop operations. The pressing order is BB with 12 alternatives (any one of the 12 batting orders is the correct pressing order). When the stop operation is performed in the corresponding correct order, "BB" (C_BB) is displayed with a probability of 3/4, and "NM41", "NM44", "NM45", and so on with a probability of 1/4. Any one of "NM63" to "NM72" and "MN75" to "MN80" is displayed. On the other hand, when the stop operation is not performed in the corresponding correct order, there is a probability of 1/4 that "NM41", "NM44", "NM45", "NM63"-"NM72", "MN75"-" MN80” is displayed, and there is a probability of 3/4 that neither display combination is displayed. For example, when "F_batting order BB01" is determined as an internal winning combination, if the first stop operation is reel A and the second stop operation is reel B, then the correct pressing order is "BB" with a probability of 3/4. (C_BB) is displayed, and one of "NM44", "NM45", "NM62" to "NM65", and "MN76" is displayed with a probability of 1/4. On the other hand, if the first stop operation is not reel A and the second stop operation is not reel B, one of "NM44", "NM45", "NM62" to "NM65", and "MN76" is selected with a probability of 1/4. It will appear and there is a 3/4 probability that neither of the presenting hands will appear.

As shown in FIG. 49, when "F_batting order BB10" is determined as an internal winning combination while inside the BB, there are 4 choices (out of the 4 batting orders) consisting of selection of the first stop operation. Any one of the batting order is the correct pressing order), and the pressing order is BB. When the stop operation is performed in the corresponding correct order of pressing (the first stop operation is reel D), "BB" (C_BB) is displayed with a probability of 9/16, and "NM40" is displayed with a probability of 7/16. , "NM62", "NM73", or "MN74" is displayed. On the other hand, when the stop operation is performed in a sequence other than the corresponding correct pressing order (the first stop operation is other than reel D), there is a probability of 1/4 that "NM44", "NM45", "NM62" to "NM65". , "MN76" will be displayed, and there is a probability of 3/4 that none of the display combinations will be displayed.

"RB+F_Weak Chase", "RB+F_Strong Chase 1", "RB+F_Strong Chase 2", "RB+F_Weak Watermelon 1", "RB+F_Weak Watermelon 2", "RB+F_Strong Watermelon 1", "RB+F_Strong Watermelon 2", "BB+F_RB1" Sheet 01" to "BB+F_RB1 sheet 12", "RB+F_Exclusive 1 sheet 1", "RB+F_Exclusive 1 sheet 2", "RB+F_Exclusive 1 sheet 3", "RB+F_Common 1 sheet A", "BB+F_Common 1 sheet B", "RB+F_batting order BB01" to "RB+F_batting order BB10" are configured to be determined as internal winning combinations in RT0 state or RT1 state. That is, in the normal state (RT0 state, RT1 state), "RB" is "F_Weak Che", "F_Strong Che1", "F_Strong Che2", "F_Weak Watermelon1", "F_ weak watermelon 2", "F_strong watermelon 1", "F_strong watermelon 2", "F_exclusive 1 sheet 1", "F_exclusive 1 sheet 2", "F_exclusive 1 sheet 3", "F_common 1 sheet A" , "F_batting order BB01" to "F_batting order BB10".

As shown in FIG. 45, "RB+F_Weak Chase", "RB+F_Strong Chase 1", "RB+F_Strong Chase 2", "RB+F_Weak Watermelon 1", "RB+F_Weak Watermelon 2", "RB+F_Strong Watermelon 1", "RB+F_ Strong watermelon 2", "RB + F_ exclusive 1 card 1", "RB + F_ exclusive 1 card 2", "RB + F_ exclusive 1 card 3", "RB + F_ common 1 card A", "RB + F_ batting order BB01" to "RB + F_ batting order BB10" stop The correspondence relationship between the operation mode and the display combination is shown in FIG. F_strong watermelon 1", "F_strong watermelon 2", "F_exclusive 1 sheet 1", "F_exclusive 1 sheet 2", "F_exclusive 1 sheet 3", "F_common 1 sheet A", "F_batting order BB01" ˜“F_batting order BB10” is the same as the corresponding relationship between the stop operation mode and the display combination. That is, in the general state (RT0 state, RT1 state), "RB" is "F_Weak Che", "F_Strong Che1", "F_Strong Che2", "F_Weak Watermelon1", "F_Weak Watermelon2 ", "F_strong watermelon 1", "F_strong watermelon 2", "F_exclusive 1 sheet 1", "F_exclusive 1 sheet 2", "F_exclusive 1 sheet 3", "F_common 1 sheet A", "F_ In a game in which any one of the batting order BB01 to "F_batting order BB10" is won, the combination of symbols related to "RB" is not displayed regardless of the stop operation mode (see FIG. 45).

On the other hand, in a game in which any one of "F_RB 1 card 01" to "F_RB 1 card 12" is won during the RB interior (state between RB flags), a combination of symbols related to "RB" may be displayed (Fig. 47). That is, in a game in which any one of "F_RB 1 card 01" to "F_RB 1 card 12" is won during the inside of the RB (state between RB flags), when the stop operation is performed in the order of pressing the correct answer, the symbols related to "RB" is not displayed, but a combination of symbols that pays out one medal is displayed. When the stop operation is not performed in the order of pressing the correct answer, and when the combination of symbols for paying out one medal is not displayed, the combination of symbols related to "RB" is displayed.

Also, in the case of the normal state (RT0 state, RT1 state), "BB" overlaps with any of "F_RB 1 sheet 01" to "F_RB 1 sheet 12" and "F_Common 1 sheet B". As shown in FIG. 45, the correspondence relationship between the stop operation modes of "BB+F_RB 1 card 01" to "BB+F_RB 1 card 12" and "BB+F_Common 1 card B" and the display combination is as shown in FIG. This is the same as the correspondence relationship between the stop operation mode and the display combination of "F_RB 1 card 12" and "F_Common 1 card B". That is, in the general state (RT0 state, RT1 state), in a game in which "BB" overlaps with any of "F_RB 1 card 01" to "F_RB 1 card 12" and "F_Common 1 card B", the stop operation Regardless of the mode, the combination of symbols related to "BB" is not displayed (see FIG. 45).

On the other hand, in a game in which any one of "F_batting order BB01" to "F_batting order BB10" is won during the BB (state between BB flags), a combination of symbols related to "BB" may be displayed (Fig. 49). That is, in a game in which any one of "F_batting order BB01" to "F_batting order BB10" has been won in the BB, when the stop operation is performed in the correct order, the combination of symbols that pays out one medal is selected. When not displayed, a combination of symbols related to "BB" is displayed. Then, if the stop operation is not performed in the correct order, the symbol combination related to "BB" may not be displayed, and the symbol combination that pays out one medal may be displayed.

[Playability of the second gaming machine]
Next, with reference to FIG. 50, the game flow in the second gaming machine will be described. FIG. 50 is a diagram showing an example of the game state transition flow in the non-advantageous section and the advantageous section in the second gaming machine.

[Transition of game state]
As shown in FIG. 50, in the second gaming machine, the state in which a player plays a game is roughly divided into a non-advantageous interval and an advantageous interval. A zone section is provided. The non-advantageous section is a game state (non-AT state) in which information on a stop operation that is advantageous to the player is not notified, and is a game state that is disadvantageous to the player. The non-advantageous section is controlled as an initial state when the game in the advantageous section is completed, when a setting change operation is performed, when other initialization conditions are satisfied, or when it is shipped from the factory. state.

The normal section is a game state (non-AT state) in which the information of the stop operation that is advantageous for the player is not notified, and is similar to the non-advantageous section in that it is a game state that is disadvantageous to the player. , differs from the non-advantageous section in that the map type is determined. The normal section is a control state as a normal state in which the player plays a normal game, with the degree of expectation for transition (granting) to the pseudo-bonus section being variable depending on the map type or the like. The pseudo-bonus section is a game state (AT state) in which information of a stop operation that is advantageous to the player is notified, and is a game state that is advantageous to the player. That is, the pseudo-bonus section is a control state as an advantageous state in which the player can increase medals.

In addition, the continuous chan zone section is a game state (non-AT state) in which information on the stop operation that is advantageous for the player is not notified, and is a game state that is disadvantageous to the player, similar to the non-advantageous section. As will be described later, this is different from the non-advantageous section in that a map transition is performed. The consecutive-chan zone section is a control state as a normal state in which the player normally plays a game, with the degree of expectation for transition (granting) to the pseudo-bonus section being variable depending on the map type or the like. In addition, in the consecutive chan zone section, it is possible to determine the map type different from the normal section, and the expectation of the pseudo bonus section transition (granting) is higher than in the normal section.

In the non-advantageous section, it is determined whether or not the advantageous section transition condition is satisfied for each game. When the advantageous section transition condition is satisfied, the non-advantageous section is transferred to the advantageous section. In the second gaming machine, the advantageous section transition condition is that a predetermined internal winning combination is determined. Predetermined internal winning combinations other than "Illegal (Only during RB/BB)", "F_Normal Rep 2", "F_Normal Rep 3", "One in F_RB", and "Bell in F_RB" playing a role. It should be noted that the transition from the non-advantageous section to the advantageous section is also possible in the inter-RB flag state, the inter-BB flag state, the RB operating state, and the BB operating state.

In the non-advantageous section, when a predetermined internal winning combination is determined, winning/non-winning of the pseudo bonus is determined. The types of pseudo bonus that can be determined in this case are "REG bonus", "BIG bonus", and "super BIG bonus". Further, when a predetermined internal winning combination is determined in the non-advantageous section and "REG bonus" is determined, the type of pseudo bonus is changed to "BIG bonus". Note that when a predetermined internal winning combination is determined in the non-advantageous section and "BIG bonus" or "super BIG bonus" is determined, the type of pseudo bonus is not changed. However, when a predetermined internal winning combination is determined in a non-advantageous section and a "BIG bonus" is determined, the pseudo bonus type is changed to a "super BIG bonus" or other benefits are given. good too.

In the game following the game that transitioned to the advantageous section (hereinafter referred to as the "next game after transition to the advantageous section"), a table type lottery, which will be described later, is performed, and the table type is determined according to the RT state at that time. be. The determined table type is basically not changed until the pseudo bonus is determined. In addition, in the normal section and the continuous zone section of the advantageous section, the map type is determined according to the table type, and the winning/non-winning of the pseudo-bonus is determined according to the determined map type. When the winning of the pseudo-bonus is determined, the transition to the pseudo-bonus section is determined.

When the RT state in the first G of the advantageous section is the RT0 state, it is easier for the player to determine the table type that is advantageous to the player than in the case of the RT1 to RT3 states. As for the table type that is advantageous for the player, the map type that is advantageous for winning the pseudo bonus is likely to be determined. Therefore, when the RT state in the first G of the advantageous section is the RT0 state, the probability of winning the pseudo bonus is higher than in the cases of the RT1 and RT2 states.

(Normal section)
Except when directly transitioning from a non-advantageous section to a pseudo-bonus section, when transitioning to an advantageous section, it basically starts from the normal section. The normal section has a high probability zone and a BIG probability zone. In the normal section, the map type is determined every predetermined period (approximately 200G). Also, in the normal section, whether the pseudo bonus is won or not is determined according to the map type. The high probability zone is set from 1 to 200G in the normal section. The types of pseudo bonus that can be determined in the high probability zone are "REG bonus", "BIG bonus", and "super BIG bonus". The high probability zone has a higher degree of expectation that a pseudo bonus will be determined than the BIG certainty zone. In the high-probability zone, when the pseudo bonus is determined, the probability of determining the "REG bonus" and the probability of determining the "BIG bonus" are set to be substantially the same. In the gaming machine according to the present invention, the probability of determining the "REG bonus" and the probability of determining the "BIG bonus" may be different when the pseudo bonus is won. For example, if a pseudo-bonus is determined in a high-probability zone for a specific number of consecutive times, and all the pseudo-bonus types are "REG bonuses," the probability of determining a "REG bonus" is higher than that of a "BIG bonus." ” may be determined.

When the pseudo-bonus type is determined in the high-probability zone, the predictive G (game) number is determined, and in the final game of the predictive G-number, the determined (given) pseudo-bonus type is notified. Hereinafter, the number of precursor Gs determined when the pseudo bonus is determined is referred to as the number of precursor Gs, and the game until reaching the number of precursor Gs is referred to as the middle of the precursor. When the "REG bonus" is determined in the high probability zone and the transition to the BIG certainty zone is made in the present omen, the determined "REG bonus" is changed to the "BIG bonus". On the other hand, when the "BIG bonus" or "super BIG bonus" is determined in the high probability zone and the game is shifted to the BIG certainty zone while the game of this sign G number is consumed, the determined pseudo bonus type is not changed.

The BIG definite zone is set from the normal section 201G to the ceiling. The BIG definite zone ceiling is 951G + number of prognostic Gs. That is, the "BIG bonus" or "super BIG bonus" is determined in the 951G of the advantageous section, and the pseudo-bonus is determined (given) in the final game of the sign G number determined at that time, and the pseudo-bonus type is notified. be. Types of pseudo bonuses that can be determined in the BIG probability zone are “BIG bonus” and “super BIG bonus”. That is, if no pseudo-bonus is won by 200 G in the advantageous section, the pseudo-bonus to be won after that will always be a "BIG bonus" or a "super-BIG bonus".

In normal intervals, fake precursors can be determined. When the fake sign is determined, the number of fake sign G is determined, and it is informed that the pseudo bonus will not be determined (given) in the final game of the fake sign G number. Hereinafter, the game until the number of fake precursor G is reached is referred to as a fake precursor. In normal intervals, pseudo-bonuses can be determined during fake precursors. When a pseudo-bonus is determined (given) during the fake omen, if the remaining fake omen G number is equal to or greater than a predetermined number, the fake omen is rewritten to the real omen without changing the omen G number. In this case, the type of the determined (given) pseudo bonus is notified in the final game of the determined precursor G number. Further, when a pseudo bonus is determined (given) during the fake omen, if the remaining fake omen G number is less than a predetermined number, the omen G number is extended and the fake omen is rewritten to the real omen. In this case, the type of the determined (given) pseudo bonus is notified in the final game of the extended predictive G number.

(pseudo bonus section)
A “REG bonus”, a “BIG bonus”, and a “super BIG bonus” are provided in the pseudo bonus section. The "REG bonus" is started from the game following the announcement of the type of the determined (given) pseudo-bonus. The termination condition of the "REG bonus" is that the push order navigation at the time of winning the push order minor role reaches the first prescribed number. About 75 medals can be obtained for the "REG bonus" according to the present embodiment. When the "REG bonus" ends, the pseudo-bonus section and the advantageous section end, and shift to the non-advantageous section.

The "BIG bonus" is started from the game following the notification of the type of pseudo bonus that has been determined (given). The end condition of the "BIG bonus" is that the pushing order navigation at the time of winning the pushing order minor role reaches the second specified number. About 500 medals can be obtained for the "BIG bonus" according to the present embodiment. When the "BIG bonus" ends, the consecutive chan zone section starts. Also, during the "BIG bonus", a "1G consecutive" lottery will be held. If you win the "1G consecutive" lottery, the "BIG bonus" will be stocked. When the "BIG bonus" is stocked, the winning (giving) of the "BIG bonus" is notified by the main display device 210 or the like in the 1st G of the consecutive-chan zone section. Then, the "BIG bonus" starts from the next game. The "1G consecutive" lottery is performed when "strong chess" ("F_strong chess 1", "F_strong chess 2") is won, and when it is not won, the combination of symbols related to "batting order error" is displayed. The pressing order (batting order navigation) is displayed so that the player does not know that the "strong match" has been won. On the other hand, when the "1G consecutive" lottery at the time of the "strong choi" win is a win, the pushing order (batting order navigation) is not displayed. That is, when the "1G run" lottery at the time of winning "Strong Che" is won, if the first stop operation is Reel A or Reel D, the symbol combination (NM21 to NM23) related to "Strong Che" is displayed. be done. This can suggest to the player that the "1G consecutive" lottery has been won. In addition, the "1G consecutive" lottery is performed when "RB 1 sheet" ("F_RB 1 sheet 01" to "F_RB 1 sheet 12") is won, and in this case, regardless of winning or not winning, the correct answer pushing order (batting order navigation) display. When the "1G Ren" lottery has already been won and the "BIG Bonus" is stocked, the "1G Ren" lottery will not be conducted even if the "Strong Chase" or "1 RB" is won.

The "super BIG bonus" is started from the next game in which the pseudo-bonus is determined (given) and the type of the pseudo-bonus is announced. The "super BIG bonus" means that the winning of the "BIG bonus" and the stock of the "BIG bonus" are determined. That is, when the determination (granting) of the "super BIG bonus" is notified by the main display device 210 or the like, the "BIG bonus" is started from the next game, and when the "BIG bonus" is finished, the continuous-chan zone section is entered. Transition. Then, in the 1st G of the consecutive-chan zone section, determination (giving) of the "BIG bonus" is reported by the main display device 210 or the like, and the "BIG bonus" is started from the next game. Therefore, the "super BIG bonus" according to the present embodiment can obtain approximately 1000 medals.

When "RB" and "BB" are activated during the pseudo bonus (AT), the pseudo bonus is temporarily interrupted and a special state is started. In the special state, the number of medals that have decreased during the operation of "RB" and "BB" is counted. Then, after the operation of "RB" and "BB" is completed, navigation (that is, informing the player of the information of the stop operation advantageous to the player for the combination related to the payout of medals) returns the reduced medals. do. Specifically, the number of times of navigation is set to a value obtained by dividing the number of medals decreased during the operation of "RB" and "BB" by 12 (the remainder is discarded). In addition, during the special state, the main display device 210 or the like displays "returning to state" to inform the player that the pseudo bonus is temporarily interrupted. The special state ends when the navigation for the set number of times (returning medals for the decrease) is completed and the game stop operation is completed while the RB is inside (during carryover). , return to the pseudo-bonus.

(Ren-chan zone section)
The continuous chan zone section is set to a maximum of 100 G after the end of the "BIG bonus". The table type is determined for the 1G of the continuous zone section, and the map type is determined according to the table type. The table type of the continuous zone section is determined according to the remaining period (number of games played) of the advantageous section or whether or not a pseudo bonus has been determined. In addition, in the consecutive chan zone section, winning or non-winning of the pseudo bonus is determined according to the map type.

Types of pseudo bonuses that can be determined in the continuous zone zone are "BIG bonus" and "super BIG bonus". That is, when the pseudo bonus is determined in the consecutive-chan zone, it is decided to shift to the consecutive-chan zone section after the pseudo-bonus section ends. The continuous chan zone section has a higher degree of expectation that the pseudo bonus will be determined than the high probability zone and the BIG certainty zone. In addition, when the winning of the pseudo-bonus is determined before shifting to the continuous-chan zone section, the winning of the pseudo-bonus is not determined in the continuous-chan zone section.

In the continuous zone section, it is possible to determine a fake sign. When the fake portent is determined, the number of fake portent G is determined, and the fake portent effect over the fake portent G number is performed. In the fake precursor effect, it is reported that the pseudo bonus will not be determined (given) in the final game. When the fake sign ends, the consecutive chan zone section ends and the advantageous section ends. As a result, the advantageous section shifts to the non-advantageous section. In addition, as the continuous chan zone section, there is a section in which the fake precursor effect is started at the same time as the start (immediate precursor). In this case, even if the fake portent effect ends, the consecutive-chan zone section does not end, nor does the advantageous section end. In the present embodiment, the end condition of the consecutive-chan zone section is the end of the fake precursor, but the ending condition of the consecutive-chan zone section according to the present invention can be set as appropriate. For example, the number of games in the continuous-challenging zone section may be determined when shifting to the continuous-challenging zone section. Also, the number of games in the continuous zone section may be set to a predetermined fixed value.

(Advantageous section upper limit processing)
In the second gaming machine, limit processing is executed in the same manner as in the above-described first gaming machine (see FIG. 1). As limit processing, the above-described game number limiter (1500 games) and payout number limiter (2400 cards) are employed. In the second gaming machine, in the normal section, when the number of medals paid out in the advantageous section reaches a first specific number (for example, "1400") or the value of the advantageous section game number counter reaches the first specific value. (For example, "1350") or more, the lottery for "super BIG bonus" and "1G series" is not performed. In other words, if there is a possibility that the player cannot fully enjoy the benefits of the "super BIG bonus" or the "1G ren" and there is a possibility that limit processing will be performed, the winning of the "super BIG bonus" or the "1G ren" You can choose not to decide. As a result, it is possible to prevent the player from feeling uncomfortable. Also, in the normal section, the value of the advantageous section game count counter is less than or equal to a second specific value (eg, "1479"), and the number of medals paid out during the advantageous section is equal to or greater than a second specific number (eg, "2200"). or when the value of the number-of-games-advantage-zone game counter reaches the second specific value, the "BIG bonus" is determined (given), and the "BIG bonus" is determined (given) by the main display device 210 or the like. inform.

In the pseudo-bonus section, if the number of medals paid out during the advantageous section exceeds the payout number limiter (2400), or if the value of the advantageous section game number counter reaches the game number limiter (1500 games), a pseudo-bonus. The (advantageous section) is ended, and the end of the pseudo bonus (advantageous section) is notified by the main display device 210 or the like. Also, in the pseudo-bonus section, the value of the advantageous section game number counter is a second specific value (eg, "1479") or less, and the number of medals paid out during the advantageous section is a second specific number (eg, "2200") or greater. , or when the value of the number-of-games-advantage-zone game counter reaches the second specific value, the main display device 210 or the like executes an ending effect that announces the ending. When the pseudo-bonus in which the ending effect was performed ends, the advantageous section ends without moving to the consecutive chan zone section. In addition, during the pseudo-bonus with the ending effect, if the number of payout medals in the advantageous section exceeds the payout number limiter (2400), or the value of the advantageous section game number counter reaches the game number limiter (1500 games). If it becomes, even in the middle of the pseudo bonus, the pseudo bonus is terminated and the advantageous section is terminated. In addition, if the upper limit of the advantageous section is reached while the pseudo bonus (AT) and "RB" and "BB" are in operation, the end of the advantageous section is displayed as the main display when the next game start operation is performed. Notification is made by the device 210 or the like.

In the second gaming machine, only the number-of-games limiter may be used to limit the advantageous interval, or only the payout-number limiter may be used to limit the advantageous interval. Both the limiter and the number-of-payouts limiter may be used to limit the advantageous section. When both limiters are used, it is desirable to end the advantageous interval when the operation condition of one of the limiters is satisfied after the advantageous interval starts.

Also, the types of limiters are not limited to the game number limiter and payout number limiter described above. For example, the number of times of navigating the push-order minor combination during the AT state (that is, the number of times the information of the stop operation that is advantageous to the player for the combination related to the payout of medals) is a predetermined number (for example, "400" times). A navigation count limiter may be provided for executing limit processing when the number of times of navigation is reached. That is, as long as the gambling aspect can be appropriately suppressed, it is possible to execute limit processing using various game-related conditions.

[High probability zone / BIG probability zone table]
Next, with reference to FIGS. 51 and 52, tables of high probability zones and BIG probability zones will be described. FIG. 51 is a table list of a high probability zone and a BIG probability zone according to the second gaming machine. FIG. 52 is a correspondence table of the high probability zone and the BIG probability zone and the zone according to the second gaming machine.

As shown in FIG. 51, the table types of the high probability zone and the BIG probability zone are tables A to E. As described above, the table types of the high probability zone and the BIG probability zone are determined by the table type lottery performed in the next game after shifting to the advantageous section. Once the table type is determined, it basically does not change until a pseudo bonus (REG bonus, BIG bonus, super BIG bonus) is won. Then, the MAP type is determined according to the table type. The MAP type influences the degree of expectation for winning the pseudo bonus.

As shown in FIG. 51, table A is a basic table and is a table type that is easier to determine than tables B-E. When table A is determined, the number of games (ceiling) until the pseudo bonus is determined is the largest. As shown in FIG. 52, when table A is determined, the expectation level for determination of the pseudo bonus (hereinafter referred to as "AT winning expectation level") is "low" in the advantageous section 51 to 100G. Become. AT winning expectations include “blank”, “low”, “medium”, “high”, and “fixed”, and AT winning expectation “blank” has the lowest expectation. Expectations increase in the order of "Medium", "High", and "Confirmed". It should be noted that the pseudo bonus is always determined during the period (zone) of the AT winning expectation degree “fixed”. When table A is determined, the AT win expectation degree is “fixed” in the advantageous section of 951 to 1000G, and a pseudo bonus is always determined. Also, when Table A is determined, the AT winning expectation is "high" in the advantageous section 151-200G, and the probability that the pseudo-bonus will be determined is higher than other periods excluding the advantageous section 951-1000G. get higher

As shown in FIG. 51, table B is a chance table A with a higher degree of expectation than table A for determining a pseudo bonus. When table B is determined, the number of games (ceiling) until the pseudo bonus is definitely determined is smaller than when table A is determined. As shown in FIG. 52, when the table B is determined, the AT winning expectation degree becomes "fixed" in the advantageous section 751 to 800G, and the pseudo bonus is always determined. Also, when table B is determined, the AT winning expectation is "high" in the advantageous section 151-200G, and the probability that the pseudo bonus is determined is higher than other periods except for the advantageous section 751-800G. get higher

As shown in FIG. 51, table C is a chance table B with a higher degree of expectation than table A for determining a pseudo bonus. When table C is determined, the number of games (ceiling) until the pseudo bonus is definitely determined is smaller than when table B is determined. As shown in FIG. 52, when the table C is determined, the AT win expectation degree is "fixed" in the advantageous section 551 to 600G, and the pseudo bonus is always determined. Also, when Table C is determined, the AT winning expectation is "high" in the advantageous section 151-200G, and the probability that the pseudo-bonus is determined is higher than in other periods excluding the advantageous section 551-600G. get higher

As shown in FIG. 51, table D is a chance table C with a higher degree of expectation than table A for determining a pseudo bonus. When table D is determined, the number of games (ceiling) until the pseudo bonus is definitely determined is smaller than when table C is determined. As shown in FIG. 52, when the table D is determined, the AT win expectation degree is "fixed" in the advantageous section 351 to 400G, and the pseudo bonus is always determined. Also, when Table D is determined, the AT winning expectation is "high" in the advantageous section 151-200G, and the probability that the pseudo-bonus will be determined is higher than in other periods excluding the advantageous section 351-400G. get higher

As shown in FIG. 51, table E is a table in which a pseudo-bonus is determined within 200 games. As shown in FIG. 52, when the table E is determined, the AT win expectation degree is "fixed" in the advantageous section 151 to 200G, and the pseudo bonus is always determined. Also, when Table E is determined, the AT winning expectation is "low" in the advantageous section 51-100G, and the probability that the pseudo-bonus will be determined is higher than other periods excluding the advantageous section 151-200G. get higher

In the next game after transitioning to the advantageous section, if the RT state is the RT0 state, table A is not determined, and tables B to E are determined. As for the table to be determined, table D or table E may be determined, or only table E may be determined. On the other hand, when the RT states are the RT1 and RT2 states, table A is likely to be determined. Therefore, when the RT state is the RT0 state, the degree of expectation that the pseudo bonus will be determined is higher than when the RT state is the RT1 or RT2 state.

For example, in a non-advantageous section after initialization by a setting change operation, if "RB" is won and the symbol combination related to "RB" is not displayed in the game, the game will be performed inside the RB (RB In order to shift to the inter-flag state), the RT state shifts from the RT0 state to the RT2 state, and also shifts to the advantageous section in the game. Therefore, in the next game after transitioning to the advantageous section, the RT state becomes the RT2 state, so the table type lottery according to the RT0 state is not performed.

On the other hand, in a non-advantageous section after initialization by a setting change operation, if an internal winning combination that does not overlap with "RB" or "BB" and is capable of transitioning to an advantageous section is won, RT state does not change from the RT0 state, and transitions to the advantageous section in the game. After that, if "RB" or "BB" is won in the next game after transitioning to the advantageous section, the RT state will shift from the RT0 state to the RT2 state. However, in the present embodiment, taking into consideration that the RT state in the game that transitioned to the advantageous section was the RT0 state, the table type lottery is performed according to the RT0 state.

Also, in the non-advantageous section after initialization by the setting change operation, if "BB" is won and the symbol combination related to "BB" is not displayed in the game, the game will be performed inside the BB (BB state between flags), and transition to an advantageous section in the game. As described above, a lottery (for example, an AT lottery (pseudo-bonus lottery)) relating to the number of balls to be put out is not performed in the state between BB flags. Therefore, even though the player does not make any mistakes, the player is put in a disadvantageous state. Moreover, since it is in the state between BB flags (RT2 state), the table type lottery according to the RT0 state cannot be accepted. Therefore, in the present embodiment, the table type lottery is not performed during the BB flag state, and the table type lottery corresponding to the BB operation state is performed after shifting to the BB operating state. In the table type lottery corresponding to the BB operation, tables B to table E are determined in the same manner as the table type lottery corresponding to the RT0 state.

[Ren-chan zone table]
Next, referring to FIG. 53, a table of consecutive chan zones will be described. FIG. 53 is a table list of the consecutive-chan zone related to the second gaming machine.

As shown in FIG. 53, the table types of the consecutive chan zone are Table F to Table I. The table type of the consecutive chan zone depends on the type of pseudo bonus and the remaining period of the advantageous section (number of games) when "BIG bonus", "super BIG bonus", or "freeze" described later is decided. It is determined. Table F is determined when the type of pseudo bonus is "BIG bonus" and the remaining period (number of games played) of the advantageous interval is equal to or longer than a predetermined period (for example, 500 G). Table G is determined when the type of pseudo bonus is "BIG bonus" and the remaining period (number of games played) of the advantageous interval is less than the predetermined period. When the table G is determined, the map type is not determined in which the maximum number of games played until the "BIG bonus" is determined is 100 G in the consecutive-chan zone section. On the other hand, when Table F is determined, a map type is determined in which the maximum number of games played until the "BIG bonus" is determined is 100G in the consecutive-chan zone section. Therefore, when table G is determined, the number of games played until the "BIG bonus" is determined is smaller than when table F is determined (the period during which medals decrease is shortened) in the continuous zone section. Become).

Table H is determined when the type of pseudo bonus is "freeze". “Freeze” is a pseudo bonus that determines a “super BIG bonus” and increases the probability of winning the 1G series. “Freeze” is determined when “middle cherry” (F_middle choi 1, F_middle choi 2), which is a fixed combination, is won, or when “freeze” is won in the AT type lottery described later. When "freeze" is determined, a lock effect is performed in the next game, and it is notified that a "super BIG bonus" has been determined (given). Table I is determined when it is a special mode, which will be described later.

[Table type lottery table]
Next, the table type lottery table will be described with reference to FIGS. 54 to 59. FIG. The table type lottery table is referred to for the table type lottery to be performed in the next game of the transition to the advantageous section, and defines the lottery value information for the table type lottery result for each setting value. The probability denominator of the lottery values shown in FIGS. 54 to 59 is "256".

FIG. 54 is a table type lottery table referred to when the RT state is the RT0 state in the next game after transitioning to the advantageous section. As shown in FIG. 54, when the RT state is the RT0 state, table A does not win, and table B tends to win. In other words, if the RT state is the RT0 state in the next game after transitioning to the advantageous section, it is easy to win the table where the pseudo bonus (AT) is determined at least in the advantageous section 751-800G. Note that the table E may be determined when the RT state is RT0 in the next game after transitioning to the advantageous section. In this case, since the pseudo bonus is determined in the advantageous section 151-200G, the state after the setting change is more advantageous to the player.

FIG. 55 is a table type lottery table that is referred to when the RT state is other than the RT0 state in the next game after transitioning to the advantageous section. In this embodiment, a table type lottery table is provided which is referred to in the RB operating state (RT3 state) and the BB operating state (RT3 state). Therefore, when the RT state is other than the RT0 state, it is substantially the RT1 state and the RT2 state. As shown in FIG. 55, when the RT state is other than the RT0 state, table A is easy to win, and tables B to E are relatively difficult to win. That is, if the RT state is other than the RT0 state in the next game after transitioning to the advantageous section, it is easy to win a table in which a pseudo bonus (AT) is determined at least in the advantageous section 951-1000G.

FIG. 56 is a table type lottery table referred to when the RB operation state (RT3 state) occurs in the next game after transitioning to the advantageous section. In the case of the RB operating state (RT3 state), the higher the set value, the easier it is to win the table C. That is, in the case of the RB operating state (RT3 state) in the next game after transitioning to the advantageous section, the higher the set value, the more likely it is to win a table in which the pseudo bonus (AT) is determined at least in the advantageous section of 551 to 600G. Become.

FIG. 57 is a table type lottery table that is referred to when the BB is activated (RT3 state) in the next game after transitioning to the advantageous section. In the case of the BB operating state (RT3 state), table A does not win, and table B wins relatively easily. Also, the higher the set value, the easier it is to win the table C. That is, when the RB operation state (RT3 state) is in the next game after the transition to the advantageous section, it is relatively easy to win the table where the pseudo bonus (AT) is determined at least in the advantageous section 751 to 800G, and the set value is high. As the number increases, it becomes easier to win the table where the pseudo bonus (AT) is determined at least in the advantageous section of 551 to 600G.

[Each zone and MAP type]
Next, with reference to FIGS. 58 and 59, the MAP type of the high probability zone, the BIG certainty zone, and the continuous Chan zone section will be described. FIG. 58 is a correspondence table of zones and MAP levels relating to the second gaming machine. FIG. 59 is a correspondence table of MAP levels and pseudo-bonus win rates relating to the second gaming machine.

As shown in FIG. 58, the map types of the high-probability zones are high-probability_normal A, high-probability_normal B, high-probability_normal C, and high-probability_heaven. The map type of the high-probability zone is determined by a normal map lottery held in the next game after the transition to the advantageous section. Also, the high probability zone is the advantageous section from 1 to 200G and is divided into four blocks. The first block of the high probability zone is 1-50G, the second block is 51-100G, the third block is 101-150G, and the fourth block is 151G-200G. Each map type of the high probability zone defines a MAP level for each block. For example, if high probability_normal A is determined as the map type of the high probability zone, the first block is MAP level 0, the second block is MAP level 1, the third block is MAP level 0, and the fourth block is MAP level 2.

The map types of BIG definite zones are BIG_Normal A, BIG_Normal B, BIG_Normal C, and BIG_Heaven. The map type of the BIG certainty zone is determined by a normal map lottery that is performed every 200G in the BIG certainty zone. The BIG probability zone is the advantageous section from 201 to 1000G, and is divided into four blocks every 200G. For example, the first block of the BIG definite zone is 201-250G, 401-450G, 601-650G, 801-850G. The map type of the BIG probability zone is determined by the normal map lottery performed in the 1st block (4) 1G. Each map type of the BIG certainty zone defines the MAP level for each block. For example, if BIG_Normal A is determined as the map type of the BIG probability zone, the first block is MAP level 0, the second block is MAP level 0, the third block is MAP level 0, and the fourth block is MAP level. 1.

The map types of the Renchan zone section are Ren_Normal A, Ren_Normal B, Ren_Normal C, Ren_Normal D, Ren_Normal E, Ren_Normal F, Ren_Immediately weak sign A, Ren_Immediately weak. These are omen B, ren_immediately weak omen C, ren_immediately strong omen A, ren_strong omen B, ren_strong omen C, and ren_special. The continuous chan zone section has a maximum of 100G after the end of the pseudo-bonus and is divided into two blocks. The first block of the continuous chan zone section is 1 to 50G after the end of the pseudo bonus, and the second block is 51 to 100G after the end of the pseudo bonus.

The map type of the consecutive-chan zone section is determined by the consecutive-chan zone map lottery performed in 1G of the first block. In addition, the table type referred to in the Renchan zone map lottery is determined when the "BIG bonus", "Super BIG bonus", or "Freeze" that was performed before moving to the Renchan zone section is decided. It is Each map type of the continuous zone section defines the MAP level for each block. For example, when RUN_NORMAL A is determined as the map type of the RUN zone section, the first block is MAP level 0, and the second block is MAP level 1. FIG. It should be noted that continuation_special is a map type that can be determined in the case of a special mode, which will be described later.

As shown in FIG. 59, MAP level 0 to MAP level 6 are provided as MAP levels related to the second game. A block with MAP level 0 has a pseudo bonus winning rate of "low". The pseudo-bonus winning rate “low” has the lowest expected value for determining the pseudo-bonus. In a block of MAP level 0, it is determined by lottery whether or not to perform an omen (an omen includes a real omen and a fake omen). In addition, in the block of MAP level 0, it is decided by lottery whether or not to perform the forced portent G number lottery. When the forced precursor G number lottery is performed, the forced precursor G number is determined, and when the game with the determined forced precursor G number is played, an AT lottery corresponding to the MAP level is performed.

A block of MAP level 1 has a pseudo-bonus winning rate of “normal”. The pseudo-bonus winning rate “Normal” has a higher expected value for determining the pseudo-bonus than the pseudo-bonus winning rate “Low”. In the block of MAP level 1, since the forced precursor G number lottery is performed, the precursor is always performed. For example, if the map type is BIG_Normal A, the first to third blocks are MAP level 0, and the fourth block is MAP level 1. Therefore, when the map type is BIG_Normal A, a sign is always performed in the fourth block.

A block of MAP level 2 has a pseudo bonus winning rate of “high”. The pseudo-bonus winning rate “high” has a higher expected value for determining the pseudo-bonus than the pseudo-bonus winning rate “normal”. In the blocks of MAP level 2, since the compulsory precursor G number lottery is performed, the precursor is always performed. For example, if the map types are high-precision_normal A, high-precision_normal B, and high-precision_normal C, the fourth block is MAP level 2. Therefore, when the map types are high probability_normal A, high probability_normal B, and high probability_normal C, the expected value for determining the pseudo bonus is high in the fourth block.

A block of MAP level 3 has a pseudo-bonus winning rate of “fixed”. The pseudo-bonus winning rate “fixed” determines the winning of the pseudo-bonus. In the block of MAP level 3, since the forced precursor G number lottery is performed, the precursor is always performed. For example, if the map types are High Accuracy_Heaven, BIG_Heaven A, and BIG_Heaven B, the fourth block is MAP level 3. Therefore, when the map types are high probability_heaven, BIG_heaven A, and BIG_heaven B, the winning of the pseudo-bonus is confirmed in the fourth block.

A block of MAP level 4 has a pseudo bonus winning rate of “high”. In MAP level 4 blocks, a precursor is started at the beginning. In addition, in the blocks of MAP level 4, the compulsory precursor G number lottery is not performed. For example, if the map type is RUN_Immediately weak precursor A, continuation_Immediately weak precursor B, or RING_Immediately strong precursor A Ren_Immediately strong precursor B, the first block is MAP level 4. FIG. Therefore, if the map type is Ren_Immediately Weak Omen A, Ren_Immediately Weak Omen B, Ren_Immediately Strong Omen A Ren_Immediately Strong Omen B, at the start of the first block (after the "BIG Bonus" ends) Omens start at , and the expected value that determines the pseudo-bonus increases.

A block of MAP level 5 has a pseudo-bonus winning rate of “fixed”. In the block of MAP level 5, a pseudo bonus is won at the start, and this sign is started. In addition, in blocks of MAP level 5, a compulsory precursor G number lottery is performed. For example, if the map type is RUN_SLOW SIGN C, RUN_SONG STRONG SIGN C, the first block is MAP level 5. FIG. Therefore, when the map type is the continuation_immediate weak omen C and the continuation_immediately strong omen C, this omen is started at the start of the first block (after the end of the "BIG bonus").

Blocks with MAP level 6 have a pseudo-bonus winning rate of "extremely low". The pseudo-bonus winning rate “extremely low” has a lower expected value for determining the pseudo-bonus than the pseudo-bonus winning rate “low”. In the block of MAP level 6, since the forced precursor G number lottery is performed, the precursor is always performed. MAP level 6 is defined only for the second block when the map type is ream_special.

[Normal map lottery table]
Next, the normal map lottery table will be described with reference to FIGS. 60 to 84. FIG. In this embodiment, the advantageous section 1 to 200G is called zone 0, and the advantageous section 201 to 400G is called zone 1. In addition, the advantageous section 401-600G is called zone 2, 601-800G is called zone 3, and 801-1000G is called zone 4. The normal map lottery table is referenced for the normal map lottery that is held in the first G (every 200G) of zones 0 to 4 in the advantageous section, and defines the lottery value information for the map type lottery results for each set value. do. The probability denominator of the lottery values shown in FIGS. 60 to 84 is "256".

FIG. 60 is a normal map lottery table referred to when the table type is table A in zone 0. FIG. FIG. 61 is a normal map lottery table referred to when the table type is table B in zone 0. FIG. FIG. 62 is a normal map lottery table referred to when the table type is table C in zone 0. FIG. FIG. 63 is a normal map lottery table referred to when the table type is table D in zone 0. FIG. FIG. 64 is a normal map lottery table referred to when the table type is table E in zone 0. FIG. As shown in FIGS. 60 to 64, in zone 0, which is an advantageous section from 1 to 200G, when the table types are table A and table B, high accuracy_normal A wins as the map type. Further, when the table type is table D, high probability_normal C can be won as the map type, and when it is table E, high probability_heaven can be won as the map type.

65 is a normal map lottery table referred to when the table type is table A in zone 1. FIG. FIG. 66 is a normal map lottery table referred to when the table type is table B in zone 1. FIG. FIG. 67 is a normal map lottery table referred to when the table type is table C in zone 1. FIG. FIG. 68 is a normal map lottery table referred to when the table type is table D in zone 1. FIG. 69 is a normal map lottery table referred to when the table type is table E in zone 1. FIG. As shown in FIGS. 65 to 69, in zone 1, which is the advantageous section from 201 to 400G, when the table types are table A and table E, BIG_normal A wins as the map type. In the case of Table B and Table C, BIG_Normal A and BIG_Normal B can be won as map types, and in the case of Table D, BIG_Tengoku A and BIG_Tengoku B can be won as map types. .

FIG. 70 is a normal map lottery table referred to when the table type is table A in zone 2. FIG. FIG. 71 is a normal map lottery table referred to when the table type is table B in zone 2. FIG. FIG. 72 is a normal map lottery table referred to when the table type is table C in zone 2. FIG. 73 is a normal map lottery table referred to when the table type is table D in zone 2. FIG. FIG. 74 is a normal map lottery table referred to when the table type is table E in zone 2. FIG. As shown in FIGS. 70 to 74, in zone 2, which is the advantageous section 401 to 600G, when the table types are table B, table D, and table E, BIG_Normal A wins as the map type. In the case of Table A, BIG_Normal A and BIG_Normal B can be won as map types, and in the case of Table C, BIG_Heaven A and BIG_Heaven B can be won as map types.

FIG. 75 is a normal map lottery table referred to when the table type is table A in zone 3. FIG. FIG. 76 is a normal map lottery table referred to when the table type is table B in zone 3. FIG. FIG. 77 is a normal map lottery table referred to when the table type is table C in zone 3. FIG. FIG. 78 is a normal map lottery table referred to when the table type is table D in zone 3. FIG. FIG. 79 is a normal map lottery table referred to when the table type is table E in zone 3. FIG. As shown in FIGS. 75 to 79, in zone 3, which is the advantageous section 601 to 800G, when the table types are table A and table C to table E, BIG_Normal A wins as the map type. In the case of table B, BIG_heaven A and BIG_heaven B can be won as map types.

FIG. 80 is a normal map lottery table referred to when the table type is table A in zone 4. FIG. FIG. 81 is a normal map lottery table referred to when the table type is table B in zone 4. FIG. FIG. 82 is a normal map lottery table referred to when the table type is table C in zone 4. FIG. 83 is a normal map lottery table referred to when the table type is table D in zone 4. FIG. FIG. 84 is a normal map lottery table referred to when the table type is table E in zone 4. FIG. As shown in FIGS. 80 to 84, in zone 4, which is the advantageous section 801 to 1000G, when the table type is table A, BIG_heaven A wins as the map type. In the case of Table B to Table E, BIG_Normal A wins as the map type as the map type.

[Ren-chan zone map lottery table]
Next, with reference to FIGS. 85 to 88, the consecutive-chan zone map lottery table will be described. The consecutive-chan zone map lottery table is referred to for the consecutive-chan zone map lottery performed in the 1st G of the consecutive-chan zone in the advantageous section, and defines the lottery value information for the map type lottery result for each set value. The probability denominator of the lottery values shown in FIGS. 85 to 88 is "256".

FIG. 85 is a consecutive-chan zone map lottery table referred to when the table type is table F in the consecutive-chan zone. FIG. 86 is a consecutive-chan zone map lottery table referred to when the table type is table G in the consecutive-chan zone. FIG. 87 is a consecutive-chan zone map lottery table referred to when the table type is table H in the consecutive-chan zone. FIG. 88 is a consecutive-chan zone map lottery table referred to when the table type is table I in the consecutive-chan zone.

As described above, the table F is determined when the remaining period (number of games played) of the advantageous section is equal to or longer than the predetermined period. Then, as shown in FIG. 85, in the case of table F in the run-chan zone, run_normal A, run_normal B, run_normal C are likely to be won as map types. In the run_normal A, run_normal B, and run_normal C, the second block of the run-chan zone section has a higher expected value for winning the pseudo bonus than the first block (see FIG. 58). On the other hand, the table G is determined when the remaining period (number of games played) of the advantageous section is less than the predetermined period. Then, as shown in FIG. 86, in the case of table G in the consecutive-chan zone, consecutive_normal D, consecutive_normal E, and consecutive_normal F are likely to be won as map types. In the run_normal D, run_normal E, and run_normal F, the expected value of winning the pseudo bonus is higher in the first block than in the second block of the run zone section (see FIG. 58). In this way, when the remaining period (number of games played) of the advantageous section is less than the predetermined period, the table G is determined so that the pseudo bonus is won relatively earlier than when the table F is determined. there is As a result, it is possible to shorten the continuous zone section (the section in which the number of medals decreases) between the pseudo-bonus sections in which medals increase and the pseudo-bonus section, thereby relieving the dissatisfaction of the player.

As described above, table H is determined when the type of pseudo bonus is "freeze". As shown in FIG. 87, in the case of the table H in the consecutive-chan zone, the consecutive_immediately strong precursor B and the consecutive_immediately strong precursor C are won as the map types. Therefore, when the type of the pseudo bonus is "freeze", as the map type of the subsequent consecutive-chan zone section, the consecutive_immediately strong precursor B or the consecutive_immediately strong precursor C is won. Also, table I is determined in the case of a special mode, which will be described later. As shown in FIG. 88, in the case of table I in the consecutive-chan zone, consecutive_special wins as the map type. Therefore, in the case of the special mode, RUN_SPECIAL wins.

[AT lottery (pseudo bonus lottery)]
Next, the AT lottery relating to the second gaming machine will be described. In the second game machine, three AT lotteries are provided: an AT lottery when the number of forced precursor G is reached, a normal AT lottery, and an AT lottery when the AT point is reached. In addition, in the second gaming machine, when the winning combination is "middle stage cherry", a pseudo-bonus (AT) win is determined without conducting an AT lottery. As described above, "middle stage cherry" is a fixed hand and corresponds to the above-mentioned "F_middle stage choi 1" and "F_middle stage choi 2".

(AT lottery when compulsory sign G number is reached)
The AT lottery at the time of reaching the forced sign G number can be executed in the high probability zone, the BIG certainty zone, and the consecutive chan zone section of the advantageous section. In the second gaming machine, it is determined whether or not to perform a forced predictive G number lottery in the 1st G of each block (50G increments) in the high probability zone, BIG certainty zone, and continuous zone section. In the MAP level 0 block, it is determined whether or not to perform the forced precursor G number lottery by the MAP level 0 forced precursor entry lottery. Also, in the blocks of MAP levels 1 to 3, MAP level 5, and MAP level 6, it is determined that a forced precursor G number lottery will be performed. Then, in blocks of MAP level 4, it is decided not to perform the forced precursor G number lottery.

The forced precursor G number determined by the forced precursor G number lottery is set in the counter for the number of forced precursor games. The compulsory precursor game number counter is decremented by 1 for each game, and in the game in which the value of the compulsory precursor game number counter becomes "0", an AT lottery is performed when the compulsory precursor G number is reached. In the AT lottery when the number of forced omen G is reached, one of non-winning, fake winning, and real omen winning is determined. If a non-winning is determined, no omen is performed.

When the fake winning is determined, the number of fake precursor games is determined, and the fake precursor effect is performed over the determined number of fake precursor games. In the final game of the fake precursor effect, the main display device 210 or the like notifies that the pseudo bonus (AT) has not been won. In addition, in a game in which the fake precursor effect is performed, an AT lottery is performed during the fake precursor. In the fake omen AT lottery, it is determined whether or not to change the fake prize to the real omen prize. When the fake winning is changed to the main omen winning, "BIG bonus" is determined as the type of the pseudo bonus (AT). In addition, when changing the fake lottery to the main omen game, the remaining number of fake omen games is set to the number of omen games, or an appropriate number of games is added to the remaining number of fake omen games to make the number of omen games. It is determined whether Then, the main sign effect is performed over the number of the main sign games.

When the main omen lottery is determined, an AT type lottery is performed. In the AT type lottery, one of "REG bonus", "BIG bonus", "super BIG bonus", and "freeze" is determined. When "REG bonus", "BIG bonus", or "super BIG bonus" is determined by AT type lottery, the number of omen games is determined, and the omen effect is performed over the determined number of omen games. . On the other hand, when "freeze" is determined by the AT type lottery, the main display device 210 or the like notifies that the "super BIG bonus" has been won in the next game without performing this precursor effect.

In the game in which the main sign effect is performed, an AT type promotion lottery is performed during the main sign. In the AT type promotion lottery in this precursor, it is determined whether or not the “REG bonus” is promoted to the “BIG bonus” or whether the “BIG bonus” is promoted to the “super BIG bonus”. When the "super BIG bonus" has been determined in the AT type lottery, the AT type promotion lottery in this omen is not performed. In the final game of this portent effect, the type of the won (finally determined) pseudo bonus (AT) is notified by the main display device 210 or the like.

(Normal AT lottery)
Usually AT lotteries are held in non-advantageous sections and advantageous sections. In the non-advantageous section, the winning combinations that can be shifted to the advantageous section ("Illegal (only during RB/BB)", "F_Normal Rep 2", "F_Normal Rep 3", "One in F_RB", and "F_RB When a combination other than "medium bell" is determined, a normal AT lottery is performed. On the other hand, in the advantageous section, normal AT lottery is performed during non-prediction. Usually, in the AT lottery, either non-winning or winning is determined. The flow of the game when the winning is determined by the normal AT lottery is the same as when the above-described main omen winning is determined. On the other hand, when non-winning is determined by the normal AT lottery, the pseudo bonus is not won and the fake portent entry lottery is performed. In the fake sign entry lottery, either non-winning or winning is determined. When non-winning is determined by the fake sign entry lottery, the fake sign production is not performed. The flow of the game when the winning is determined by the fake sign entry lottery is the same as the above-described case when the fake winning is determined.

(AT lottery when AT points are reached)
In the second game machine, in a game in which any one of ``F_RB 1 card 01'' to ``F_RB 1 card 12'' is won in the advantageous section and inside the RB, the display of the combination of symbols related to ``RB'' is stopped. The operation mode (correct answer pressing order) is reported. Then, when the stop operation is performed in the avoidance stop operation mode, a combination of symbols relating to "F_RB 1 sheet 01" to "F_RB 1 sheet 12" is displayed. Also, if any one of "F_RB 1 card 01" to "F_RB 1 card 12" is won, 1 point is given as an AT point. It is added to the granted AT point counter. Then, when the value of the AT point counter reaches a predetermined value (12 points in this embodiment), an AT lottery is performed when the AT point is reached. More specifically, after the next game in which the value of the AT point counter reaches a predetermined value, it is not in the continuous zone section, but in the non-prediction, and inside other than "F_RB 1 card 01" to "F_RB 1 card 12". When the winning combination is won, an AT lottery is performed when the AT point is reached. At this time, if the AT point counter value is greater than a predetermined value, the predetermined value is subtracted from the AT point counter value, and the remaining points are carried over. In the AT lottery upon reaching the AT point, either non-winning or winning is determined. The flow of the game when the winning is determined by the AT point reaching AT lottery is the same as the above-described case when the main omen winning is determined. On the other hand, when non-winning is determined by the normal AT lottery, the pseudo bonus is not won, the number of fake precursor games is determined, and the fake precursor performance is performed over the determined number of fake precursor games. Also, the AT point counter is reset when transitioning to a non-advantageous section. It should be noted that the AT point counter may be reset when the "BIG bonus" and "super BIG bonus" are won or finished.

[Map Level 0 Forced Omen Inrush Lottery Table]
Next, with reference to FIG. 89, the forced precursor entry lottery table at MAP level 0 will be described. The MAP level 0 forced entry lottery table is a MAP level 0 forced entry that is performed when the 1G of each block (50G increments) in the high probability zone, BIG certainty zone, and continuous zone section is MAP level 0. It is referred to for the lottery, and defines the lottery value information for the lottery result of winning/non-winning for each set value. The probability denominator of the lottery value shown in FIG. 89 is "256".

[Forced Omen Game Number Lottery Table]
Next, with reference to FIG. 90, a forced precursor game number lottery table will be described. The forced predictive game number lottery table is referred to for the forced predictive game number lottery performed at the 1st G of each block (50G increments) in the high probability zone, BIG probability zone, and continuous zone section, and the forced predictive game number lottery is performed for each set value. Specifies the lottery value information for the number lottery result. The probability denominator of the lottery value shown in FIG. 90 is "256".

[AT lottery table when the number of forced precursor games is reached]
Next, with reference to FIGS. 91 to 97, the AT lottery table at the time of reaching the number of forced precursor games will be described. The AT lottery table when the number of forced precursory games is reached is referred to for the AT lottery when the number of forced precursory games is reached, which is performed in games where the value of the counter for the number of forced precursory games is "0". It defines the lottery value information for the lottery results of the lottery and the main omen lottery. The probability denominator of the lottery values shown in FIGS. 91 to 97 is "256".

FIG. 91 is an AT lottery table upon reaching the number of forced precursor games referred to when the MAP level is 0. FIG. As shown in FIG. 91, in the AT lottery at the time of reaching the number of compulsory portent games when the MAP level is 0, the main portent lottery is likely to be determined. That is, when it is determined that the number of forced precursor games lottery is to be performed by the forced precursor entry lottery at MAP level 0 when the MAP level is 0, the main precursor lottery is likely to be determined. FIG. 92 is an AT lottery table upon reaching the number of forced precursor games referred to when the MAP level is 1. FIG. In the AT lottery at the time of reaching the number of forced precursor games when the MAP level is 1, a fake lottery is likely to be determined. FIG. 93 is an AT lottery table upon reaching the number of forced precursor games referred to when the MAP level is 2. FIG. In the AT lottery at the time of reaching the number of compulsory precursor games in the case of MAP level 2, the main precursor lottery is more likely to be determined than in the case of MAP level 1.

FIG. 94 is an AT lottery table upon reaching the number of forced precursor games referred to when the MAP level is 3. FIG. In the AT lottery at the time of reaching the number of compulsory portent games in the case of MAP level 3, the main portent lottery is determined. Therefore, as shown in FIG. 58, when a map type that defines MAP level 3 is determined, a pseudo bonus (AT) is always won (fixed). FIG. 95 is an AT lottery table upon reaching the number of forced precursor games referred to when the MAP level is 4. FIG. In the AT lottery at the time of reaching the number of forced precursor games when the MAP level is 4, non-winning is determined. When the MAP level is 4, since the number-of-mandated-prediction-games lottery is not performed, the AT lottery is basically not performed when the number of forced precursory games is reached.

FIG. 96 is an AT lottery table upon reaching the number of forced precursor games referred to when the MAP level is 5. FIG. In the AT lottery at the time of reaching the number of forced precursor games when the MAP level is 5, non-winning is determined. As shown in FIG. 58, when a map type that defines MAP level 5 is determined, a pseudo bonus (AT) is always won (settled). In the present embodiment, in the AT lottery at the time of reaching the number of forced precursor games when the MAP level is 5, no pseudo bonus is won, and in the normal AT lottery, the pseudo bonus (AT) is always won. FIG. 97 is an AT lottery table upon reaching the number of forced precursor games referred to when the MAP level is 6. FIG. In the AT lottery at the time of reaching the number of compulsory precursor games in the case of MAP level 6, a fake lottery is determined.

[Normal AT lottery table]
Next, the normal AT lottery table will be described with reference to FIGS. 98 to 105. FIG. The normal AT lottery table is referred to for the normal AT lottery performed in the non-prediction game, and defines the lottery value information for the winning combination and the winning/non-winning lottery result for each set value. The probability denominator of the lottery values shown in FIGS. 98 to 105 is "256". In addition, the "replay" of the winning combination shown in FIG. handle. "Weak Choi" corresponds to "F_Weak Choi", and "Weak Watermelon" corresponds to "F_Weak Watermelon 1" and "F_Weak Watermelon 2". "Strong Che" corresponds to "F_Strong Che 1" and "F_Strong Che 2", and "Strong Watermelon" corresponds to "F_Strong Watermelon 1" and "F_Strong Watermelon 2".

FIG. 98 is a normal AT lottery table referred to when there is no table type (non-advantageous section). In the normal AT lottery with no table type, for example, when the winning combination is "Strong Che", a pseudo-bonus (AT) is determined. FIG. 99 is a normal AT lottery table referred to when the MAP level is 0. FIG. In the normal AT lottery when the MAP level is 0, for example, when the winning combination is "Strong Che", a pseudo bonus (AT) is determined with a probability of about 1/10. FIG. 100 is a normal AT lottery table referred to when the MAP level is 1. FIG. In the normal AT lottery when the MAP level is 1, for example, when the winning combination is "Strong Che", a pseudo bonus (AT) is determined with a probability of about 1/3. FIG. 101 is a normal AT lottery table referred to when the MAP level is 2. FIG. In the normal AT lottery at MAP level 2, for example, when the winning combination is "Strong Che", a pseudo-bonus (AT) is determined with a probability of about 3/4.

FIG. 102 is a normal AT lottery table referred to when the MAP level is 3. FIG. In the normal AT lottery when the MAP level is 3, for example, when the winning combination is "Strong Che", a pseudo-bonus (AT) is determined with a probability of 255/256. FIG. 103 is a normal AT lottery table referred to when the MAP level is 4. FIG. In the normal AT lottery when the MAP level is 4, for example, a pseudo-bonus (AT) is determined regardless of whether the winning combination is "weak Che", "weak watermelon", "strong Che", or "strong watermelon". be done. FIG. 104 is a normal AT lottery table referred to when the MAP level is 5. FIG. In the normal AT lottery when the MAP level is 5, a pseudo bonus (AT) is determined for any winning combination. FIG. 105 is a normal AT lottery table referred to when the MAP level is 6. FIG. In the normal AT lottery when the MAP level is 6, for example, when the winning combination is "Strong Che", a pseudo bonus (AT) is determined with a probability of 2/256.

[AT lottery table when reaching AT point]
Next, with reference to FIG. 106, the AT point lottery table will be described. The AT point reaching AT lottery table is referred to for an AT point reaching AT lottery to be performed when the value of the AT point counter reaches a predetermined value (12 points in this embodiment). defines the lottery value information for the winning/non-winning lottery results. The probability denominator of the lottery value shown in FIG. 106 is "256".

[AT lottery table during fake omen]
Next, with reference to FIG. 107, the AT lottery table during fake precursor will be described. The AT lottery table during fake omen is referred to for the AT lottery during fake omen performed in the game during fake omen (during fake omen production), and the lottery results of winning and non-winning for each winning role and set value. Specifies value information. The probability denominator of the lottery value shown in FIG. 107 is "256". When the pseudo-bonus is determined by the AT lottery during the fake omen, "BIG bonus" is determined as the type of the pseudo-bonus without performing the AT type lottery.

[AT type promotion lottery table in this omen]
Next, with reference to FIGS. 108 and 109, the AT type promotion lottery table in this sign will be described. The AT type promotion lottery table during this omen is referred to for the AT type promotion lottery during this omen performed in the game during this omen (during this omen production), and the lottery of winning and non-winning is performed for each winning combination and set value. Specifies the lottery value information for the result. The probability denominator of the lottery value shown in FIGS. 108 and 109 is "256".

FIG. 108 is the AT type promotion lottery table in this sign that is referenced when the type of the determined pseudo bonus is "REG bonus". FIG. 109 is the AT type promotion lottery table in this sign that is referenced when the type of the determined pseudo bonus is "BIG bonus". As shown in FIGS. 108 and 109, promotion from the "REG bonus" to the "BIG bonus" is more likely to be decided than promotion from the "BIG bonus" to the "super BIG bonus".

[AT type lottery table]
Next, the AT type lottery table will be described with reference to FIGS. 110 to 114. FIG. The AT type lottery table is referred to for the AT type lottery performed when the pseudo bonus (AT) lottery is determined by various AT lotteries, and contains lottery value information about the lottery result of the pseudo bonus type for each set value. stipulate. The probability denominator of the lottery values shown in FIGS. 110 to 114 is "256".

FIG. 110 is an AT type lottery table that is referred to in the case of the consecutive chan zone section. As shown in FIG. 110, in the continuous-chan zone section, "REG bonus" is not determined as the type of pseudo bonus, and "BIG bonus" or "super BIG bonus" is determined. FIG. 111 is an AT type lottery table that is referenced when the advantageous section is 201G or later. As shown in FIG. 111, in the case of the consecutive-chan zone section, "REG bonus" is not determined as the pseudo-bonus type. FIG. 112 is an AT type lottery table referred to when special ON (special mode). As shown in FIG. 112, when special ON (special mode), "super BIG bonus" is not determined. FIG. 113 is an AT type lottery table that is referred to in the advantageous section of 1 to 100G. FIG. 114 is an AT type lottery table that is referred to in the advantageous section 101-200G. As shown in FIGS. 113 and 114, in the advantageous section of 1 to 100 G, the "REG bonus" and the "BIG bonus" are determined with almost the same probability.

[AT type lottery table for middle stage cherry]
Next, with reference to FIGS. 115 and 116, the AT type lottery table for middle cherry will be described. The middle cherry AT type lottery table is referred to for the middle cherry AT type lottery that is performed when the pseudo bonus (AT) is determined by the "middle cherry" win, and the pseudo bonus type is determined for each set value. It specifies lottery value information for lottery results.
The probability denominator of the lottery values shown in FIGS. 115 and 116 is "256".

FIG. 115 is an AT type lottery table for middle cherry, which is referred to when "middle cherry" is won in a section other than the consecutive chan zone section (normal). FIG. 116 is an AT type lottery table for middle cherry which is referred to when "middle cherry" is won in the consecutive chan zone section. As shown in FIGS. 115 and 116, the "REG bonus" is not won in the AT type lottery at middle cherry. Also, if you win the "middle cherry" in a section other than the continuous chan zone (normal), you may win the "freeze", but if you win the "middle cherry" in the continuous chan zone section, the "freeze ” will not win.

[Stable state (special mode)/Rough wave state (non-special mode)]
In the second game machine, as the control state of the advantageous section (which may be called a game state, mode, or internal state), a "stable state" and a "rough wave state" are provided. The "stable state" is the above-described "special mode ON", and although the possibility of the player being able to rapidly increase the game value is reduced, the game value of the player is less likely to decrease. In addition, the "rough sea state" is "special mode OFF", and although there is a high possibility that the player can rapidly increase the game value, the game value of the player is likely to decrease. In addition, in the second gaming machine, although the "stable state" and the "rough wave state" are provided as internal states, the number of internal states is not limited to two, and may be three or more. . As the internal state according to the present invention, for example, a "first stable state", a "second stable state", a "first rough sea state", and a "second rough sea state" may be provided.

In the second game machine, a special rewrite lottery is performed in the game in which the fake sign (effect) of the fourth block (151G to 200G) is started. In the special rewrite lottery, it is determined whether or not the fake portent is rewritten to the real portent according to ON/OFF of the special mode. In the case of the "stable state" (special mode ON) at the time of the special rewrite lottery, it is more likely to be rewritten to the main omen than in the case of the "rough wave state" (special mode OFF). Also, when the normal AT lottery is performed in the "stable state" (special mode ON), if the MAP level at that time is "MAP level 1" or "MAP level 2", the normal AT lottery of "MAP level 6" Browse the table. Also, in the case of the "stable state" (special mode ON), the AT lottery during the fake sign is not performed. Also, in the case of the "stable state" (special mode ON), "super BIG bonus" and "freeze" are not won in the AT type lottery (see FIG. 112). Further, when "BIG bonus" is determined as the type of pseudo bonus in the "stable state" (special mode ON), "Table I" is determined as the table type of the consecutive-chan zone section. In addition, in the case of the "stable state" (special mode ON), no forced predictive G number lottery is performed at MAP level 0. That is, at MAP level 0, it is decided not to perform the MAP level 0 time forced precursor entry lottery (see FIG. 89) and not to perform the forced precursor G number lottery.

In the second game machine, the "stable state" (special mode ON) is set at the time of transition to the advantageous section. Then, in the second gaming machine, when the normal section of the advantageous section, the game state is other than the BB inside, the non-premonitory state, and "F_weak choi" is won, the cherry navi lottery is performed. conduct. In the cherry-navi lottery, whether the cherry-navi is won or not is determined according to ON/OFF of the special mode. In the case of the "stable state" (special mode ON) at the time of the Cherry Navi lottery, the winning of Cherry Navi is more likely to be determined than in the case of the "rough wave state" (special mode OFF). When cherry-navi winning is determined by the cherry-navi lottery, information of the stop operation (for example, "27") is displayed on the instruction monitor, and a production pattern different from usual is executed. At this time, a specific stop operation mode corresponding to the information of the stop operation displayed on the instruction monitor (for example, the order of the fourth reel D, the third reel C, the second reel B, and the first reel A; If it is the pressing timing at which a cherry is displayed on the lower stage of the reel D), "NM19" (C_weak Che A) is displayed and two medals are paid out. On the other hand, when the specific stop operation mode is not performed, "NM19" (C_Weak Che A) is not displayed, and one medal is paid out ("NM20" (S_Weak Che B)). , or the display mode of the omission is displayed. In the second gaming machine, "NM19" (C_Weak Che A) is displayed, and when two medals are paid out, the "stable state" (special mode ON) is maintained, and "NM19" (C_ If the weak check A) is not displayed and one medal is paid out, or if no medals are paid out, the state is switched to "rough sea state" (special mode OFF). In addition, in the second game machine, the state (mode) transition is determined depending on whether or not two medals are paid out. The state (mode) transition may be determined depending on whether or not the state (mode) is present.

In this way, in the "stable state" (special mode ON), it is impossible to win "super BIG bonus" or "freeze". If you do, you will be able to earn two medals. Therefore, in the "stable state" (special mode ON), the possibility of the player being able to rapidly increase the game value is reduced, but the game value of the player is less likely to decrease. On the other hand, in the "rough sea state" (special mode OFF), it is possible to win "super BIG bonus" and "freeze", but it is difficult to determine the winning of Cherry Navi, so if you win "F_Weak Che" It is difficult to win two medals. Therefore, in the "rough wave state" (special mode OFF), the possibility that the player can rapidly increase the game value increases, but the game value of the player tends to decrease.

FIG. 117 is a diagram for explaining an effect pattern of a normal scroll effect (at the time of non-winning in Cherry Navi lottery). Also, FIG. 118 is a diagram for explaining the effect pattern of the scroll effect when the cherry-navi lottery is won. As shown in FIG. 117, when the normal (non-winning Cherry Navi lottery) effect pattern of the scroll effect is executed, the scroll is displayed at the left end of the display screen of the main display device 210, and then toward the right end. By opening the scroll, a display suggesting a winning combination is performed. On the other hand, as shown in FIG. 117, when the effect pattern of the scroll effect at the time of winning the cherry navigation lottery is executed, the scroll is displayed at the right end of the display screen of the main display device 210, and then the scroll is displayed toward the left end. When opened, a display suggesting a winning combination is displayed. As a result, a specific stop operation mode is suggested by an effect using the main display device 210 . If the player who notices this indication or display on the instruction monitor desires to maintain the "stable state" (special mode ON), he performs a specific stop operation mode to display "NM19" (C_weak Che A). Also, if the player who notices this suggestion or display on the instruction monitor wishes to switch to the "rough wave state" (special mode OFF), "NM19" (C_weak Che A) is displayed without performing a specific stop operation mode. don't let Moreover, it is preferable that the specific stop operation mode is different from the stop operation mode that the player normally performs. Thus, when the player does not notice the suggestion by the effect of the main display device 210 or the display of the instruction monitor, it can be switched to the "rough sea state" (special mode OFF).

In the second gaming machine, when "F_Weak Chase" is won, "NM19" (C_Weak Chase A) is displayed and two medals are paid out. ” (special mode ON). However, in the gaming machine of the present invention, winning in the cherry-navi lottery may be added to the condition for performing the process of transitioning to the "stable state" (special mode ON). In other words, the internal state may be made transferable when a winning is determined in the cherry-navi lottery. As a result, when the production pattern of the normal scroll production (at the time of non-winning in the cherry navi lottery) is executed, even if "NM19" (C_weak Che A) is displayed by performing a specific stop operation mode, " It is possible to prevent the transition to "stable state" (special mode ON). As a result, it becomes difficult to shift to the "stable state" (special mode ON), and the "stable state" (special mode ON) can be rare.

FIG. 119 is a simplified diagram for explaining the timing of conventional state (mode) transition processing and the timing of state (mode) transition processing of the second gaming machine (present invention). For example, assume that "F_Weak Che" is won in the processing at the time of the 1G lever shown in FIG. In the conventional 1G reel full stop processing, the number of payouts is detected, and if "NM19" (C_Weak Che A) is displayed and two medals are paid out, a flag related to the special mode is set. Turn ON. On the other hand, if "NM19" (C_Weak Che A) is not displayed and two medals have not been paid out, the flag associated with the special mode is turned OFF (special mode OFF). Then, in the 2G lever-time processing, it is determined whether or not the flag relating to the special mode is ON, and if the flag relating to the special mode is ON, the transition processing to the "stable state" (special mode ON) is performed. is done. On the other hand, when the flag relating to the special mode is OFF, transition processing to the "rough wave state" (special mode OFF) is performed.

In the processing when the reels of the second gaming machine are fully stopped in the 1G, the ON/OFF of the flag relating to the special mode is not performed. Then, in the 2G lever-time processing, if the 1G (previous) winning combination is "F_Weak Che", the number of payouts is detected, and if two medals have been paid out, a special mode is entered. This flag is turned ON, and transition processing to the "stable state" (special mode ON) is performed. On the other hand, if two medals have not been paid out, the flag relating to the special mode is turned OFF, and transition processing to the "rough wave state" (special mode OFF) is performed. As a result, it is possible to reduce the determination processing and improve the efficiency of the state (mode) transition processing.

In addition, in the second gaming machine, lottery for a pseudo bonus (AT) is performed after the state (mode) transition process. For example, in the case of “rough sea state” (special mode OFF) and “MAP level 1”, the cherry navi lottery is won, “NM19” (C_weak Che A) is displayed, and two medals are paid out. Suppose it was After the transition to the "stable state" (special mode ON) is performed in the processing at the time of the lever of the next game, a pseudo-bonus (AT) lottery is performed. As described above, when performing normal AT lottery in "stable state" (special mode ON), if the MAP level at that time is "MAP level 1" or "MAP level 2", "MAP level 6" The AT lottery table is usually referred to. Therefore, since the current MAP level is "MAP level 1", when the normal AT lottery is performed, the pseudo bonus (AT) lottery is performed with reference to the normal AT lottery table of "MAP level 6". A lottery for a pseudo bonus (AT) may be performed before the state (mode) transition process. For example, in the case of “rough sea state” (special mode OFF) and “MAP level 1”, the cherry navi lottery is won, “NM19” (C_weak Che A) is displayed, and two medals are paid out. Suppose it was If a normal AT lottery is performed in the lever processing of the next game, after referring to the normal AT lottery table of "MAP level 1", a pseudo-bonus (AT) lottery is performed, and then a "stable state" (special mode ON) is performed.

It should be noted that reducing the processing for determining the number of medals to be paid out when the reels are fully stopped, and detecting the number of medals to be paid out in processing at the time of the next lever and executing the processing is not limited to the state transition processing, as in the following modifications. It can be used even in the case of

(Modification 1)
In the non-prediction of the normal section, it is detected whether or not two medals are paid out in the game in which ``F_Weak Che'' is won in the game next to the game in which ``F_Weak Che'' is won, and normal AT lottery is performed. change the table. MAP level is other than "MAP level 5" when it is detected that two medals have been paid out in the game in which "F_Weak Che" has been won in the game following the game in which "F_Weak Che" has been won. , the normal AT lottery is performed by referring to the normal AT lottery table of "MAP level 5", and if the MAP level is "MAP level 5", the normal AT lottery table of "MAP level 5" is used without change. An AT lottery is normally performed with reference to an AT lottery table. Note that the normal AT lottery may be performed by referring to a normal AT lottery table for not only "MAP level 5" but also "MAP level 3" or "MAP level 4". Also, in the game following the game in which "F_Weak Che" was won, if it is detected that two medals were not paid out in the game in which "F_Weak Che" was won, the normal game of "MAP level 6" An AT lottery is normally performed with reference to an AT lottery table.

In addition, in the game following the game in which "F_Weak Che" was won, if it is detected that two or one medals were paid out in the game in which "F_Weak Che" was won, "MAP level 5" Normal AT lottery is performed by referring to the normal AT lottery table, and if it is detected that no medals have been paid out (missed) in the game in which "F_Weak Che" is won, normal AT lottery of "MAP level 6" A normal AT lottery may be performed by referring to a table.

(Modification 2)
In the game next to the game in which "F_Weak Che" is won, it is detected whether or not two medals are paid out in the game in which "F_Weak Che" is won, and whether or not a pseudo bonus (AT) is won is detected. It is determined whether or not to execute the inciting production to incite. When it is detected that two medals are paid out in the game in which ``F_Weak Che'' is won in the game following the game in which ``F_Weak Che'' has been won, the main display device 210 executes a fanning effect. In addition, when it is detected that two medals have not been paid out in the game in which "F_Weak Che" has been won in the game following the game in which "F_Weak Che" has been won, the main display device 210 produces a fanning effect. do not run

In addition, in the game following the game in which "F_Weak Che" was won, when it is detected that two or one medals were paid out in the game in which "F_Weak Che" was won, the main display device 210 is displayed. When it is detected that no medals have been paid out (missed) in a game in which an effect is executed and "F_Weak Che" is won, the main display device 210 may not execute the fanning effect.

Also, the hype effect is not limited to the effect by the main display device 210, and may be the effect by the speakers 35a and 35b, the upper lamp 23, and the like. For example, in the game following the game in which "F_Weak Che" was won, if it is detected that two medals were paid out in the game in which "F_Weak Che" was won, a special start sound different from the normal start sound , and when it is detected that two medals have not been paid out in a game in which "F_Weak Che" has been won, a normal start sound may be played.

In addition, in the game following the game in which "F_Weak Che" was won, if it is detected that two or one medals were paid out in the game in which "F_Weak Che" was won, a special start sound is played. , and when it is detected that no medals have been paid out (lost) in a game in which "F_Weak Che" has been won, a normal start sound may be played.

(Modification 3)
In the "BIG Bonus", the probability of winning the 1G ream varies depending on the internal winning combination. When "1 RB"("F_RB 1 card 01" to "F_RB 1 card 12") is won, the 1G ream is won with a probability of 1/256, and when other internal winning combinations are won, the probability is 0/256.

In the game following the game in which ``F_Weak Che'' has been won, it is detected whether or not two medals have been paid out in the game in which ``F_Weak Che'' has been won, and the probability of winning 1G consecutive is changed. In the game following the game in which "F_Weak Che" was won, if it is detected that two medals were paid out in the game in which "F_Weak Che" was won, the 1G ream is won regardless of the internal winning combination. Change the probability to 128/256. It should be noted that the probability of winning the 1G group may be changed to 256/256 regardless of the internal winning combination. Also, in the game following the game in which "F_Weak Che" was won, if it is detected that two medals were not paid out in the game in which "F_Weak Che" was won, 1G regardless of the internal winning combination. Change the probability of winning a run to 0/256. In addition, if it is detected that two medals were not paid out in the game in which "F_Weak Che" was won in the game following the game in which "F_Weak Che" was won, the probability of winning the 1G run is reduced. You may leave it unchanged.

In addition, in the game following the game in which "F_Weak Che" was won, if it is detected that two or one medals were paid out in the game in which "F_Weak Che" was won, regardless of the internal winning combination The probability of winning the 1G ren is changed to 128/256, and if it is detected that no medals have been paid out (missed) in a game in which ``F_Weak Choi'' has been won, the 1G ren will be won regardless of the internal winning combination. You may make it change the probability to do to 0/256. Incidentally, when it is detected that no medals were paid out (missed) in a game in which "F_Weak Che" was won, the probability of winning the 1G run may not be changed.

[Special rewriting lottery table]
Next, the special rewrite lottery table will be described with reference to FIGS. 120 and 121. FIG. The special rewrite lottery table is referred to for the special rewrite lottery performed in the game in which the fake sign (effect) of the fourth block (151G to 200G) is started, and the lottery results of winning and non-winning are determined for each set value. Specifies value information. The probability denominator of the lottery values shown in FIGS. 120 and 121 is "256".

FIG. 120 is a special rewrite lottery table referred to when the special mode is OFF. As shown in FIG. 120, when the special mode is OFF, the winning of the special rewriting lottery is almost never determined. Therefore, when the special mode is OFF, even if a fake sign (effect) is performed in the fourth block, it is difficult to rewrite to a real sign by a special rewrite lottery. In addition, when the special mode is OFF, an AT lottery is performed during the fake precursor. When the special mode is OFF, the probability of winning the special rewrite lottery is 1/256 regardless of the set value, but it may be 0/256 regardless of the set value. Also, the probability of winning the special rewriting lottery may be changed according to the set value. FIG. 121 is a special rewrite lottery table referred to when the special mode is ON. As shown in FIG. 121, when the special mode is ON, the winning of the special rewrite lottery is almost determined. Therefore, when the special mode is ON, if a fake sign (effect) is performed in the fourth block, it is likely to be rewritten to a real sign by a special rewrite lottery. Note that when the special mode is OFF, the AT lottery during the fake sign is not performed. When the special mode is ON, the probability of not winning the special rewrite lottery is 1/256 regardless of the set value, but it may be 0/256 regardless of the set value. Also, the probability of winning (not winning) in the special rewrite lottery may be changed according to the set value.

[Cherry navi lottery table]
Next, the Cherry Navi lottery table will be described with reference to FIGS. 122 and 123. FIG. The cherry navi lottery table is for the cherry navi lottery performed when the normal section of the advantageous section, the game state is other than the inside of the BB, the non-premonitory state, and "F_Weak Che" is won. It is referred to and defines lottery value information for winning/non-winning lottery results for each set value. The probability denominator of the lottery values shown in FIGS. 122 and 123 is "256".

FIG. 122 is a cherry-navi lottery table referred to when the special mode is OFF. As shown in FIG. 122, when the special mode is OFF, winning in the Cherry Navi lottery is almost never determined. Therefore, when the special mode is OFF, it is difficult to display stop operation information on the instruction monitor, and it is difficult to perform an effect suggesting a specific stop operation mode (see FIG. 118). When the special mode is OFF, the probability of winning the Cherry Navi lottery is 1/256 regardless of the set value, but it may be 0/256 regardless of the set value. Also, the probability of winning the cherry-navi lottery may be changed according to the set value. FIG. 123 is a cherry-navi lottery table referred to when the special mode is ON. As shown in FIG. 123, when the special mode is ON, the winning of the Cherry Navi lottery is almost determined. Therefore, when the special mode is ON, information on the stop operation is likely to be displayed on the instruction monitor, and an effect (see FIG. 118) suggesting a specific stop operation mode is likely to be performed. When the special mode is ON, the probability of not winning the cherry-navi lottery is 1/256 regardless of the set value, but it may be 0/256 regardless of the set value. Also, the probability of winning (not winning) in the cherry-navi lottery may be changed according to the set value.

[Determination of table when transitioning to advantageous section]
As described above, in the second gaming machine, the table type to be used in the normal section is determined in the next game after transition to the advantageous section. Then, the map type is determined according to the table type. Also, the map type defines the MAP level in each block, and in the AT (pseudo-bonus) lottery in the normal section, winning or non-winning is determined according to the MAP level and the winning combination. Therefore, determining the table type in the next game after transitioning to the advantageous section affects subsequent AT (pseudo-bonus) lottery.

When determining the table type to be used in the normal section in the next game after transitioning to the advantageous section, the RT state type at that time is referred to. As the RT state, four types of RT0 state to RT3 state are provided (FIG. 38). The RT0 state is set when initialization is performed by a setting change operation, and the RT1 state transitions when the operation of the bonuses (RB, BB) is completed. The RT2 state is shifted when the bonus (RB, BB) is in progress, and the RT3 state is shifted when the bonus (RB, BB) is in operation. In the next game after transitioning to the advantageous section, if the RT state is the RT0 state, table A is not determined, and tables B to E are determined. In the normal section when table A is determined, the likelihood of determining the pseudo bonus is lower than in the normal section when table B to table E are determined. Therefore, the fact that table A is not determined (that table B to table E are determined) is a privilege for the player. Note that in the RB1 state and the RB2 state, there is a possibility that table A will be determined, and the probability that table A will be determined is higher than the probability that tables B to E will be determined.

As described above, in the second gaming machine, if the non-advantageous section can be shifted to the advantageous section (in the RT0 state) before the bonus (RB, BB) is won, a lottery that is more advantageous than the table A is received. Tables B to E to be used are determined. On the other hand, when the operation of the bonuses (RB, BB) is completed, the state is shifted to RT1 state. Therefore, even if a bonus (RB, BB) is won and activated intentionally just before the end of the advantageous section, the RT state cannot be changed to the RT0 state. As a result, it is possible to prevent a privilege (advantageous lottery) from being received by intentionally changing the game state. In addition, the benefits according to the present invention are not limited to receiving an advantageous lottery. (Bonus) can be set as appropriate, such as increasing the number of games.

In the second game machine, "RB" is "F_Weak Chase", "F_Strong Chase 1", "F_Strong Chase 2", "F_Weak Watermelon 1", "F_Weak Watermelon 2", "F_Strong Watermelon" 1", "F_strong watermelon 2", and "F_batting order BB01" to "F_batting order BB10". In this case, regardless of the stop operation mode, "F_Weak Che", "F_Strong Che 1", "F_Strong Che2", "F_Weak Watermelon 1", "F_Weak Watermelon 2", "F_Strong Watermelon 1" ”, “F_Strong Watermelon 2”, and “F_Battering Order BB01” to “F_Battering Order BB10” are displayed, and the symbol combination regarding “RB” is not displayed (see FIG. 45). As a result, winning of "RB" can be easily avoided.

In the second game machine, when "F_RB 1 card 01" to "F_RB 1 card 12" are won in the RB, when the stop operation is performed in the order of pressing the correct answer, "F_RB 1 card 01" to "F_RB 1 card 12" are won. " is displayed (see FIG. 47). On the other hand, if the stop operation is not performed in the correct order, the symbol combination of "RB" may be displayed depending on the timing of the stop operation. Therefore, in the second gaming machine, when "F_RB 1 sheet 01" to "F_RB 1 sheet 12" are won inside the RB and during the advantageous section, the correct pressing order is notified by the main display device 210 or the like. As a result, it is possible to maintain the inside of the RB (during carryover).

In the second gaming machine, when the RT state in the next game after transition to the advantageous section is the RT0 state, the table type is determined regardless of the setting value (see FIG. 54). As a result, in the RT0 state, the table B to table E can be determined without being affected by the set values, and the award of benefits can be prevented from being unfair. Also, in the second gaming machine, when the RT state in the next game after transitioning to the advantageous section is other than the RT0 state (RT1 state, RT2 state), the table type is determined according to the set value (see FIG. 55). As a result, when the state is other than the RT0 state (RT1 state, RT2 state), the probability of table A to table E being determined can be varied according to the set value, and the determined table type can be predicted from the game state. can be made difficult.

[Processing to refer to the number of payouts]
In the second game, when the reels 3A to 3D are all stopped in the game in which "F_Weak Che" is won, the ON/OFF of the flag relating to the special mode is not performed. Then, in the game next to the game in which "F_Weak Che" was won, it is determined whether or not two medals have been paid out in the previous game, and if two medals have been paid out, a special A flag related to the mode is turned ON, and transition processing to the "stable state" (special mode ON) is performed. On the other hand, if two medals have not been paid out, the flag relating to the special mode is turned OFF, and transition processing to the "rough wave state" (special mode OFF) is performed. As a result, it is possible to reduce the judgment processing of whether or not the flag related to the special mode is ON, which is conventionally performed, and to reduce the judgment processing in the game in which "F_Weak Che" is won. As a result, the efficiency of state (mode) transition processing can be improved.

If you win "F_ weak Che", a specific stop operation mode (for example, the order of the 4th reel D, the 3rd reel C, the 2nd reel B, the 1st reel A, and the lower row of the 4th reel D If it is the pressing timing at which a cherry is displayed), "NM19" (C_weak Che A) is displayed and two medals are paid out. Also, when the specific stop operation mode is not performed, "NM20" (S_Weak Che B) is displayed and one medal is paid out, or the display mode of missing is displayed. Thereby, it is possible to select a transition state (mode) depending on the stop operation mode. In addition, it is possible to vary the easiness of medal depletion according to the mode of the stop operation. Also, in the second gaming machine, it is possible to display "NM20" (S_Weak Che B) when the specific stop operation mode is not performed. Therefore, by confirming whether the display mode is "NM19" (C_Weak Chess A) or "NM20" (S_Weak Chess B), it is possible for the player to recognize the state (mode) transition destination. can.

In the second gaming machine, when transition processing to the "stable state" (special mode ON) is performed, the normal AT lottery table of MAP level 6 is referred to, and the pseudo-bonus winning rate becomes "extremely low". Therefore, by performing transition processing to "stable state" (special mode ON) and "rough sea state" (special mode OFF), the probability of the transition lottery to AT (pseudo bonus) can be varied, and AT ( The transition lottery to the pseudo bonus) can be diversified. In addition, in the second gaming machine, when the cherry-navi lottery is determined by the cherry-navi lottery, information of the stop operation (for example, "27") is displayed on the instruction monitor. Thus, it is possible to suggest that the "F_Weak Che" has been won by using the display of the instruction monitor. In addition, in the second game machine, when a cherry navigator win is determined by the cherry navigator lottery, the production mode (drawing pattern) of the scroll production is set to be different from the normal production mode. As a result, the fact that "F_weak choi" has been won can be indicated in a manner different from the normal scroll presentation.

In the second gaming machine, the probability that Cherry Navi is won by the Cherry Navi lottery in the "stable state" (special mode ON) is determined by the Cherry Navi lottery in the "rough wave state" (special mode OFF). is determined (see FIGS. 122 and 123). As a result, when it is in the "stable state" (special mode ON), it is easier to suggest that "F_weak" has been determined, and it is possible to maintain the "stable state" (special mode ON). become easier. On the other hand, in the case of "rough sea state" (special mode OFF), it is difficult to suggest that "F_weak" has been determined, and from "rough sea state" (special mode OFF) to "stable state" ( It becomes difficult to shift to the special mode ON). In addition, in the second gaming machine, the lottery for shifting to the pseudo bonus (AT) is given preferential treatment in the "rough wave state" (special mode OFF) than in the "stable state" (special mode ON). As a result, the "rough sea state" (special mode OFF) can be set to a state in which the player's medals are likely to decrease, although the possibility of increasing the number of medals increases.

The transition processing to the "stable state" (special mode ON) in the second game machine corresponds to the first processing according to the present invention, and the transition processing to the "rough wave state" (special mode OFF) corresponds to the present invention. This corresponds to the second processing. However, the first processing and the second processing according to the present invention are not limited to transition processing to the "stable state" and "rough sea state". The first process and the second process according to the present invention can be appropriately set as long as they are the main processes that control the game. AT lottery, etc.), a process of giving game-related points, a process of changing management information (eg, table A to table E) and advantage information (eg, map type). Further, in the second gaming machine, processing is performed both when two medals are paid out and when two medals are not paid out in the game in which "F_Weak Che" is won. made it However, in the gaming machine of the present invention, the main processing for controlling the game may be performed in the case of one determination result, and the main processing for controlling the game may not be performed in the case of the other determination result.

[Number of remaining games in the advantageous section and table determination]
In the second gaming machine, the table F to be used in the continuous zone section is determined when the remaining period (number of games played) of the advantageous section is equal to or longer than a predetermined period. On the other hand, the table G is determined when the remaining period (number of games played) of the advantageous section is less than the predetermined period. As shown in FIGS. 85 and 86 , in the Ren-chan zone map lottery, for example, “Ren_Normal D” and “Ren_Normal D” and “Ren_Normal D” with a higher expectation of transition to the pseudo bonus (AT) than “Ren_Normal D” Usually F" can be won. Then, when the table G is determined in the continuous chan zone section, the "continuous_normal F" is more likely to be determined than when the table F is determined. Therefore, when the table G is determined, it is easier to win (shift to) the pseudo bonus earlier than when the table F is determined. When the remaining period (number of games played) of the advantageous interval is less than the predetermined period, the table G is determined so that the pseudo bonus is won relatively earlier than when the table F is determined. As a result, it is possible to shorten the continuous zone section (the section in which the number of medals decreases) between the pseudo-bonus sections in which medals increase and the pseudo-bonus section, thereby relieving the dissatisfaction of the player.

In the second gaming machine, when "BIG bonus", "super BIG bonus", or "freeze" is determined as the pseudo-bonus type, the table used in the consecutive-chan zone section that starts after the pseudo-bonus section ends. Determine the type. As a result, the type of table used in the consecutive-chan zone section is determined before the consecutive-chan zone section is started. As a result, the management information can be used from the first game in the consecutive-chan zone section. In addition, in the second gaming machine, the map type is determined according to the table type in the consecutive Changthorn section. The map type defines the MAP level in each block. Then, in the AT (pseudo-bonus) lottery in the continuous Changthorn section, winning or non-winning is determined according to the MAP level and the winning combination. As a result, it is possible to diversify the lottery for transition to the pseudo bonus (AT) in the continuous Changthorn section. Further, in the second gaming machine, since the degree of expectation for shifting to the pseudo bonus (AT) differs depending on the map type, it is possible to diversify the degree of expectation for shifting and improve the interest of the game.

In the second gaming machine, the probability that a map type with a high degree of expectation for shifting to a pseudo bonus (AT) (for example, "continuous_normal F") is determined differs depending on the set value. As a result, it is possible to vary the degree of expectation for the transition to the pseudo bonus (AT) according to the set value, thereby improving the interest in the game.

[Appendix 1]
In a conventional game machine, a non-advantageous section and an advantageous section can be set, an AT state can be set in the advantageous section, and a transition from the advantageous section to the non-advantageous section is performed when a predetermined end condition is satisfied. is known (see, for example, JP-A-2017-185099).

In such a game machine, when a non-advantageous section is shifted to an advantageous section, it is determined whether or not the game state is in the bonus state or in the general state, and whether or not an advantageous lottery can be accepted is determined. . For example, when the setting is changed, the bonus flag is initialized, and if the non-advantageous section can be shifted to the advantageous section before the bonus is won, an advantageous lottery can be received. However, by intentionally awarding a bonus just before the end of the advantageous section, dissipating the bonus, changing the game state to normal, and then shifting to the advantageous section, you can receive an advantageous lottery even when the setting is not changed. There is a problem that the

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and provides a game machine that prevents an advantageous lottery (privilege) from being received by intentionally winning a bonus just before the end of an advantageous section. for the purpose.

internal winning combination determination means (for example, the main CPU 101 that performs internal lottery processing) that determines an internal winning combination with a predetermined probability;
Variable display means (for example, reels 8A to 8D) configured by a plurality of display columns and variably displaying symbols necessary for a game;
stop operation detection means (for example, stop switch 8S) for detecting a stop operation by the player;
stop control means (for example, main CPU 101 for performing reel stop control processing) for stopping the variable display of symbols based on the determination result of the internal winning combination determination means and the detection of the stop operation by the stop operation detection means;
an informing means (for example, the main display device 210) capable of informing a stop operation mode that is advantageous to the player;
Section control means (for example, game state transition) for controlling the transition between a non-advantageous section in which the notification of the stop operation mode by the notification means is not possible and an advantageous section in which the notification of the stop operation mode is possible by the notification means A main CPU 101) that performs
The internal winning combination determination means can determine a special combination (for example, RB) that can be carried over,
As types of game states, a first state (for example, RT0 state) in which the special role is not carried over, a second state (for example, RT2 state) in which the special role is carried over, and a combination of symbols related to the special role. A third state (for example, RT1 state) that is shifted after a special game started by derivation,
Privilege determination means ( For example, a gaming machine further comprising a main CPU 101 that performs table type lottery with reference to a table type lottery table (in RT0).
According to such a gaming machine, it is possible to receive a privilege (advantageous lottery) by intentionally winning a special role ("RB") immediately before the end of the advantageous section to transition the game state. can be prevented. Further, when it is decided to shift from a non-advantageous section to an advantageous section in a specific game state, a state can be set in which a privilege is given to the player.

When the transition from the non-advantageous section to the advantageous section is determined, if the gaming state is the first state, the privilege is given more than when the gaming state is the third state The above game machine characterized by a high percentage of
According to such a gaming machine, even if the game state is changed to the third state by intentionally winning a special role (“RB”) immediately before the end of the advantageous section, the privilege (advantageous Lottery) will be less likely to be received. Therefore, by intentionally changing the game state immediately before the end of the advantageous section, it is not possible to increase the rate at which a privilege (advantageous lottery) can be received than in the first state. Further, when it is determined in the first state that the non-advantageous section is shifted to the advantageous section, the rate at which the player is awarded the privilege can be made higher than in the third state.

The above game machine, wherein the special combination can be won in duplicate with a specific combination (for example, "F_batting order BB01" to "F_batting order BB10").
According to such a gaming machine, in a game in which a special combination has been won, it is possible to display a symbol combination relating to a specific combination, so that the second state in which the special combination is carried over can be easily achieved.

Equipped with initialization means (for example, setting key switch 52 and reset switch 53) capable of initializing predetermined game information (for example, data in a designated storage area),
The game machine described above is characterized in that the game state is not shifted to the first state until the predetermined game information is initialized by the initialization means.
According to such a gaming machine, when predetermined game information is initialized, it is possible to create a state in which a privilege is given to a player. Therefore, it is possible to prevent frequent granting of the privilege, and increase the value of the privilege.

The above-mentioned game characterized by having a plurality of management information (for example, tables A to E) for managing the determination of whether or not to transition to an advantageous state (for example, pseudo bonus (AT)) that is advantageous to the player. machine.
According to such a gaming machine, it is possible to vary the degree of difficulty of shifting to an advantageous state.

A management information determination means (for example, a main CPU 101 that performs table type lottery) for determining one management information from the plurality of management information,
The management information determination means determines the type of the management information by referring to the type of the game state when a next game start operation is performed after shifting from the non-advantageous section to the advantageous section. A game machine as described above.
According to such a gaming machine, determining the type of management information can correspond to determining whether or not to give a privilege.

The gaming machine as described above, wherein the privilege is that predetermined management information (for example, table A) with a low expectation of transition to the advantageous state is not selected.
According to such a gaming machine, the degree of expectation for transition to an advantageous state can be varied according to the type of game state when a transition from a non-advantageous section to an advantageous section is determined, thereby increasing the interest of the game. can be enhanced.

When the type of the management information is determined, advantage information determining means (for example, performing a normal map lottery) determines the advantage information (for example, map type) related to the determination of whether to transition to the advantageous state. The gaming machine described above, comprising a main CPU 101).
According to such a gaming machine, it is possible to diversify the degree of expectation for transition to an advantageous state.

The management information determining means determines the type of the management information regardless of the set value indicating the degree of advantage of the player in the game when the transition to the advantageous section is determined in the first state. The above gaming machine characterized by:
According to such a gaming machine, when it is in the first state, it is possible to determine the type of management information corresponding to awarding of a privilege without being influenced by the set value.

In the second state or the third state, when the transition to the advantageous section is determined, the management information determining means determines whether the management information The above game machine, characterized in that it determines the type of the.
According to such a gaming machine, in the case of the second state or the third state, the probability that each piece of management information is determined can be varied according to the setting value, and the type of the determined management information can be changed. It is possible to make it difficult to predict from the game state.

[Appendix 2]
Information advantageous to a player so as to display a symbol combination related to a combination determined as an internal winning combination in a conventional game machine, or to prevent the display of a symbol combination related to the determined combination from being missed. (For example, see Japanese Patent Application Laid-Open No. 2016-104425).

In such gaming machines, in order to enhance the enjoyment of the game, for example, efforts have been made to further diversify the game characteristics related to the granting of an advantageous state (AT (assist time) state), transitions, and the like. However, by diversifying the game, the game may become complicated. As a result, there arises a problem that the main processing for controlling the game is burdened.

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and an object of the present invention is to improve the efficiency of main processing for controlling a game.

internal winning combination determination means (for example, the main CPU 101 that performs internal lottery processing) that determines an internal winning combination with a predetermined probability;
Variable display means (for example, reels 8A to 8D) configured by a plurality of display columns and variably displaying symbols necessary for a game;
stop operation detection means (for example, stop switch 8S) for detecting a stop operation by the player;
stop control means (for example, main CPU 101 for performing reel stop control processing) for stopping the variable display of symbols based on the determination result of the internal winning combination determination means and the detection of the stop operation by the stop operation detection means; with
The internal winning combination determining means uses a specific stopping operation mode (for example, the order of 4th reel D, 3rd reel C, 2nd reel B, 1st reel A, and a cherry is displayed on the lower row of the 4th reel D). When the stop operation is performed at the timing of pressing the ,
When the specific display mode is derived, a specific amount (for example, two) of game value (for example, medals) is given,
When the start operation of the game following the game in which the specific role is determined is performed, different processing (for example, , transition processing to a “stable state” (special mode ON), and transition processing to a “rough wave state” (special mode OFF)).
According to such a gaming machine, in the game subsequent to the game in which the specific combination has been determined, the determination process is performed based on the amount of game value given in the game in which the specific combination has been determined, so that the specific combination is determined. It is possible to reduce the judgment processing in the game. As a result, the efficiency of the main processing for controlling the game can be improved.

The gaming machine as described above, wherein a game value equal to or greater than the specific amount is not awarded if the stop operation is not performed in the specific stop operation mode in the game in which the specific combination is determined.
According to such a gaming machine, the easiness of decrease in game value can be made different between when the stop operation is performed in the specific stop operation mode and when the stop operation is not performed in the specific stop operation mode. .

If the game value of the specific amount is given in the game in which the specific role is determined when the start operation of the game next to the game in which the specific role is determined is performed, a first process (for example, Transition processing to a "stable state" (special mode ON)) is executed, and if the specific amount of game value is not awarded in the game in which the specific combination is determined, a second process (for example, "rough sea state") is executed. (transition processing to special mode OFF)).
According to such a gaming machine, it is possible to determine whether to perform the first process or the second process based on whether or not the game value awarded in the game in which the specific combination is determined is the specific amount. can be done.

having a plurality of internal states, including a first state (e.g., "stable state") and a second state (e.g., "rough sea state");
The first process is a process of transitioning to the first state and a process of changing a rate at which transition to an advantageous state is determined,
The gaming machine described above, wherein the second process is a transition process to the second state.
According to such a gaming machine, when a specific amount of game value is awarded in a game in which a specific combination is determined, the rate at which transition to an advantageous state is determined can be changed. migration decisions can be varied. Further, by selecting whether or not to perform a specific stop operation mode, it is possible to select the transition destination of the internal state, thereby making the game more interesting.

The gaming machine described above is characterized in that a predetermined display mode (for example, "NM20" (S_Weak Che B)) can be derived when the specific stop operation mode is not performed.
According to such a gaming machine, by confirming whether it is a specific stop operation mode or a predetermined display mode, it is possible for the player to recognize which process is to be performed thereafter. .

a display means (for example, an instruction monitor) capable of displaying information on the stop operation mode;
a predetermined determination means (for example, the main CPU 101 for performing a cherry-navi lottery) for making a predetermined determination (for example, winning a cherry-navi lottery) when the specific combination is determined;
The gaming machine described above, wherein the display means is capable of displaying information on the stop operation mode when the predetermined determination is made.
According to such a gaming machine, by displaying the predetermined information, it is possible to suggest that the specific combination has been determined.

Equipped with production execution means (for example, main display device 210) capable of executing production,
The production executing means is
When the specific role is determined, a predetermined effect (for example, scroll effect) can be executed,
The gaming machine described above is characterized in that the mode of the predetermined effect is varied depending on whether or not the predetermined determination has been made.
According to such a gaming machine, it is possible to suggest that a specific winning combination has been determined by a predetermined effect mode.

The gaming machine described above is characterized in that the internal state can be shifted when the predetermined determination is made.
According to such a game machine, it is possible to make the transition of the internal state difficult and to make the transition of the internal state rare.

The gaming machine described above, wherein the rate at which the predetermined determination is made differs according to the internal state.
According to such a gaming machine, it is possible to make it easier to shift the internal state or to make it difficult to shift the internal state according to the internal state.

The gaming machine as described above, wherein a rate of making the predetermined decision in the first state is higher than a rate of making the predetermined decision in the second state.
According to such a gaming machine, when it is in the first state, it is easy to suggest that a specific combination has been determined. Therefore, when a specific amount of game value is awarded in a game in which a specific combination has been determined, the first state can be easily maintained when performing processing for shifting to the first state. Also, in the case of the second state, it becomes difficult to suggest that the special combination has been determined. Therefore, when the transition processing to the second state is performed when the specific amount of game value has not been awarded, it is possible to make the transition from the second state to the first state difficult.

The gaming machine described above is characterized in that transition to an advantageous state (for example, pseudo bonus (AT)) is more likely to be determined in the second state than in the first state.
According to such a gaming machine, the second state can be set to a state in which the game value of the player is likely to decrease, although the possibility of increasing the game value increases.

[Appendix 3]
In a conventional gaming machine, a non-advantageous section and an advantageous section are set, an AT state can be set in the advantageous section, and a transition from the advantageous section to the non-advantageous section is performed when a predetermined end condition is satisfied. known (see, for example, Japanese Patent Application Laid-Open No. 2017-185099).

In such an advantageous section of the game, an increase section (pseudo bonus) where an increase in gaming value can be expected by notifying (navigating) the pressing order of the stop operation A game feature is known in which a decreasing section in which the game value decreases is repeated. Also, one of the conditions for ending the advantageous section is, for example, a limiter of 1500 G (game). In the case of the above-described game characteristics, as the number of Gs completed in the advantageous section approaches 1500G, the player becomes dissatisfied with completing the reduced section, which may lead to a decrease in interest in the game.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a gaming machine that can eliminate the dissatisfaction that a player has regarding advantageous sections.

internal winning combination determination means (for example, the main CPU 101 that performs internal lottery processing) that determines an internal winning combination with a predetermined probability;
Variable display means (for example, reels 8A to 8D) configured by a plurality of display columns and variably displaying symbols necessary for a game;
stop operation detection means (for example, stop switch 8S) for detecting a stop operation by the player;
stop control means (for example, main CPU 101 for performing reel stop control processing) for stopping the variable display of symbols based on the determination result of the internal winning combination determination means and the detection of the stop operation by the stop operation detection means;
an informing means (for example, the main display device 210) capable of informing a stop operation mode that is advantageous to the player;
Section control means (for example, game state transition) for controlling the transition between a non-advantageous section in which the notification of the stop operation mode by the notification means is not possible and an advantageous section in which the notification of the stop operation mode is possible by the notification means A main CPU 101) that performs
In the advantageous section, an advantageous state (for example, a pseudo bonus "BIG bonus") in which the game value can be increased by notification of the stop operation mode, and a transition to the stop operation mode after the end of the advantageous state and a predetermined state (for example, continuous chanthorn section) in which it is not possible to increase the gaming value by notification,
The predetermined state is obtained from a plurality of management information (eg, tables F to I) including at least predetermined management information (eg, table F) and specific management information (eg, table G) more advantageous than the predetermined management information. further comprising management information determining means (for example, the main CPU 101 that performs table type lottery) for determining one of the management information used in
The number of games required to transition to the advantageous state when the specific management information is determined is shorter than the number of games required to transition to the advantageous state when the predetermined management information is determined. ,
The gaming machine, wherein the management information determination means determines the specific management information when a predetermined condition (for example, the number of remaining games in the advantageous section is less than a predetermined period) is satisfied.
According to such a gaming machine, when the predetermined condition is satisfied, the predetermined state in which the game value cannot be increased can be shortened. As a result, the period during which the predetermined state is performed can be varied depending on whether or not the predetermined condition is satisfied, and the interest in the game can be enhanced.

The advantageous interval ends when the number of games in the advantageous interval reaches a specified number (for example, 1500);
The gaming machine as described above, wherein the predetermined condition is that the transition to the advantageous state is determined when the number of remaining games in the advantageous section is less than a threshold value (for example, less than 500G).
According to such a gaming machine, it is possible to shorten the predetermined state in which it is not possible to increase the game value when the advantageous section runs short. As a result, it is possible to prevent the period in which the advantageous state can be enjoyed from being shortened, and to eliminate the dissatisfaction of the player.

The advantageous state has at least a first advantageous state (eg, "BIG bonus") and a second advantageous state (eg, "REG bonus");
The predetermined state has at least a first predetermined state (e.g., high probability zone) and a second predetermined state (e.g., consecutive chanson section),
The section control means may be configured such that when the transition to the second advantageous state occurs in the first predetermined state, or the transition to the first advantageous state does not occur in the second predetermined state before reaching a specific period (for example, 100 G). The gaming machine described above is characterized in that, when no determination is made, the advantageous section is shifted to the non-advantageous section.
According to such a gaming machine, when a predetermined condition is satisfied, it is possible to make it easier to determine the transition to the first advantageous state before reaching the specific period.

The gaming machine described above, wherein the predetermined management information and the specific management information are used in the second predetermined state.
According to such a gaming machine, it is possible to shorten the number of games required to transition from the second predetermined state to the first advantageous state when the predetermined condition is satisfied. As a result, even if the number of remaining games in the advantageous section is small, it is possible to secure a period during which the player can enjoy an advantageous state.

The first predetermined state is started when the non-advantageous section transitions to the advantageous section,
The gaming machine described above, wherein the second predetermined state is started after the end of the first advantageous state.
According to such a gaming machine, when a predetermined condition is satisfied, the second predetermined state performed between the first advantageous state in which the game value increases can be shortened, and dissatisfaction felt by the player can be eliminated. be able to.

The management information determining means determines the type of the management information in the second predetermined state after the end of the first advantageous state when the transition to the first advantageous state is determined. The game machine mentioned above.
According to such a gaming machine, since the type of management information is determined before the second predetermined state is started, the management information can be used from the first game in the second predetermined state.

having a plurality of pieces of advantage information (e.g., map type) related to determining whether or not to transition to the advantageous state in the predetermined state;
The gaming machine described above further comprises advantage information determining means (for example, the main CPU 101 that performs a consecutive-chan zone map lottery) that determines one piece of advantage information from a plurality of pieces of advantage information in accordance with the management information.
According to such a gaming machine, it is possible to diversify lottery for transition to an advantageous state in a predetermined state.

The gaming machine described above is characterized in that the degree of expectation for transition to the advantageous state differs according to the type of the advantage information.
According to such a gaming machine, it is possible to diversify the degree of expectation for the transition to the advantageous state in the predetermined state, and to improve the amusement of the game.

The plurality of pieces of advantage information include predetermined advantage information (for example, continuation_normal D) and specific advantage information (for example, continuation_normal F ) and
The gaming machine described above is characterized in that, when the specific management information is determined, the specific advantage information is more likely to be determined than when the predetermined management information is determined.
According to such a gaming machine, when the predetermined condition is satisfied, the specific advantage information can be easily determined, and the degree of expectation for the transition to the advantageous state is higher than when the predetermined condition is not satisfied. be able to.

The gaming machine described above is characterized in that a probability that the advantage information with a high degree of expectation for transition to the advantageous state is determined differs according to a set value.
According to such a gaming machine, it is possible to vary the degree of expectation for transition to an advantageous state according to the set value, thereby enhancing the interest of the game.

[11. Third gaming machine]
Next, referring to FIGS. 124 to 145, another specific example of the control system of the pachi-slot machine will be described as a "third game machine". It should be noted that part or all of the configuration of the control system described as the third gaming machine in the present embodiment can be applied to other gaming machines described in the present embodiment. Part or all of the configuration of the control system described as another game machine in the embodiments can be applied to the third game machine described in this embodiment. In other words, an appropriate combination of these can be used as the invention according to the present embodiment.

[11-1. Configuration of control system of pachislot machine]
First, referring to FIG. 124, the configuration of the control system provided in the third game machine (pachi-slot machine) will be described. FIG. 124 is a block diagram showing the configuration of the control system of the third gaming machine (pachi-slot machine). 124, the same components as those in the control systems of the first and second gaming machines described with reference to FIGS. are denoted by the same reference numerals, and the description of the constituent parts thereof is omitted.

As shown in FIG. 124, the third gaming machine (pachi-slot machine) is connected to the main control unit 600, the sub-control unit 620, and the main control unit 600 by control signal lines (solid arrows in FIG. 124). and a plurality of peripheral devices.

The main control unit 600 is a component for controlling the progress of the game, and has a main control board 601, a reel device board 602 (relay board), and a door relay board 603 (relay board). The internal configuration of each of these substrates will be detailed later.

The main control board 601, the reel device board 602 and the door relay board 603 are connected by an optical fiber cable (double line arrow in FIG. 124). Specifically, the optical communication output connector A provided on the main control board 601 is connected to the optical communication input connector D provided on the reel device board 602 via an optical fiber cable. The optical communication output connector E provided in is connected to the optical communication input connector F provided on the door relay board 603 via an optical fiber cable, and the optical communication output connector G provided on the door relay board 603 is connected to , is connected to an optical communication input connector B provided on the main control board 601 via an optical fiber cable.

The communication between the main control board 601, the reel device board 602, and the door relay board 603 is one-way communication, and the data transmitted from the main control board 601 is transmitted between the reel device board 602 and the door relay board 603. It is transmitted in order and finally transmitted from the door relay board 603 to the main control board 601 . That is, the data transmitted from the main control board 601 circulates through the reel device board 602 and the door relay board 603 in this order and returns to the main control board 601 . Data communication between the boards is synchronous serial communication, and is performed at an interval equal to or less than the periodic interrupt processing period (1 interrupt time: 1.1172 ms) performed by the main CPU (see FIG. 131, which will be described later). carried out in

In addition, in the third game machine, an example in which the main control board 601, the reel device board 602 and the door relay board 603 are connected by an optical fiber cable will be described, but the present invention is not limited to this. A communication cable (harness) may be used to connect between these three boards. In addition, in the third game machine, as described above, the transmission data circulates in this order from the main control board 601 to the reel device board 602 and the door relay board 603, and returns to the main control board 601. However, the present invention is not limited to this, and the configuration is such that the transmission data circulates from the main control board 601 through the door relay board 603 and the drum device board 602 in this order and returns to the main control board 601. good too. In this case, in the block diagram shown in FIG. 124, the direction of the double-line arrow connecting the main control board 601, the drum board 602 and the door relay board 603 (communication direction via the optical fiber cable) is reversed. , the connection mode of the optical fiber cable to each substrate is changed as appropriate.

The sub control unit 620 is a component that controls various production devices (for example, display devices, speakers, lamps, accessories, etc.) (not shown) according to commands from the main control unit 600. It has a control board 622 and a VDP board 623 . The internal configuration of the sub-controller 620 will be detailed later.

In the third game machine, the optical communication output connector C provided on the main control board 601 is connected to the optical communication input connector C provided on the sub relay board 621 via an optical fiber cable (double line arrow in FIG. 124). The communication between the main controller 600 and the sub-controller 620 connected to the connector H is one-way communication from the main controller 600 to the sub-controller 620 . Data communication between the main controller 600 and the sub-controller 620 is asynchronous serial communication. In the third game machine, an example in which the main control unit 600 and the sub-control unit 620 are connected with an optical fiber cable will be described, but the present invention is not limited to this. , the main control unit 600 and the sub control unit 620 may be connected.

The plurality of peripheral devices include the hopper device 32 (including the medal auxiliary storage 33), the setting key switch 52, and the external centralized terminal board 55, which are connected to the main control section 600. In addition, the plurality of peripheral devices include the left reel 3L (first reel), the middle reel 3C (second reel), and the right reel 3R (third reel), which are connected to the reel device board 602. be Further, the plurality of peripheral devices include an information display device 14 (LED status display device), a medal sensor 31S (medal selector), a stop switch 8S (stop switch substrate), a settlement switch 9S ( A settlement button 9), a start switch 7S (start lever 7), an error release switch 57 (reset switch 53), and a door opening/closing monitoring switch 56 are included.

In the third game machine, as shown in FIG. 124, the main control board 601, the reel device board 602, the door relay board 603 and the sub-relay board 621 each include a first HB-LSI (Hybrid-Large Scale Integration) 611, a second HB-LSI 612, a third HB-LSI 613 and a fourth HB-LSI 614 are implemented. Each HB-LSI is an LSI (Application Specific Integrated Circuit (ASIC)) having a plurality of functions such as a communication function, a data port input/output function, a random number generation function, and an LED drive function.

In the third game machine, HB-LSIs having the same configuration (specification) are used as the first HB-LSI 611, the second HB-LSI 612, the third HB-LSI 613, and the fourth HB-LSI 614. FIG. Note that the present invention is not limited to this, and for example, HB-LSIs having different configurations (specifications) may be used for each board depending on the type of board to be mounted.

In the third game machine, the first HB-LSI 611 provided on the main control board 601 is set as a master, and the second HB- The LSI 612 and the third HB-LSI 613 are set as slaves. Further, in the third game machine, communication between the main control unit 600 and the sub-control unit 620 is one-way communication from the main control unit 600 to the sub-control unit 620. The fourth HB-LSI 614 is also set as a slave. The internal configuration of the HB-LSI used in the third gaming machine will be detailed later.

In addition, in the third game machine, the main control unit 600 (main control board 601) is used for the certification test (testing test) of the pachislot machine by the control signal line for the testing test (broken arrow in FIG. 124). It is connected to the tester first interface board 301 (relay board). Further, the main control unit 600 (main control board 601) separates from the first tester interface board 301, depending on the contents of the test, the second interface board 302 for the tester, or the third interface board for the tester. It is connected to board 303 . The second testing machine interface board 302 is a relay board for the maximum ball payout test, and the third testing machine interface board 303 is a relay board for the minimum ball payout test. is not connected to Note that the first tester interface board 301 is connected to the main control unit 600 in any test content.

The control system of the third gaming machine can also be applied to a medalless gaming machine. When the third gaming machine is a medalless gaming machine, the medal count control board 650 is provided as a relay board, The number control board 650 is connected to the main control board 601 of the main control unit 600 by a control signal line (one-dot chain line arrow in FIG. 124). The configuration of the medal count control board 650 and the mode of connection with the main control unit 600 (the dashed-dotted line arrow in FIG. 124) are similar to those of the medal count control board (game value management device) described in the first gaming machine (see FIG. 34). ) are similar to those in

Also, when the third gaming machine is a medalless gaming machine, the medal selector and hopper device 32 (including the medal auxiliary storage 33) are not provided, or even if provided, the main control unit 600 Not connected. Furthermore, when the third gaming machine is a medalless gaming machine, although not shown in FIG. 124, the medal number control board 650 is connected to a game value providing device called "Sand". In this case, a medal count control microprocessor (not shown) for controlling the game value providing device may be provided in the medal count control board 650 or the main control board 601 . In the latter case, the main control board 601 is a dedicated main control board for a medalless game machine on which both the microprocessor 610 for game control and the microprocessor for medal number control are mounted.

[11-2. Configuration of information display device]
Next, a specific configuration example of the information display device 14 used in the third gaming machine will be described with reference to FIGS. 125 and 126. FIG. FIG. 125 is a diagram showing a configuration example of the information display device 14 used when the gaming machine is a normal (non-medalless) gaming machine. FIG. 126 is a diagram showing one configuration example of the information display device 14 used when the gaming machine is a medalless gaming machine.

(Information display device used in ordinary game machines)
As shown in FIG. 125A, the information display device 14 used in an ordinary gaming machine has various lamps (status display lamps) indicating the operation status of the game, such as an "INSERT" lamp, a "START" lamp, and a "REPLAY" lamp. , and lamps for displaying the number of bets marked with "1BET", "2BET" and "3BET". Each status display lamp is composed of one LED (Light Emitting Diode).

The "INSERT" lamp is a lamp that lights up when it is possible to insert medals, the "START" lamp is a lamp that lights up when it is possible to start a game, and the "REPLAY" lamp is a lamp that lights up when a game can be started. This is a lamp that lights up when a replay is possible due to the winning of a replay combination. In addition, the "1BET", "2BET" and "3BET" lamps are displayed according to the number of bets on the gaming value (game medium or accumulated) (the number of bets by inserting the gaming value or pressing the MAX bet button 6a and the 1 bet button 6b). It is a lamp that lights when

Further, the information display device 14 used in an ordinary gaming machine is provided with a 7-digit 7-segment LED (hereinafter referred to as "7-segment LED"). Each 7-segment LED is composed of 7 segments a to g arranged in the manner shown in FIG. 125B.

Of the 7-digit 7-segment LEDs, the lamp composed of 2-digit 7-segment LEDs on the left side of the figure (on the notation of “CREDIT”) indicates the number of accumulated gaming values (credit credit display lamp for digitally displaying (announcing) information such as the number of credits to the player.

Of the 7-digit 7-segment LEDs, the lamp composed of 2-digit 7-segment LEDs on the right side of the figure (on the notation of “PAY”) provides information on the number of payouts (number of awards) of game value to the player. It is a payout display lamp for digital display (notification). The 2-digit 7-segment LED constituting the payout display lamp is also used as an error display lamp for digitally displaying (informing) the player of information on error occurrence and error type.

Also, of the seven-digit seven-segment LEDs, the lamp composed of the three-digit seven-segment LEDs in the middle is stopped as necessary to display the symbol combination corresponding to the determined internal winning combination along the effective line. It is an instruction monitor for announcing operation information. This instruction monitor notifies the player of the necessary stop operation information by lighting, blinking, or extinguishing the 3-digit 7-segment LED in a manner uniquely corresponding to the information of the stop operation to be notified. .

Although the display mode of the stop operation information on the instruction monitor (3-digit 7-segment LED) is arbitrary, for example, the leftmost (3rd digit) of the 3-digit 7-segment LED in FIG. The information displayed by the 7-segment LED located at is information regarding the stop operation of the left reel 3L, and the information displayed by the 7-segment LED located in the center (second digit) is information regarding the stop operation of the middle reel 3C, Information displayed by the rightmost (first digit) 7-segment LED may be information regarding the stop operation of the right reel 3R.

Specifically, when the reels are stopped in the middle reel 3C, the right reel 3R, and the left reel 3L, the 7-segment LED located in the center (second digit) of the instruction monitor (3-digit 7-segment LED) "1" is displayed as information about the stop operation of the middle reel 3C to be the first stop target (suggestion of pressing the stop button 8C), and the 7-segment LED located on the right side (first digit) is the second stop target. "2" is displayed as information regarding the stop operation of the right reel 3R (suggestion of pressing the stop button 8R), and the stop operation of the left reel 3L, which is the third stop target, is displayed on the 7-segment LED located on the left side (third digit). "3" is displayed as information related to (suggestion of pressing the stop button 8L).

Further, for example, using only the 7-segment LED located in the center (second digit) of the instruction monitor (3-digit 7-segment LED), the information regarding the stop operation of the left reel 3L, the middle reel 3C and the right reel 3R is displayed. may be displayed. Specifically, when the 7-segment LED located in the center (second digit) displays, for example, "1", the information regarding the stop operation on the left reel 3L (suggestion of pressing the stop button 8L) is displayed. When "2" is displayed, the information is used as information regarding the stop operation (suggestion of pressing the stop button 8C) for the middle reel 3C, and when "3" is displayed, the information is used for the right reel 3R. This is information about the stop operation (suggestion of pressing the stop button 8R).

(Information display device used in medalless game machines)
The information display device 14 used in the medalless game machine has a status display monitor 14a and an instruction monitor 14b, as shown in FIG. In addition, in the third game machine, the status display monitor 14a and the instruction monitor 14b are arranged separately on the pedestal of the game machine.

The status display monitor 14a is provided with a 'START' lamp, a 'REPLAY' lamp, a '1BET' lamp, a '2BET' lamp and a '3BET' lamp as status display lamps indicating the operation status of the game. Each lamp is composed of one LED (segment). Further, the status display monitor 14a is provided with a 5-digit 7-segment LED for digitally displaying (informing) the player of information such as the number of accumulated game values (the number of credits). The number of payouts (number of awards) of game value is added to the number of credits, and the result of the addition is displayed on a 5-digit 7-segment LED.

The instruction monitor 14b is composed of a 3-digit 7-segment LED, and notifies the information of the stop operation necessary for displaying the symbol combination corresponding to the determined internal winning combination along the activated line. The configuration of the instruction monitor 14b is the same as the configuration of the instruction monitor used in the above-described normal gaming machine, and the configuration of the 7-segment LED for each digit that constitutes the instruction monitor 14b is also the same as that of the normal gaming machine ( 125A).

[11-3. Configuration of HB-LSI]
Next, a configuration example of the HB-LSI (first HB-LSI 611 to fourth HB-LSI 614) used in the third game machine will be described. As described above, the first HB-LSI 611 to the fourth HB-LSI 614 used in the third game machine are LSIs having the same configuration. It is written as LSI700.

FIG. 127 is a block diagram showing the internal configuration of HB-LSI 700. As shown in FIG. As shown in FIG. 127, the HB-LSI 700 (input/output communication means) includes a serial bus communication circuit 701 (first communication section), an asynchronous serial communication circuit 702 (second communication section), and an LED drive circuit 703 (display drive unit), 7-segment character data storage unit 704, PIO (Parallel Input/Output) circuit 705 (signal input/output unit), controller 706, and external bus interface 707 (hereinafter referred to as “external bus I/F ) and a random number generator 708 (random number generator). These units forming the HB-LSI 700 are connected to each other via an internal bus 709 .

(Serial bus communication circuit)
The serial bus communication circuit 701 is a circuit that controls data communication (transmission/reception) operations when synchronous serial bus communication is performed between the board on which the serial bus communication circuit 701 is mounted and an external board. The third game machine adopts a clock-synchronous two-wire (I2C compliant) serial communication method as a synchronous communication method, but adopts a clock-synchronous three-wire (SPI compliant) serial communication method. may be adopted.

The serial bus communication circuit 701 is connected to an “OP_I” terminal (input terminal) and an “OP_O” terminal (output terminal) of the HB-LSI 700 . The "OP_I" terminal (input terminal) can be connected to the optical communication input connector used for synchronous serial communication on the board on which the HB-LSI 700 is mounted, and the "OP_O" terminal (output terminal) is connected to the board. It can be connected to an optical communication output connector used in synchronous serial communication (see FIGS. 131 to 133 described later). For example, when the HB-LSI 700 is the first HB-LSI 611 (master) mounted on the main control board 601, the “OP_I” terminal of the serial bus communication circuit 701 of the first HB-LSI 611 is connected to the main control board 601. It is connected to the communication input connector B, and the "OP_O" terminal is connected to the optical communication output connector A of the main control board 601 (see FIG. 131 described later).

(asynchronous serial communication circuit)
The asynchronous serial communication circuit 702 (UART: Universal Asynchronous Receiver Transmitter) performs data communication (transmission/reception) operation when performing asynchronous serial communication between the board on which the asynchronous serial communication circuit 702 is mounted and an external board. is a circuit that controls Specifically, the asynchronous serial communication circuit 702 mainly performs a process of converting a serial signal into a parallel signal and a signal conversion process in the opposite direction by the asynchronous method. Further, in the third gaming machine, the asynchronous serial communication circuit 702 is capable of transmitting and receiving not only fixed-length data but also variable-length data. The internal configuration and various functions of the asynchronous serial communication circuit 702 will be detailed later.

The asynchronous serial communication circuit 702 is connected to an “O_RX” terminal (receiving terminal) and an “O_TX” terminal (transmitting terminal) of the HB-LSI 700 . The "O_RX" terminal (receiving terminal) can be connected to an optical communication input connector used in asynchronous serial communication on the board on which the HB-LSI 700 is mounted, and the "O_TX" terminal (transmitting terminal) is It can be connected to an optical communication output connector used in asynchronous serial communication (see later-described FIGS. 131 and 134).

In addition, in the third game machine, as described above, asynchronous serial communication is performed between the main control unit 600 (main control board 601) and the sub-control unit 620 (sub-relay board 621). The circuit 702 is used in the first HB-LSI 611 (master) mounted on the main control board 601 and the fourth HB-LSI 614 (slave) mounted on the sub relay board 621 . Therefore, the asynchronous serial communication circuit 702 of the first HB-LSI 611 (master) is connected to the optical communication output connector C (see FIG. 131 described later) of the main control board 601 via the "O_TX" terminal of the first HB-LSI 611. be done. Also, the asynchronous serial communication circuit 702 of the fourth HB-LSI 614 (slave) is connected to the optical communication input connector H of the sub relay board 621 via the "O_RX" terminal of the fourth HB-LSI 614 (see FIG. 134 described later). reference).

(LED drive circuit, 7-segment character data storage unit)
The LED drive circuit 703 is an LED driver circuit for controlling an externally provided LED device (including a 7-segment LED and a lamp composed of one LED). In addition, in the third game machine, the LED drive circuit 703 of the third HB-LSI 613 mounted on the door relay board 603 is connected to the 7-segment LED and status display provided in the information display device 14 connected to the door relay board 603. Used to control the display behavior of the lamp.

The LED drive circuit 703 is connected to the "POa" to "POg" terminals and the "AS0" to "AS15" terminals of the HB-LSI 700, and these terminals are connected to an external LED device to be controlled (third game machine Then, it is connected to the information display device 14). Specifically, the “POa” to “POg” terminals are the cathodes of the segment a to segment g (see FIG. 125B) constituting each 7-segment LED included in the LED device (information display device 14), and each state It is connected to the cathode of the indicator lamp (see FIGS. 125A and 126), and the "AS0" to "AS15" terminals are connected to the anode of each LED (cathode common connection method). Data (character data) corresponding to the form of information (numbers and characters) actually displayed by the 7-segment LED and on/off data for each status display lamp are set to the "POa" to "POg" terminals. A control signal for anode selection when controlling the external 7-segment LED device to be controlled by the dynamic control method is set to the "AS0" to "AS15" terminals. The connection mode between the LED drive circuit 703 of the third HB-LSI 613 and the information display device 14 via the "POa" to "POg" terminals and the "AS0" to "AS15" terminals is that the game machine is a medalless game machine. The connection mode will be described in detail later.

The 7-segment character data storage unit 704 stores the display data acquired by the HB-LSI 700 via the serial bus communication circuit 701 in the form of information (numbers and characters) actually displayed by the 7-segment LED, that is, each 7-segment character data. Data for conversion into character data corresponding to the lighting/light-out state of segments a to g constituting the segment LED is stored. Specifically, display data obtained via the serial bus communication circuit 701 (for example, "7-segment display data" in FIG. 144 described later) and character data corresponding to the actual display mode of the 7-segment LED is stored in the 7-segment character data storage unit 704 .

In the third game machine, the HB-LSI 700 converts the 2-byte display data obtained via the serial bus communication circuit 701 into character data for 2-digit 7-segment LED display. Therefore, in the 7-segment character data storage unit 704, a data table (not shown; hereinafter referred to as , referred to as a “corresponding data table”).

For example, the 2-byte display data "0AH" acquired via the serial bus communication circuit 701 and the character data for displaying the number "10" on the 2-digit 7-segment LED are associated with each other in a correspondence data table. shall be stored in In this case, if the HB-LSI 700 (serial bus communication circuit 701) receives "0AH" as 2-byte display data for the 7-segment LED display, the HB-LSI 700 converts the 2-byte data based on the corresponding data table. The display data is converted into character data for displaying the number "10" on a 2-digit 7-segment LED.

Also, for example, the 2-byte display data "75H" obtained via the serial bus communication circuit 701 and the character data for displaying the characters "EE" on the 2-digit 7-segment LED are associated with each other. It is assumed that it is stored in the data table. In this case, if the HB-LSI 700 (serial bus communication circuit 701) receives "75H" as 2-byte display data for the 7-segment LED display, the HB-LSI 700 converts the 2-byte data based on the corresponding data table. The display data is converted into character data for displaying the characters "EE" on a 2-digit 7-segment LED.

Also, for example, 2-byte display data "01H" obtained via the serial bus communication circuit 701 and "1" (the first digit is "1" and the second digit is "blank") by the two-digit 7-segment LED ) are stored in the corresponding data table in association with the character data for displaying the characters. In this case, if the HB-LSI 700 (serial bus communication circuit 701) receives "01H" as 2-byte display data for the 7-segment LED display, the HB-LSI 700 converts the 2-byte data based on the corresponding data table. The display data is converted into character data for displaying the character "1" on a 2-digit 7-segment LED.

Although not shown in FIG. 127, the HB-LSI 700 stores 2-byte display data (“7-segment display data” and “status display data” in FIG. 144 described later) obtained via the serial bus communication circuit 701. ) are provided. Specifically, the HB-LSI 700 is provided with five 2-byte length first segment registers 0 to 4 and three 2-byte length second segment registers 0 to 2 . Each segment register can store up to two digits of 7 segment LED display data.

The first segment registers 0-4 are mainly segment registers that store 2-byte display data for normal gaming machines, and the second segment registers 0-2 store 2-byte display data for medalless gaming machines. is a seg register. That is, in the third game machine, the HB-LSI 700 is compatible not only with the information display device 14 (see FIG. 125) for a normal game machine, but also with the information display device 14 (see FIG. 126) for a medalless game machine. It has a possible configuration. As will be described later, the first segment registers 2 and 3 are set with display data for controlling the lighting/extinguishing of the instruction monitor included in the information display device 14, and the first segment register 4 is set with the information display device Since the display data for controlling the lighting/extinguishing of each status display lamp (LED) included in 14 is set, the first segment registers 2 to 4 are shared in both normal game machines and medalless game machines. .

Here, the flow from the conversion operation to the 7-segment LED character data to the setting operation of the 7-segment LED character data executed in the third gaming machine will be briefly described. In the third gaming machine, first, display data (2 bytes) for the 7-segment LED acquired via the serial bus communication circuit 701 of the HB-LSI 700 (3rd HB-LSI 613) is stored in the first segment register or the second segment register. set. At this time, if the gaming machine is a normal gaming machine, the display data (2 bytes) for the 7-segment LED obtained via the serial bus communication circuit 701 is set in one of the first segment registers 0 to 3. be done. On the other hand, when the gaming machine is a medalless gaming machine, the display data (2 bytes) for the 7-segment LED obtained via the serial bus communication circuit 701 are the first segment registers 2-3 and the second segment registers 0-2. is set to either

Then, under the control of the controller 706, the display data set in the first segment register or the second segment register is actually displayed by the 7 segment LED based on the corresponding table data stored in the 7 segment character data storage unit 704. converted to character data corresponding to the information (numbers and letters) Then, the converted character data is set to the “POa” to “POg” terminals of the HB-LSI 700 (third HB-LSI 613) via the LED drive circuit 703. FIG. At this time, control signals for anode selection corresponding to the current dynamic control state of the 7-segment LED are set to the "AS0" to "AS15" terminals of the HB-LSI 700. FIG.

(PIO circuit)
The PIO circuit 705 connects “PI0” to “PI15” terminals (input terminals), “PO0” to “PO15” terminals (output terminals), and “S0” to “S2” terminals (address setting input terminals) of the HB-LSI 700 . ) to input and output signals (information) via these terminals.

Terminals "PI0" to "PI15" are terminals used when signals are input to the PIO circuit 705 from peripheral devices (input peripheral devices) such as external devices, switches, and boards. ' terminal is a terminal used when outputting a signal from the PIO circuit 705 to a peripheral device (output peripheral device) such as an external device or a substrate.

Also, the terminals “S0” to “S2” are connected to a 5V power supply or GND (ground). The "S0" terminal is a terminal (main/sub switching terminal) for setting whether the HB-LSI 700 is the LSI of the main control unit 600 (main side) or the LSI of the sub control unit 620 (sub side). When one of the 5V power supply and GND is connected to the "S0" terminal of the HB-LSI 700 on the main side (main setting), the "S0" terminal of the HB-LSI 700 on the sub side is connected to the 5V power supply and GND. The other is connected (sub-configured). "S1" and "S2" terminals are terminals for setting the address of the HB-LSI 700, and the 5V power supply or GND set to "S1" and the 5V power supply or GND set to the "S2" terminal are connected. Address setting is performed by combination.

When the HB-LSI 700 set as a slave outputs the data received by the serial bus communication circuit 701 from the HB-LSI 700 set as a master to a peripheral device, the PIO circuit 705 outputs the data received by the serial bus communication circuit 701. are set to the "PO0" to "PO15" terminals as port output data and output. In addition, in the HB-LSI 700 set as a slave, when data input from a peripheral device via the "PI0" to "PI15" terminals is transmitted to the HB-LSI 700 set as a master, the PIO circuit 705 performs " The data (port input data) input via terminals PI0 to PI15 are set as transmission data of the serial bus communication circuit 701 .

In the third game machine, between the main CPU of the microprocessor 610 and the HB-LSI 700 set as the master (first HB-LSI 611), there is an external bus I/F 707 built in the HB-LSI 700, and a bus to be described later. 606 (including a data bus, an address bus, etc.) and the main CPU via a built-in external bus I/F. Therefore, the main CPU can perform port input/output of data to the “PI0” to “PI15” terminals and “PO0” to “PO15” terminals in the HB-LSI 700 . That is, the main CPU can use the HB-LSI 700 as a PIO circuit.

(controller)
A controller 706 is a control device for controlling the operation (function) of each circuit incorporated in the HB-LSI 700 .

(external bus I/F)
The external bus I/F 707 includes a data bus, an address bus, etc., and is a circuit for performing input/output control of data via a host-side device (main CPU, sub CPU) and a bus. The external bus I/F 707 is connected to terminals “D0” to “D7” and “A0” to “A15” provided in the HB-LSI 700 . The "D0" to "D7" terminals are used to input/output data to/from an external device or the like via the external bus I/F 707, and the "A0" to "A15" terminals are used to This is a terminal used when inputting/outputting address data to/from a device or the like via the external bus I/F 707 .

In this example, the number of terminals (data bus terminals) used for data input/output in the external bus I/F 707 is 8 (input/output terminals for 8 bits). is not limited to this, and for example, the number of terminals (data bus terminals) used for data input/output may be 16 (input/output terminals for 16 bits). Also, here, an example in which the number of terminals (address bus terminals) used for inputting/outputting address data in the external bus I/F 707 is 16 (input/output terminals for 16 bits) has been described. The invention is not limited to this, and for example, the number of terminals (data bus terminals) used for address input/output may be 32 (input/output terminals for 32 bits).

(random number generator)
A random number generator circuit 708 is a circuit for generating a 16-bit random number value. In the third gaming machine, the HB-LSI 700 that uses the random number generation circuit 708 is the first HB-LSI 611 mounted on the main control board 601, and the random number generation circuit 708 of the first HB-LSI 611 has an internal winning combination. Generate random numbers used in lottery. The internal configuration and operation of the random number generation circuit 708 will be detailed later.

(Summary of HB-LSI features)
Each board on the main side of a conventional gaming machine includes an ASIC (master) equipped with a random number generation circuit, a PIO circuit, and a serial bus communication circuit between master and slave, a PIO circuit, a serial bus communication circuit between master and slave, An ASIC (slave) with an LED drive circuit and an ASIC (security LSI) with an asynchronous serial communication circuit (encrypted communication circuit) between the main and sub circuits are separately provided. On the other hand, on each board on the main side of the third gaming machine, as described above, the random number generation circuit 708, the PIO circuit 705, the master-slave serial bus communication circuit 701, the LED drive circuit 703, and the main board. • An inter-sub asynchronous serial communication circuit 702 (capable of handling variable-length data) is mounted in one HB-LSI 700.

That is, in each board on the main side of the third gaming machine, the configuration of the HB-LSI 700 is a configuration in which three types of conventional ASICs are combined into one. In addition, in the third game machine, switching between the master and slave settings of the HB-LSI 700 is performed by a combination of signals (voltages) input to the "S0" to "S2" terminals of the PIO circuit 705 (voltage application mode). done.

[11-3-1. Internal configuration of asynchronous serial communication circuit]
In the third gaming machine, as described above, the asynchronous serial communication circuit 702 incorporated in the HB-LSI 700 is a communication circuit used for communication between main and sub (communication speed: 230400 bps to 460800 bps). Therefore, the asynchronous serial communication circuit 702 is used in the first HB-LSI 611 (master) mounted on the main control board 601 and the fourth HB-LSI 614 (slave) mounted on the sub relay board 621 .

The data (command data) transmitted from the main control unit 600 to the sub control unit 620 by asynchronous serial communication includes various data related to the game situation (“d1” to “dn” in FIG. 137 described later: hereinafter, "Game control data"), data indicating the start of transmission data ("STX (Start of Text)" in FIG. 137 described later: hereinafter referred to as "start data"), and indicating the end of transmission data Data ("ETX (End of Text)" in FIG. 137 to be described later: hereinafter referred to as "end data") and error detection code data for detecting abnormalities that occur with the transfer of game control data (described later "CRC (Cyclic Redundancy Check) 16" in FIG. 137).

Further, in the third gaming machine, a function (data conversion function) of performing DLE (Data Link Escape) control on game control data is provided in generating transmission data (command data). When the game control data is the same as the start data (7EH) or the end data (7FH), DLE control (conversion) is applied to the game control data, and the game control data before conversion is DLE-controlled. (7DH: hereinafter referred to as "DLE data") and the converted game control data. Also, in the third gaming machine, even when the game control data is DLE data (7DH), DLE control (conversion) is performed on the game control data. The configuration of the command data and the contents of the DLE control will be detailed later.

FIG. 128 is a block diagram showing the internal configuration of the asynchronous serial communication circuit 702. As shown in FIG. The asynchronous serial communication circuit 702, as shown in FIG. , a baud rate generation circuit 715, an option addition/check circuit 716, a CRC16 generation/check circuit 717, a transmission data buffer 718 (data buffer), a transmission shift register 719, a reception shift register 720, and a reception data buffer 721. and have

(first data set register, second data set register, data read register)
The first data set register 711 is a register that stores (sets) game control data to be transmitted to the outside, outputs the stored game control data to a transmission data buffer 718, and writes the stored game control data. In the first data set register 711, among a plurality of game control data contained in the game control data group of one packet to be transmitted, the first transmitted game control data (hereinafter referred to as "first game control data") Each game control data up to the game control data transmitted one before the game control data transmitted last (hereinafter referred to as "last game control data") is stored sequentially. The processing of setting the game control data to the first data set register 711 is controlled by the host (the main CPU in the third gaming machine).

The second data set register 712, like the first data set register 711, is also a register that stores game control data to be transmitted to the outside, outputs the stored data to the transmission data buffer 718, and writes it. The second data set register 712 stores the last game control data contained in one packet of game control data group to be transmitted. The process of setting the game control data to the second data set register 712 is controlled by the host (the main CPU in the third gaming machine).

Further, in the third game machine, when the last game control data is stored in the second data set register 712, it is determined that writing of one packet of the game control data group is completed. Therefore, by storing the game control data by the second data set register 712 and writing to the transmission data buffer 718, the data length of the transmitted command data (game control data + start data + end data + error detection code data) Determine. In addition, in the third gaming machine, the data length of one packet of game control data group transmitted and received by the asynchronous serial communication circuit 702 can be made variable, and the maximum data length is 32 bytes.

In the third game machine, a transmission packet data counter (not shown) for storing (counting) the data size of one packet written to the transmission data buffer 718 is provided for the number of packets written to the transmission data buffer 718. be done. And, the transmission packet data counter, when the last game control data is written in the transmission data buffer 718 by the second data set register 712, game control data is written in the transmission data buffer 718 by the first data set register 711 The number of times obtained by adding the number of times (one time) the game control data is written in the transmission data buffer 718 by the second data set register 712 to the number of times (number of bytes) is set. Also, at this time, a transmission packet data counter used for transmission data of one packet to be transmitted next is initialized (set to "0"). For example, when the game control data for 5 packets is written in the transmission data buffer 718, when the data size of 1 packet is set to the 5th transmission packet data counter, the 6th transmission packet data counter Initialized.

Then, the value of the transmission packet data counter is decremented by 1 (updated) each time 1-byte game control data in the corresponding 1-packet transmission data is transmitted. In addition, when the game control data written in the transmission data buffer 718 is the data for DLE control, the value of the transmission packet data counter is not subtracted at the time of transmission of the DLE data, and the game control after the DLE control (conversion) The value of the transmission packet data counter is decremented by one when data is transmitted.

In the third gaming machine, an example in which the minimum size of the game control data group is set to 2 bytes will be explained. A configuration example in which the game control data of the byte is set to the first data set register 711 and written to the transmission data buffer 718, and the game control data of the fifth byte is set to the second data set register 712 and written to the transmission data buffer 718. , but the invention is not limited thereto. For example, the minimum size of the game control data group may be 1 byte. The game control data is set in the 2 data set register 712 and is written in the transmission data buffer 718 .

The data read register 713 is a register that reads and stores (sets) the game control data received from the outside from the reception data buffer 721 . The received data set in the data read register 713 is read by the host (the sub CPU 615 in the third gaming machine).

(Status monitoring circuit)
A status monitoring circuit 714 is a circuit that monitors the communication state of the asynchronous serial communication circuit 702 . Specifically, the status monitor circuit 714 monitors the states of the transmission data buffer 718, the reception data buffer 721, and the like. For example, when all the received data is read from the received data buffer 721, the monitoring result of the presence/absence of received data monitored by the status monitoring circuit 714 becomes null.

The status monitor circuit 714 includes a 1-byte status register T storing various information about the transmission state (transmission operation), and a 1-byte length status register R storing various information about the reception state (reception operation). is provided. The status register T stores various information regarding the state of the transmission data buffer 718 for each bit, and the status register R stores various information regarding the state of the reception data buffer 721 for each bit.

129A and 129B are diagrams showing configurations of status register T and status register R, respectively. In the status register T, as shown in FIG. 129A, information called "buffer ready" is set in bit 0, information called "buffer empty 1" is set in bit 1, and "buffer The information called "empty 2" is set in bit 2, the information called "buffer full" is set in bit 3, the information called "transfer error" is set in bit 4, and the information called "access protected" is set in bit 4. Bit 6 is set to 5, and the information called "active" is set to bit 6. Note that bit 7 of the status register T is unused.

In the third gaming machine, confirmation (reading) and setting (writing) of various information related to the transmission state stored in the status register T can be executed by the main CPU serving as a host for the transmission operation. However, the main CPU can only check (read) bits 0 to 4 in the status register T (see "R/-" notation in FIG. 129A), but bits 5 to 6 can be both checked (read) and set (written) (see "R/W" notation in FIG. 129A).

“Buffer ready” (bit 0) in the status register T stores information on the acceptance state of data transfer (write) to the transmission data buffer 718 . If not ready, '0' (off) is set to 'buffer ready' (bit 0); if ready, '1' (on) is set to 'buffer ready' (bit 0). be done.

"Buffer empty 1" (bit 1) in the status register T stores information on the state of the transmission data buffer 718 (whether it is empty or not). If there is more than 1 packet (or 1 byte) of data in the transmit data buffer 718, "0" (off) is set to "buffer empty 1" (bit 1) and 1 packet (or 1 byte) is in the transmit data buffer 718. 1 byte), a "1" (on) is set to "buffer empty 1" (bit 1).

The "buffer empty 2" (bit 2) in the status register T stores information on the state of the transmission data buffer 718 (whether or not the empty state has passed for a certain period of time (transmission cycle=8 ms) or longer). If there is no space in the transmission data buffer 718 or if a certain period of time has not passed since the transmission data buffer 718 became empty, "0" (off) is set to "buffer empty 2" (bit 2). If a certain period of time has passed since the transmission data buffer 718 became empty, "1" (on) is set to "buffer empty 2" (bit 2). The condition for setting the "buffer empty 2" (bit 2) in the status register T to "1" (on) is that a certain period of time (transmission cycle =8 ms), and the free space of the transmission data buffer 718 is equal to or greater than the maximum number of bytes (32 bytes) of one packet.

“Buffer full” (bit 3) in the status register T stores information as to whether or not the transmission data buffer 718 has an empty space for one or more packets. If there is one or more packets available in the transmit data buffer 718, "0" (off) is set to "buffer full" (bit 3) and there is not one or more packets available in the transmit data buffer 718 (no space is available). 1 packet), then a '1' (on) is set to 'buffer full' (bit 3).

The conditions for setting "buffer full" (bit 3) to "1" (on) include the following various conditions.
(1) When the free space of the transmission data buffer 718 is less than the maximum number of bytes (32 bytes) for one packet (2) When the free space of the transmission data buffer 718 is less than a predetermined number (16 bytes) (3) Send State in which 256 bytes of data has been written to the data buffer 718 (4) When the free space of the transmission data buffer 718 is less than the minimum number of bytes (2 bytes) for one packet

In the third gaming machine, the condition (1) is the condition for setting the buffer full (bit 3) to "1" (on). bits may be assigned to For example, a status register T2 is provided in addition to the status register T, the condition (1) is assigned to bit 0 of the status register T2, the condition (2) is assigned to bit 1, the condition (3) is assigned to bit 2, and the condition (4 ) may be assigned to bit 3. In this case, if any one of the conditions (1) to (4) is satisfied, the "buffer full" (bit 3) of the status register T is set to "1" (on), and then the status register T2 "1" (on) is set in the bit corresponding to the conditions (1) to (4) that have occurred. When adopting such a configuration, for example, the main CPU, even if the "buffer full" (bit 3) in the status register T is set to "1" (on), the size of the game control data to be transmitted is If it is 2 bytes, even if bits 0 (condition 1) to 2 (condition 3) in the status register T2 are set to "1" (on), bit 3 (condition 4) is set to "0" (off). If so, the game control data can be written in the transmission data buffer 718 .

"Transfer error" (bit 4) in the status register T stores information as to whether or not an error has occurred (abnormal transfer) in transferring (writing) data to the transmission data buffer 718. . If there is no transfer anomaly, '0' (off) is set to 'transfer error' (bit 4), and if there is a transfer anomaly, '1' (on) is set to 'transfer error' (bit 4). is set to If the game control data is written while the transmission data buffer 718 is abnormal, a transfer error occurs and the "transfer error" (bit 4) is set to "1" (on). Also, even if there is no abnormality in the transmission data buffer 718, in the state that "1" (on) is set to "access protect" (bit 5) in the status register T, when game control data is written "Transfer Error" (bit 4) is also set to "1" (on).

In the "access protect" (bit 5) in the status register T, the host (the main CPU in the third gaming machine) sets (writes) information on access restriction to the transmission data buffer 718 . If access is not allowed, "0" (off) is set to "access protect" (bit 5), and if access is allowed, "1" (on) is set to "access protect" (bit 5). be done. When the host (main CPU) confirms (reads) whether or not access to the transmission data buffer 718 is possible, the information of "access protect" (bit 5) in the status register T is It is read out by the main CPU in the game machine.

In addition, in the "active" (bit 6) in the status register T, the information indicating whether transmission to the transmission data buffer 718 is valid (transmission canceled) or invalid (transmission prohibited) is stored by the host (the main CPU in the third game machine). ) is set (Write). When transmission is prohibited, "active" (bit 6) is set to "0" (off), and when transmission is canceled, "active" (bit 6) is set to "1" (on). . When the host (main CPU) confirms (reads) whether the transmission to the transmission data buffer 718 is valid or invalid, the information of "active" (bit 6) in the status register T is It is read out by the main CPU in the game machine. Also, the main CPU sets "active" (bit 6) in the status register T to "0" (off) for a certain period of time (the time required to start the sub CPU 615) when the power is turned on (recovery from power failure). Immediately before returning the state of the main control unit 600 to the state before the power failure occurred, the “active” (bit 6) is set to “1” (on) to stabilize the activation of the sub CPU 615 .

As shown in FIG. 129B, in the status register R, information called "buffer ready" is set in bit 0, information called "buffer empty" is set in bit 1, and information called "buffer full" is set in bit 1 as information on the reception state. is set in bit 2, the information called "transmission error" is set in bit 3, the information called "receive error" is set in bit 4, and the information called "access protect" is set in bit 5. set, and the information called "active" is set in bit 6. Note that bit 7 of the status register R is unused.

In the third gaming machine, confirmation (reading) and setting (writing) of various information regarding the reception state stored in the status register R can be executed by the sub CPU 615 serving as a host for the reception operation. However, the sub CPU 615 can only check (read) bits 0 to 4 in the status register R (see "R/-" notation in FIG. 129B), but bits 5 to 6 can be both checked (read) and set (written) (see "R/W" notation in FIG. 129B).

“Buffer ready” (bit 0) in the status register R stores information on the acceptance state of data transfer (writing) to the reception data buffer 721 . If not ready, '0' (off) is set to 'buffer ready' (bit 0); if ready, '1' (on) is set to 'buffer ready' (bit 0). be done.

The "buffer empty" (bit 1) in the status register R stores information on the state of the reception data buffer 721 (whether it is empty or not). If there is more than one packet (or one byte) of data in the receive data buffer 721, "0" (off) is set to "buffer empty" (bit 1) and one packet (or one byte) is left in the receive data buffer 721. byte), a "1" (on) is set to "buffer empty" (bit 1).

“Buffer full” (bit 2) in the status register R stores information as to whether or not the reception data buffer 721 has an empty space for one or more packets. If the reception data buffer 721 has an empty space of one or more packets, "0" (off) is set to "buffer full" (bit 2), and there is no empty space of one packet or more in the reception data buffer 721. 1 packet), then '1' (on) is set to 'buffer full' (bit 2).

"Transfer error" (bit 3) in the status register R stores information as to whether or not an error has occurred in the transfer (write) of data to the reception data buffer 721 (abnormal transfer). . If there is no transfer anomaly, "0" (off) is set to "transfer error" (bit 3), and if there is a transfer anomaly, "1" (on) is set to "transfer error" (bit 3). is set to

The "reception error" (bit 4) in the status register R stores information as to whether or not an error has occurred during reception (abnormal reception). If there is no reception anomaly, "0" (off) is set to "reception error" (bit 4), and if there is a reception anomaly, "1" (on) is set to "reception error" (bit 4). is set to "Receive error" (bit 4) includes, for example, parity errors, framing errors, and overrun errors that can occur each time 1-byte data is received, and errors by the CRC16 check circuit after receiving 1-packet of data. If there are receive anomalies, such as CRC errors, that can be detected, and any one of these receive anomalies occurs, Receive Error (bit 4) is set to '1' (on). If there is no parity error, framing error, or overrun error in all of the received data (game control data) for one packet, the error detection code data (CRC) is checked by a CRC16 check circuit.

"Access protect" (bit 5) in the status register R is set (written) by the host (the sub CPU 615 in the third game machine) to restrict access to the received data buffer 721 . If access is not allowed, "0" (off) is set in "access protect" (bit 5), and if access is allowed, "1" (on) is set in "access protect" (bit 5). be done. When the host (sub CPU 615) confirms (reads) whether or not access to the reception data buffer 721 is possible, the information of "access protect" (bit 5) in the status register R is In the game machine, it is read by the sub CPU 615).

In addition, in the "active" (bit 6) in the status register R, the information indicating whether the reception to the reception data buffer 721 is valid (reception canceled) or invalid (reception inhibited) is stored by the host (sub CPU 615 in the third game machine). ) is set (Write). When reception is prohibited, "active" (bit 6) is set to "0" (off), and when reception is canceled, "active" (bit 6) is set to "1" (on). . When the host (sub CPU 615) confirms (reads) whether transmission to the reception data buffer 721 is valid or invalid, the information of "active" (bit 6) in the status register R In the game machine, it is read by the sub CPU 615).

When the host (sub CPU 615 in the third game machine) sets "active" (bit 6) in the status register R to "0" (off), the terminal "O_RX" receives transmission data from the host. Even if the received data is set to the receive shift register 720 , the received data is not written to the receive data buffer 721 even if the received data is set to the receive shift register 720 . Furthermore, in this case, the option check circuit also does not work.

In the third gaming machine, although not shown in FIG. 128, the asynchronous serial communication circuit 702 includes a transmission data counter for counting the number of 1-byte transmission data and a counter for counting the number of 1-byte reception data. A received data counter is provided for counting.

The transmission data counter is incremented by 1 each time 1-byte data is written to the transmission data buffer 718, and 1-byte data is transmitted (data is set in the transmission shift register 719 or data is transmitted from the transmission shift register 719). It is decremented by 1 each time. The main CPU serving as a host can grasp the usage status of the transmission data buffer 718 by referring to the value of the transmission data counter, and can determine whether or not the transmission data buffer 718 has overflowed. The transmission data read from the transmission data buffer 718 is erased from the transmission data buffer 718 at the time it is read (set in the transmission shift register 719).

The reception data counter receives data in 1-byte units (sets data in the reception shift register 720 or receives data in the reception shift register 720), and writes the 1-byte data to the reception data buffer 721. It is incremented, and 1 is subtracted each time data is read from the reception data buffer 721 via the data read register 713 in units of 1 byte. The sub CPU 615 serving as a host can refer to the received data counter to grasp whether or not there is received data in the received data buffer 721, and can determine the presence or absence of received data. The received data read from the received data buffer 721 is erased from the received data buffer 721 at the time it is read.

The transmit data counter is also used to set bits 1 (B1) to 3 (B3) of the status register T (FIG. 129A) to '1' (on) or '0' (off). The data counter is also used to set bit 1 (B1) and bit 2 (B2) of status register R (FIG. 129B) to "1" (on) or "0" (off).

(Baud rate generation circuit)
The baud rate generation circuit 715 divides the frequency of the clock signal (CLK) supplied to the HB-LSI 700 and generates baud rates for transmission and reception from the frequency-divided clock signal. The baud rate generation circuit 715 is also provided with a baud rate setting register T in which the generated baud rate for transmission is set (stored) and a baud rate setting register R in which the generated baud rate for reception is set. The transmission baud rate set in the baud rate setting register T is supplied to the transmission shift register 719 , and the reception baud rate set in the baud rate setting register R is supplied to the reception shift register 720 .

(Option addition/check circuit)
Option grant/check circuitry 716 includes option grant circuitry and option check circuitry.

The option giving circuit gives start data (STX) and end data (ETX) to one packet of game control data group transmitted from the asynchronous serial communication circuit 702 . Further, the option giving circuit performs DLE control (conversion) according to the game control data to generate converted game control data, and gives DLE data (7DH) to the converted game control data. Further, the option giving circuit gives error detection code data (CRC16) generated by a CRC16 generating circuit, which will be described later, to the game control data group of one packet to be transmitted.

The option check circuit checks (determines) the start data (STX) and the end data (ETX) from the data received by the asynchronous serial communication circuit 702 . In addition, the option check circuit checks whether or not the game control data received by the asynchronous serial communication circuit 702 is DLE data (7DH). , the game control data received next to the DLE data (game control data subjected to DLE control (converted)) are restored to the original game control data. Furthermore, when the option check circuit detects error detection code data (CRC16) from the data received by the asynchronous serial communication circuit 702, the option check circuit collates the error detection code data (CRC16) against the CRC16 check circuit described later (error detection). Judgment) Request processing.

(CRC16 generation/check circuit)
The CRC16 generation/check circuit 717 has a CRC16 generation circuit and a CRC16 check circuit.

The CRC16 generation circuit generates 2-byte error detection code data (CRC16: error detection data) using one packet of game control data group to be transmitted (game control data group written in transmission data buffer 718). calculate. In the third gaming machine, as will be described later, when the game control data group includes game control data to be subjected to DLE control, the game control data before DLE control (conversion) is written in the transmission data buffer 718. However, the game control data after DLE control (conversion) is not written. Therefore, in the third gaming machine, the error detection code data (CRC16) is the data before being DLE controlled (converted) even if the game control data group contains game control data to be DLE controlled. It is generated using a game control data group.

In addition, the present invention is not limited to this, and when the game control data group includes game control data to be subject to DLE control, one packet of game control data group (DLE) actually transmitted from the asynchronous serial communication circuit 702 The game control data group including the game control data after control (conversion) and DLE data (7DH: see FIG. 140B described later) may be used to generate error detection code data (CRC16). In addition, error detection code data (CRC16) may be generated including start data (STX) and end data (ETX) as well as one packet of game control data group to be transmitted.

The CRC16 check circuit generates 2-byte error detection code data (CRC16) using the received 1-packet game control data group (game control data written in the reception data buffer 721), and the generated error detection code The data is collated with the received 2-byte error detection code data, and the presence or absence of reception abnormality is set based on the collation result. The CRC16 check circuit sets the "reception error" (bit 4) in the status register R to "1" when a reception abnormality (CRC error) is detected. Even if the CRC16 check circuit does not detect a reception error, if the "reception error" (bit 4) in the status register R is already set to "1", the bit 4 " 1” is retained.

In the third game machine, an example using CRC (Cyclic Redundancy Check) as a method for checking abnormalities that occur with data communication (transfer) will be described, but the present invention is not limited to this, and the game control data group An arbitrary method can be adopted as long as it is a check method capable of detecting a communication abnormality. For example, as a communication abnormality check method, for example, a sum value may be used, or a method using both a CRC and a sum value may be used.

(transmit data buffer, transmit shift register, receive shift register, receive data buffer)
The transmission data buffer 718 stores game control data written via the first data set register 711 and the second data set register 712 by the host (the main CPU in the third game machine). In the third game machine, the transmission data buffer 718 has a capacity of 256 bytes. In addition, the value of the transmission data counter described above is incremented by 1 each time 1-byte game control data is written in the transmission data buffer 718 .

The transmission data buffer 718 does not store the start data (STX), end data (ETX), and error detection code data (CRC16) that are given to the game control data group of one packet to be transmitted. In addition, in the third game machine, the transmission data buffer 718 stores the game control data before the DLE control (conversion), but does not store the DLE data and the game control data after the DLE control (conversion). The game control data to be subjected to DLE control stored in the transmission data buffer 718 is subjected to DLE control by the option adding circuit at the time of transmission of the game control data, and the generated DLE data and the game control data after DLE control (conversion). are set directly in the transmit shift register 719 . Similarly, the start data (STX), end data (ETX), and error detection code data (CRC16) are not stored in the transmission data buffer 718 but are set in the transmission shift register 719 by the option adding circuit.

The transmission shift register 719 is composed of a 1-byte length shift register. Data to be transmitted to the outside by the asynchronous serial communication circuit 702 is set in the transmission shift register 719 . The data set in the transmission shift register 719 is transmitted to the outside via the “O_TX” terminal (transmission terminal) of the HB-LSI 700 to which the asynchronous serial communication circuit 702 is connected.

The receive shift register 720 consists of a 1-byte length shift register. Data received via the “O_RX” terminal (reception terminal) of the HB-LSI 700 to which the asynchronous serial communication circuit 702 is connected is set in the reception shift register 720 .

The reception data buffer 721 stores game control data written by the reception shift register 720 . In the third gaming machine, the capacity of the received data buffer 721 is assumed to be 256 bytes.

The received data buffer 721 does not store the start data (STX), end data (ETX), and error detection code data (CRC16) added to the game control data group of one packet to be received. Further, in the third gaming machine, the received data buffer 721 does not store the received DLE data and the game control data after the DLE control (conversion). When the reception data set in the reception shift register 720 is DLE data, the next reception data (game control data) of the DLE data is restored to the game control data before DLE control (conversion), and the restored The received game control data is stored in the received data buffer 721 .

In the third game machine, a received packet data counter (not shown) for storing (counting) the data size of one packet written to the received data buffer 721 is provided for the number of packets written to the received data buffer 721. be done. For example, when game control data for 3 packets are written in the reception data buffer 721, 3 reception packet data counters are provided. The reception packet data counter starts counting (“0” is set in the reception packet data counter) at the timing of receiving the start data (STX), and the reception shift register 720 is set with the end data (ETX). At the time point, the number of times (the number of bytes) that the game control data is written is set in the reception data buffer 721 . The above-described transmission data counter, reception data counter, multiple transmission packet data counters, and multiple reception packet data counters are stored in the RAM (not shown) in the HB-LSI 700 or the RAM (not shown) in the asynchronous serial communication circuit 702. ).

(Transmission operation in asynchronous serial communication circuit)
Here, the data transmission operation performed by the asynchronous serial communication circuit 702 will be described. In the third gaming machine, the HB-LSI 700 (first HB-LSI 611) built in the main control unit 600 is used without using the asynchronous serial communication circuit (SCU) built in the main CPU (microprocessor 610). Game control data (command data) is transmitted from the main control unit 600 to the sub control unit 620 .

When data is transmitted from the asynchronous serial communication circuit 702 to the outside, the game control data group (game control data for one packet) set in the transmission data buffer 718 is processed by the option granting circuit for start data (STX), end Data (ETX) and error detection code data (CRC16) are provided, and DLE control is performed on part of the game control data of the game control data group as necessary. After that, the transmission data is sequentially set in the transmission shift register 719, and the data is transmitted to the outside (the sub-control section 620 in the third game machine).

Specifically, first, at the start of transmission, before transmitting the first game control data stored in the transmission data buffer 718, the option addition circuit sets the start data (STX) in the transmission shift register 719 and transmits it. do. Next, the option addition circuit sets the error detection code data (CRC16) generated by the CRC16 generation circuit in the transmission shift register 719 and transmits it.

Then, the game control data are set in the transmission shift register 719 and transmitted sequentially from the first game control data stored in the transmission data buffer 718 (according to the transmission order). At this time, if the game control data in the transmission data buffer 718 is any of the DLE data (7DH), the start data (7EH) and the end data (7FH), the option giving circuit responds to the game control data. DLE control (conversion) is performed, the DLE data is set in the transmission shift register 719 and transmitted, and then the game control data after the DLE control (conversion) is set in the transmission shift register 719 and transmitted.

Then, the last game control data is stored in the transmission data buffer 718 (the value of the corresponding transmission packet data counter changes from "1" to "0"), and the last game control data is set in the transmission shift register 719. After the transmission, the option adding circuit sets the end data (ETX) in the transmission shift register 719 and transmits it.

In addition, when the game control data group of one packet or more is stored in the transmission data buffer 718, at intervals of 8 ms, the game control data is transmitted in units of one packet in the order stored in the transmission data buffer 718 by the transmission operation described above. Groups (command data) are sent.

(Receive operation in asynchronous serial communication circuit)
Next, the data receiving operation performed by the asynchronous serial communication circuit 702 will be described. When data is received by the asynchronous serial communication circuit 702 , data type check processing (discrimination processing) is performed on the received data set in the reception shift register 720 . In this check process, if the received data is game control data, the game control data is written in the received data buffer 721 (the values of the received data counter and the received packet data counter are incremented by 1), but the received data starts In the case of data (STX), end data (ETX) and error detection code data (CRC16), these data are not written to the receive data buffer 721 . Also, at this time, if the reception data set in the reception shift register 720 is DLE-controlled game control data, the restored game control data is written in the reception data buffer 721 .

Specifically, first, at the start of reception, the option check circuit checks whether or not the reception data set in the reception shift register 720 (1 byte reception) is start data (STX). If it is start data (STX), then the CRC16 check circuit acquires the 2-byte received data set in the reception shift register 720 as error detection code data (CRC16).

Then, the reception data set in the reception shift register 720 after the reception of the error detection code data (CRC16) is written in the reception data buffer 721 as game control data. At this time, if the received data set in the reception shift register 720 is DLE data (7DH), the option check circuit performs DLE restoration processing on the next reception data set in the reception shift register 720. , and writes the restored game control data into the reception data buffer 721 .

Then, when the option check circuit detects that the reception data set in the reception shift register 720 is the end data (ETX), the CRC16 check circuit generates CRC16 from the game control data group stored in the reception data buffer 721. A circuit is used to generate error-detecting code data (CRC16), and the generated error-detecting code data (CRC16) is compared with the error-detecting code data (CRC16) obtained via the reception shift register 720 .

Next, if the collation result between the generated error detection code data (CRC16) and the received error detection code data (CRC16) is normal, the reception data buffer 721 counted with reception of the start data (STX) as a start trigger. The number of times (number of bytes) of game control data written to is set to the size of one packet, and the size is set in the corresponding received packet data counter. On the other hand, if the collation result is not normal, discard the game control data written in the reception data buffer 721, and set "1" (on) to bit 4 ("reception error") of the status register R (see FIG. 129B). set.

[11-3-2. Internal Configuration of Random Number Generator]
Next, the internal configuration of random number generation circuit 708 provided in HB-LSI 700 will be described. FIG. 130 is a block diagram showing the internal configuration of the random number generation circuit 708. As shown in FIG.

Random number generator 708 includes four 16-bit random number generators (first random number generator 731, second random number generator 732, third random number generator 733, and fourth random number generator 734) as shown in FIG. , a random number circuit selection circuit 735, a random number register 736, a random number latch register 737, and a random number monitoring circuit 738 (random number monitoring unit).

The first random number generating circuit 731, the second random number generating circuit 732, the third random number generating circuit 733, and the fourth random number generating circuit 734 are all circuits that generate 16-bit random numbers. Each random number generating circuit operates according to a clock signal (CLK) externally supplied to the HB-LSI 700, and generates a random number with the cycle of the clock signal. Here, an example in which four 16-bit random number generation circuits (first random number generation circuit 731 to fourth random number generation circuit 734) are provided in one HB-LSI 700 (random number generation circuit 708) will be described. is not limited to this. For example, an even number of 16-bit random number generators such as 2, 8, or 16 may be provided in one HB-LSI 700 (random number generator 708) depending on the mounting space of the HB-LSI 700. .

The random number circuit selection circuit 735 is a circuit that selects one 16-bit random number generator from four 16-bit random number generators (first random number generator 731 to fourth random number generator 734). The random number circuit selection circuit 735 is connected to four 16-bit random number generation circuits (first random number generation circuit 731 to fourth random number generation circuit 734) and a random number register 736. A random value of bits is set in the random number register 736 .

The random number circuit selection circuit 735 is operated by a clock signal (CLK) externally supplied to the HB-LSI 700, and operates four 16-bit random number generation circuits (first random number generation circuit 731 to fourth random number generation circuit 731) at the cycle of the clock signal. The selection switching operation of the generation circuit 734) is performed. Although not shown in FIG. 130, the random number circuit selection circuit 735 is provided with a selection counter that is referred to in the selection switching operation. It is updated within the range of 0 to 65535. Random number circuit selection circuit 735 selects one 16-bit random number generation circuit from four 16-bit random number generation circuits based on the value of the selection counter updated by the clock signal.

The random number register 736 is a 16-bit register, and stores a 16-bit random value generated by one 16-bit random number generator selected by the random number circuit selection circuit 735 .

Random number latch register 737 latches the value of random number register 736 . The random number is latched by writing a random number in the address area in the main RAM (see FIG. 131 described later) assigned to the random number latch register 737, or by writing the address in the main RAM assigned to the random number register 736. By reading, the value of random number register 736 is latched and a random value is obtained from random number register 736 . Also, the latch is released by writing the random number to the address area in the main RAM assigned to the random number latch register 737 . Incidentally, in the third game machine, the random number value (the value of the random number register 736) latched by the random number generating circuit 708 of the first HB-LSI 611 is acquired by the main CPU (obtained in S4 of FIG. 23, etc.), and this random number value is is used in the lottery for the internal winning combination (S64 in FIG. 26, etc.).

A random number monitor circuit 738 monitors the operating state of the random number generator circuit 708 . Specifically, the random number monitoring circuit 738 is connected to four 16-bit random number generating circuits (first random number generating circuit 731 to fourth random number generating circuit 734) and the random number circuit selecting circuit 735, and is connected to four 16-bit random number generating circuits. , the state of the clock signal (CLK) supplied to the four 16-bit random number generators, the selection state of the random number circuit selection circuit 735, and the state (frequency) of the clock signal supplied to the random number circuit selection circuit 735 to monitor.

The random number monitoring circuit 738 is provided with a random number status register, and each bit of the random number status register stores each piece of monitoring information as a status. In the third gaming machine, the main CPU can read the information stored in the random number status register in the first HB-LSI 611 from the main RAM address assigned to the random number status register. The operating state of the random number generation circuit 708 can be grasped.

The random number monitoring circuit 738 includes four 16-bit random number generating circuits (first random number generating circuit 731 to fourth random number generating circuit 734) and a clock generating circuit (not ) is generated by a clock signal generated by a clock generation circuit different from that shown in the figure).

If the source of the clock signal for the random number monitoring circuit 738 is the same as the source of the clock signal for the four 16-bit random number generators and the random number circuit selection circuit 735, then the four 16-bit random number generators and If a clock abnormality occurs in the random number circuit selection circuit 735 and the clock generation circuit stops, the operation of the random number monitoring circuit 738 will also stop. Therefore, the period (frequency) of the clock signal supplied to the random number monitoring circuit 738 may be longer (lower) than the period (frequency) of the clock signal supplied to the four 16-bit random number generators and random number circuit selection circuit 735. good. For example, if the frequency of the clock signal supplied to the four 16-bit random number generation circuits and the random number circuit selection circuit 735 is approximately 9 MHz, the frequency of the clock signal supplied to the random number monitor circuit 738 can be approximately 3 MHz. . Also, the clock generation circuit may be provided in the random number generation circuit 708, or may be configured to supply a clock signal from the outside.

The types of abnormalities that occur in the random number generation circuit 708 include the following.
(1) When the random value generated from the 16-bit random number generator is not updated for a certain period of time or longer (circuit failure)
(2) When the clock signal (CLK) is always counted and the count cannot be updated for a certain period of time (abnormal clock frequency)
(3) When the clock signal (CLK) is always counted and the update of the clock signal count takes a long time equal to or longer than a certain threshold (specific cycle) (decrease in clock signal frequency)

When the above abnormality occurs in the random number generation circuit 708, the abnormality bit and the abnormality history bit in the random number status register are set to ON state ("1"). In addition, the host (the main CPU in the third game machine), when "circuit abnormality" or "clock frequency abnormality" occurs, performs processing corresponding to a serious error (error information "88" or "rr" is displayed), all game operations are stopped, and the power is turned off. On the other hand, the host (the main CPU in the third game machine) waits until the clock signal frequency returns to normal when the "decrease in clock signal frequency" occurs, and restarts the game operation when the frequency returns to normal. . The random number monitoring circuit 738 returns to the off state (“0”) if the frequency returns to normal in the event of “decrease in the clock signal frequency”. is maintained until the power is turned off. Specifically, the host (the main CPU in the third gaming machine) has a fixed cycle (for example, the cycle of periodic interrupt processing performed by the main CPU (1.1172 ms)), or at the start or end of the unit game. At this time, the information of each bit of the random number status register is referred to, and the above-described processing when an abnormality occurs in the random number generation circuit 708 is performed. The present invention is not limited to this. A numerical value may be obtained.

[11-4. Configuration of main control board]
Next, the internal configuration of the main control board 601 will be described. FIG. 131 is a diagram showing the internal configuration of the main control board 601 and the connection relationship between the main control board 601 and external boards and peripheral devices.

As shown in FIG. 131, the main control board 601 includes a microprocessor 610, a first HB-LSI 611, a role ratio monitor device 54 (four-digit 7-segment LED), a test firing test circuit 605, and these parts. It has a connecting bus 606 .

Further, the main control board 601 is provided with an optical communication output connector A, an optical communication input connector B, and an optical communication output connector C that can be connected to an external board using an optical fiber cable. The optical communication output connector A and the optical communication output connector C are electro-optic conversion connectors that convert electrical signals into optical signals and output them, and the optical communication input connector B converts optical signals into electrical signals. It is a photoelectric conversion connector that outputs

The microprocessor 610 (game control means) is a microprocessor with a security function used in conventional gaming machines. Therefore, although the internal configuration of the microprocessor 610 is not detailed here, the microprocessor 610 includes a main CPU (arithmetic processing unit), a main ROM (first storage unit), a main RAM (second storage unit), section), an external bus I/F, a clock circuit, a reset controller, an arithmetic circuit, a random number circuit, a parallel port, an interrupt controller, a timer circuit, a plurality of asynchronous serial communication circuits, and a signal bus connecting these sections with each other. is provided.

The test shot test circuit 605 is a circuit used for a certification test (test shot test) of a pachi-slot machine. The electronic components of the test firing test circuit 605 are mounted on the main control board 601 for application (for certification test), but not mounted on the main control board 601 for release (product version). However, since the same board is used for the main control board 601 for application and for release, the mounting pattern of the electronic parts of the test fire test circuit 605 remains on the main control board 601 for release (product version).

The role ratio monitor device 54 is composed of a 4-digit 7-segment LED and mounted on the main control board 601 . The configuration of the role ratio monitor device 54 is the same as that explained with reference to FIG. 3, and the content displayed by the role ratio monitor device 54 is also the same as that explained in <Example of Accumulated Data> in FIG. , and the description thereof is omitted here. Also, since the configuration of the first HB-LSI 611 is the same as that of the HB-LSI 700 described in FIG. 127, the description of the configuration is omitted here.

Next, the connection relationship between components mounted on the main control board 601 and between each component and external boards and peripheral devices will be described.

(Mode of connection of microprocessor)
Between the microprocessor 610 and the first HB-LSI 611, a bus 606 including an address bus and a data bus connects the internal external bus I/Fs of both, and bidirectional data input/output is performed. The role ratio monitor 54 and the sighting test circuit 605 are connected to a microprocessor 610 via a bus 606 , and the microprocessor 610 can output data to the role ratio monitor 54 and the sighting test circuit 605 . In addition, the test firing test circuit 605 is connected via a control signal line to the first tester interface board 301 (relay board) used for the certification test (testing test) of the pachislot machine. Data can be output to and from the first interface board 301 for use.

The "SCU (Serial Communication Unit) 2_T" terminal (transmission terminal) of the microprocessor 610 connected to a predetermined asynchronous serial communication circuit (not shown) built in the microprocessor 610 It is connected to the second interface board 302 or the third interface board for testing machine 303 via a control signal line. Then, between the microprocessor 610 and the second tester interface board 302 or the third tester interface board 303, asynchronous serial communication is performed from the microprocessor 610 (a predetermined asynchronous serial communication circuit) to the tester. Data is unidirectionally transmitted to the second interface board 302 for the tester or the third interface board 303 for the tester.

Also, when the third game machine is a medalless game machine, the "SCU0_T" terminal (transmission terminal) of the microprocessor 610 connected to a specific asynchronous serial communication circuit (not shown) built in the microprocessor 610 and the "SCU0_R" terminal (receiving terminal) are connected to the medal count control board 650 via the control signal line. Data is bi-directionally transmitted and received between the microprocessor 610 (specific asynchronous serial communication circuit) and the medal number control board 650 by asynchronous serial communication. In addition, when the main control board 601 and the medal number control board 650 are arranged close to each other, or when both boards are connected with a BtoB (Board to Board) connector, an external Data can be input/output by a memory-mapped IO method via an I/F and a bus (including an address bus and a data bus).

(“PO0” to “PO6” terminals of the 1st HB-LSI)
The “PO0” to “PO6” terminals (output terminals) of the first HB-LSI 611 connected to the PIO circuit 705 incorporated in the first HB-LSI 611 are connected to the external common terminal board 55 via control signal lines. Note that the first HB-LSI 611 and the external collective terminal board 55 are actually connected in parallel by seven control signal lines, but in FIG. Lines are indicated by single bold arrows.

Between the PIO circuit 705 built in the first HB-LSI 611 and the external common terminal board 55 , data is output in one direction from the PIO circuit 705 to the external common terminal board 55 . The signals output from the "PO0" to "PO6" terminals of the first HB-LSI 611 are as follows.

A signal output from the "PO0" terminal is a coin insertion signal, which is turned on for a certain period of time according to the bet operation (operation of the MAX bet button 6a, operation of the 1 bet button 6b, and medal insertion operation). If the bet operation is the operation of the 1 bet button 6b or the operation of inserting one medal, a pulse signal that is turned on for a certain period of time is output from the "PO0" terminal each time the bet operation is performed. On the other hand, when the bet operation is an operation on the MAX bet button 6a, a pulse signal corresponding to the number of game values to be newly bet by the operation is output from the "PO0" terminal. For example, when the number of bets is "0" and the number of game values "3" is newly betted by operating the MAX bet button 6a, three pulse signals are sent to the "PO0" terminal at predetermined intervals. For example, when the number of bets is "1" and the number of game values "2" is newly bet by operating the MAX bet button 6a, two pulse signals are output from the "PO0" terminal at a predetermined interval. For example, when the number of bets is "2" and the number of game values "1" is newly bet by operating the MAX bet button 6a, one pulse signal is output from the "PO0" terminal. be.

A signal output from the "PO1" terminal is a medal payout signal, and is a signal output in response to a credit-up operation (an operation of adding the number of credits) and a medal payout operation. Specifically, when a credit-up operation (credit-up operation) and a medal pay-out operation are performed, a pulse signal that is turned on for a certain period of time is output from the "PO1" terminal for the number of payouts (credit-up number). output.

The signal output from the "PO2" terminal is the external signal 1 (a signal indicating the game state of any one of RB, BB and RT), and the signal changes according to the game (ball output) specifications of the gaming machine. . The signal output from the "PO3" terminal is the external signal 2 (a signal indicating the game state of any one of RB, BB and RT), and the signal changes according to the game (ball output) specifications of the gaming machine. . The signal output from the "PO4" terminal is the external signal 3 (a signal indicating the game state of any one of RB, BB and RT), and the signal changes according to the game (ball output) specifications of the gaming machine. .

The types of game states indicated by the external signal 1, the external signal 2, and the external signal 3 output from the "PO2" terminal, the "PO3" terminal, and the "PO4" terminal, respectively, are different from each other. That is, if one predetermined output terminal among the "PO2" terminal, the "PO3" terminal and the "PO4" terminal is set as the output terminal for the signal indicating the gaming state of the RB, one of the remaining two output terminals The output terminal of is set as an output terminal for a signal indicating the gaming state of BB, and the other output terminal is set as an output terminal for a signal indicating the gaming state of RT. In addition, depending on the game (ball output) specifications of the gaming machine, any one of the "PO2" terminal, "PO3" terminal and "PO4" terminal or any two of the output terminals may output a signal indicating the game state. It may be set as an output terminal.

The signal output from the "PO5" terminal is the external signal 4 (security signal or door open signal). When the "PO5" terminal is the output terminal for the security signal, the external signal 4 changes from OFF to ON when the main CPU of the main control unit 600 detects an error, and the "PO5" terminal is the output terminal for the door open signal. , the external signal 4 is turned on (open) or off (closed) according to the state of the door opening/closing monitoring switch 56 . The signal output from the "PO6" terminal is the external signal 5 (security signal or door open signal). When the "PO6" terminal is the output terminal for the security signal, the external signal 5 changes from OFF to ON when the main CPU of the main control unit 600 detects an error, and the "PO6" terminal is the output terminal for the door open signal. , the external signal 5 is turned on (open) or off (closed) according to the state of the door opening/closing monitoring switch 56 .

The types of signals indicated by the external signals 4 and 5 output from the "PO5" terminal and the "PO6" terminal, respectively, are different from each other. That is, one output terminal of the "PO5" terminal and the "PO6" terminal is set as a security signal output terminal, and the other output terminal is set as a door open signal output terminal. In addition, in specifications where the door open signal is included in the security signal, one of the "PO5" and "PO6" terminals is used and the other is unused. In this configuration, when the main CPU of the main control unit 600 detects an error and when the door open/close monitoring switch 56 detects that the door is open (ON), the signal is sent from one of the "PO5" terminal and the "PO6" terminal. The output external signal is turned on.

(“PI0” to “PI2” terminals of the 1st HB-LSI)
The “PI0” terminal (input terminal) of the first HB-LSI 611 connected to the PIO circuit 705 incorporated in the first HB-LSI 611 is connected to the count sensor (not shown) provided in the hopper device 32 via the control signal line. Connected. Note that the count sensor is a sensor for counting medals discharged from the hopper device 32 . The "PI1" terminal (input terminal) of the first HB-LSI 611, which is connected to the PIO circuit 705 built into the first HB-LSI 611, is connected to the medal auxiliary storage box 33 provided near the hopper device 32 via a control signal line. is connected to the medal auxiliary storage switch 33S (see FIG. 3).

Between the PIO circuit 705 built in the first HB-LSI 611 and the hopper device 32 , data is output in one direction from the hopper device 32 to the PIO circuit 705 . Specifically, the count number data counted by the count sensor in the hopper device 32 is input to the "PI0" terminal of the first HB-LSI611, and the medal auxiliary storage box is input to the "PI1" terminal of the first HB-LSI611. A signal detected by the switch 33S is input.

The "PI2" terminal (input terminal) of the first HB-LSI 611 connected to the PIO circuit 705 incorporated in the first HB-LSI 611 is connected to the setting key switch 52 via the control signal line. Between the PIO circuit 705 built in the first HB-LSI 611 and the setting key-type switch 52 , data is output in one direction from the setting key-type switch 52 to the PIO circuit 705 . Specifically, a signal indicating the state (on or off) of the setting key-type switch 52 is input to the “PI2” terminal of the first HB-LSI 611 .

The port input/output of data using the "PO0" to "PO6" terminals and the "PI0" to "PI2" terminals of the first HB-LSI 611 is performed by the main CPU through the bus 606 (address bus and data bus). Execution can be controlled by the memory-mapped IO method via the

(“S0” to “S2” terminals of the first HB-LSI)
The “S0” terminal (main/sub switching terminal) of the first HB-LSI 611 connected to the PIO circuit 705 incorporated in the first HB-LSI 611 is connected to the 5V power supply (turned on), thereby causing the first HB-LSI 611 to is set as main. The “S1” terminal and the “S2” terminal of the first HB-LSI 611 connected to the PIO circuit 705 incorporated in the first HB-LSI 611 are connected to the 5V power supply (turned on), whereby the address of the first HB-LSI 611 is Settings (master settings) are performed. The master setting connection mode for the "S1" terminal and the "S2" terminal can be arbitrarily determined by a designer or the like, and the master setting can be performed in another connection mode (for example, a mode in which all are grounded). good too.

(“OP_O” and “OP_I” terminals of the first HB-LSI)
The “OP_O” terminal (transmission terminal) of the first HB-LSI 611 connected to the serial bus communication circuit 701 incorporated in the first HB-LSI 611 is connected to the optical communication output connector A of the main control board 601 via the control signal line. The optical communication output connector A is connected to the optical communication input connector D of the reel device substrate 602 via an optical fiber cable. That is, the serial bus communication circuit 701 incorporated in the first HB-LSI 611 is connected to the reel device substrate 602 via the optical communication output connector A of the first HB-LSI 611 and the optical fiber cable. Between the main control board 601 and the drum device board 602, transmission data (to be described later) is transmitted from the "OP_O" terminal of the first HB-LSI 611 in the main control board 601 to the drum device board 602 by synchronous serial communication. 144) is transmitted in one direction.

The "OP_I" terminal (receiving terminal) of the first HB-LSI 611 connected to the serial bus communication circuit 701 incorporated in the first HB-LSI 611 is connected to the optical communication input connector B of the main control board 601 via the control signal line. The optical communication input connector B is connected to the optical communication output connector G of the door relay board 603 via an optical fiber cable. That is, the serial bus communication circuit 701 incorporated in the first HB-LSI 611 is connected to the door relay board 603 via the optical communication input connector B of the first HB-LSI 611 and the optical fiber cable. Between the main control board 601 and the door relay board 603, transmission data (described later in FIG. ) are sent in one direction.

(“O_TX” terminal of the first HB-LSI)
The “O_TX” terminal (transmission terminal) of the first HB-LSI 611 connected to the asynchronous serial communication circuit 702 incorporated in the first HB-LSI 611 is connected to the optical communication output connector C of the main control board 601 via the control signal line. The optical communication output connector C is connected to the optical communication input connector H of the sub relay board 621 via an optical fiber cable. That is, the asynchronous serial communication circuit 702 incorporated in the first HB-LSI 611 is connected to the sub relay board 621 via the optical communication output connector C of the first HB-LSI 611 and the optical fiber cable. Between the main control board 601 and the sub-relay board 621, command data (described later in FIG. ) are sent in one direction.

[11-5. Configuration of Spindle Device Board]
Next, the internal configuration of the rotary drum device board 602 will be described. FIG. 132 is a diagram showing the internal configuration of the rotary drum device board 602 and the connection relationship between the rotary drum device board 602 and external boards and peripheral devices.

The drum device board 602 has a second HB-LSI 612 as shown in FIG. The configuration of the second HB-LSI 612 is the same as that of the HB-LSI 700 described with reference to FIG. 127, so description of the configuration is omitted here.

In addition, the rotary drum device board 602 is provided with an optical communication input connector D and an optical communication output connector E that can be connected to an external board using an optical fiber cable. The optical communication input connector D is a photoelectric conversion connector that converts optical signals into electrical signals and outputs them, and the optical communication output connector E is an electrical-optical conversion connector that converts electrical signals into optical signals and outputs them. be.

Further, the reel device board 602 is provided with a driver IC 741 for driving the left reel 3L, a driver IC 742 for driving the middle reel 3C, and a driver IC 743 for driving the right reel 3R. The present invention is not limited to this, and each driver IC may be provided on a reel board (not shown: provided outside reel device board 602) of the corresponding reel.

(“OP_I” and “OP_O” terminals of the second HB-LSI)
The "OP_I" terminal (receiving terminal) of the second HB-LSI 612 connected to the serial bus communication circuit 701 incorporated in the second HB-LSI 612 is connected to the optical communication input connector D of the reel device substrate 602 via a control signal line. The optical communication input connector D is connected to the optical communication output connector A of the main control board 601 via an optical fiber cable. That is, the serial bus communication circuit 701 incorporated in the second HB-LSI 612 is connected to the main control board 601 via the optical communication input connector D of the reel device board 602 and the optical fiber cable. Between the rotary drum device board 602 and the main control board 601, transmission data (to be described later) is transmitted from the main control board 601 to the "OP_I" terminal of the second HB-LSI 612 in the rotary drum device board 602 by synchronous serial communication. 144) is transmitted in one direction.

The “OP_O” terminal (transmission terminal) of the second HB-LSI 612 connected to the serial bus communication circuit 701 incorporated in the second HB-LSI 612 is connected to the optical communication output connector E of the reel device substrate 602 via a control signal line. The optical communication output connector E is connected to the optical communication input connector F of the door relay board 603 via an optical fiber cable. That is, the serial bus communication circuit 701 incorporated in the second HB-LSI 612 is connected to the door relay board 603 via the optical communication output connector E of the reel device board 602 and the optical fiber cable. Between the rotary drum device board 602 and the door relay board 603, transmission data (to be described later) is transmitted from the "OP_O" terminal of the second HB-LSI 612 in the rotary drum device board 602 to the door relay board 603 by synchronous serial communication. 144) is transmitted in one direction.

(“PO0” to “PO6” terminals of the second HB-LSI)
The "PO0" terminal (output terminal) of the second HB-LSI 612 connected to the PIO circuit 705 built into the second HB-LSI 612 is connected to the hopper device 32 (including the medal auxiliary storage 33) via the control signal line. be done. Data is unidirectionally output from the “PO0” terminal of the second HB-LSI 612 to the hopper device 32 between the drum device board 602 and the hopper device 32 .

The data (signal) output from the PIO circuit 705 in the second HB-LSI 612 to the hopper device 32 is a drive signal for driving a motor (not shown) provided for dispensing medals from the hopper device 32. be. The on/off control of this drive signal is performed by the main CPU in the main control board 601 . Specifically, the main CPU turns on the drive signal when performing control to pay out one medal, and turns off the drive signal when it detects that the count sensor (not shown) in the hopper device 32 has counted medals. state. Then, the main CPU repeats the on/off control of the drive signal for the number of medals to be paid out. The main CPU does not repeat the ON/OFF control of this drive signal for the number of payouts of the game value, but turns this drive signal ON when performing control to pay out the first medal, and pays out the last medal. When the payout control is performed, a count sensor (not shown) in the hopper device 32 may detect that the medals have been counted, and the drive signal may be turned off.

In FIG. 132, two control signal lines are connected from the hopper device 32 to the main control board 601. One of the control signal lines is connected to the count sensor (not shown) in the hopper device 32 and the main control board. 601 and the PIO circuit 705. The other control signal line is the medal auxiliary storage box switch 33S (see FIG. 3) of the medal auxiliary box 33 arranged near the hopper device 32. It is a control signal line that connects with the PIO circuit 705 in the main control board 601 .

The "PO1" terminal and "PO2" (output terminal) of the second HB-LSI 612 connected to the PIO circuit 705 built into the second HB-LSI 612 are connected to the driver IC 741 for driving the left reel 3L via the control signal line. The driver IC 741 is connected to the left reel 3L (first reel) via a control signal line. That is, the PIO circuit 705 incorporated in the second HB-LSI 612 is connected to the left reel 3L via the driver IC 741. FIG.

Between the PIO circuit 705 built in the second HB-LSI 612 and the driver IC 741 for driving the left reel 3L, data is output in one direction from the "PO1" and "PO2" terminals of the second HB-LSI 612 to the driver IC 741, Between the driver IC 741 and the left reel 3L, data is output in one direction from the driver IC 741 to the left reel 3L.

The data (signal) output from the PIO circuit 705 of the second HB-LSI 612 to the driver IC 741 via the "PO1" terminal is an A-phase excitation signal for driving the stepping motor 51L of the left reel 3L. ] terminal to the driver IC 741 is a B-phase excitation signal for driving the stepping motor 51L of the left reel 3L. The driver IC 741 for driving the left reel 3L generates an excitation signal of the A-phase (inverted phase) from the input excitation signal of the A-phase, and transmits the excitation signal of the A-phase and the excitation signal of the A-bar phase to the left reel 3L. Output. Further, the driver IC 741 for driving the left reel 3L generates a B-bar phase (inverted phase) excitation signal from the input B-phase excitation signal, and outputs the B-phase excitation signal and the B-bar phase excitation signal to the left reel 3L. Output to 3L. In FIG. 132, for convenience of explanation, only two control signal lines (thick arrows) are shown between the driver IC 741 and the left reel 3L. Since the excitation signals of the phase and the B-bar phase are input in parallel to the left reel 3L, four control signal lines are provided between the driver IC 741 and the left reel 3L.

The "PO3" terminal and "PO4" (output terminal) of the second HB-LSI 612 connected to the PIO circuit 705 built in the second HB-LSI 612 are connected to the driver IC 742 for driving the middle reel 3C via the control signal line. The driver IC 742 is connected to the middle reel 3C (second reel) via a control signal line. That is, the PIO circuit 705 incorporated in the second HB-LSI 612 is connected to the middle reel 3C via the driver IC 742.

Between the PIO circuit 705 built in the second HB-LSI 612 and the driver IC 742 for driving the middle reel 3C, data is output in one direction from the "PO3" and "PO4" terminals of the second HB-LSI 612 to the driver IC 742, Between the driver IC 742 and the middle reel 3C, data is output in one direction from the driver IC 742 to the middle reel 3C.

The data (signal) output from the PIO circuit 705 of the second HB-LSI 612 to the driver IC 742 via the "PO3" terminal is the A-phase excitation signal for driving the stepping motor 51C of the middle reel 3C. ] terminal to the driver IC 742 is a B-phase excitation signal for driving the stepping motor 51C of the middle reel 3C. The driver IC 742 for driving the middle reel 3C generates an A-bar phase (inverted phase) excitation signal from the input A-phase excitation signal, and sends the A-phase excitation signal and the A-bar phase excitation signal to the middle reel 3C. Output. Further, the driver IC 742 for driving the middle reel 3C generates a B-bar phase (inverted phase) excitation signal from the input B-phase excitation signal, and outputs the B-phase excitation signal and the B-bar phase excitation signal to the middle reel 3C. Output to 3C. In FIG. 132, for convenience of explanation, only two control signal lines (thick arrows) are shown between the driver IC 742 and the middle reel 3C. Since the excitation signals of the phase and the B-bar phase are input in parallel to the middle reel 3C, four control signal lines are provided between the driver IC 742 and the middle reel 3C.

The "PO5" terminal and "PO6" (output terminal) of the second HB-LSI 612 connected to the PIO circuit 705 built into the second HB-LSI 612 are connected to the driver IC 743 for driving the right reel 3R via the control signal line. , and the driver IC 743 is connected to the right reel 3R (third reel) via a control signal line. That is, the PIO circuit 705 incorporated in the second HB-LSI 612 is connected to the right reel 3R via the driver IC 743. FIG.

Between the PIO circuit 705 built in the second HB-LSI 612 and the driver IC 743 for driving the right reel 3R, data is output in one direction from the "PO5" and "PO6" terminals of the second HB-LSI 612 to the driver IC 743, Between the driver IC 743 and the right reel 3R, data is output in one direction from the driver IC 743 to the right reel 3R.

The data (signal) output from the PIO circuit 705 of the second HB-LSI 612 to the driver IC 743 via the "PO5" terminal is the A-phase excitation signal for driving the stepping motor 51R of the right reel 3R. ] terminal to the driver IC 743 is a B-phase excitation signal for driving the stepping motor 51R of the right reel 3R. The driver IC 743 for driving the right reel 3R generates an A-bar phase (inverted phase) excitation signal from the input A-phase excitation signal, and transmits the A-phase excitation signal and the A-bar phase excitation signal to the right reel 3R. Output. Further, the driver IC 743 for driving the right reel 3R generates a B-bar phase (inverted phase) excitation signal from the input B-phase excitation signal, and outputs the B-phase excitation signal and the B-bar phase excitation signal to the right reel 3R. Output to 3R. In FIG. 132, for convenience of explanation, only two control signal lines (thick arrows) are shown between the driver IC 743 and the right reel 3R. Since the excitation signals of the phase and the B-bar phase are input in parallel to the right reel 3R, four control signal lines are provided between the driver IC 743 and the right reel 3R.

In the third gaming machine, the stepping motors 51L, 51C, 51R for driving the reels are composed of two-phase excitation stepping motors or one- and two-phase excitation stepping motors. When two-phase excitation stepping motors are employed as the stepping motors 51L, 51C, and 51R, gears are provided on the shafts of the reels, and motor power is transmitted through the gears to rotate and stop the reels. When 1/2-phase excitation type stepping motors are employed as the stepping motors 51L, 51C, and 51R, the reels are rotated and stopped by directly connecting the motors to the reel shafts.

(“PI0” to “PI2” terminals of the second HB-LSI)
The "PI0" terminal (input terminal) of the second HB-LSI 612 connected to the PIO circuit 705 built into the second HB-LSI 612 is connected to the index sensor (not shown) of the left reel 3L via the control signal line. . Between the PIO circuit 705 built in the second HB-LSI 612 and the left reel 3L, data is output in one direction from the index sensor of the left reel 3L to the "PI0" terminal of the second HB-LSI 612. Specifically, the detection signal (on/off signal) of the index sensor of the left reel 3L is input to the “PI0” terminal of the second HB-LSI 612 .

The "PI1" terminal (input terminal) of the second HB-LSI 612 connected to the PIO circuit 705 built in the second HB-LSI 612 is connected to the index sensor (not shown) of the middle reel 3C via the control signal line. . Between the PIO circuit 705 built in the second HB-LSI 612 and the middle reel 3C, data is output in one direction from the index sensor of the middle reel 3C to the "PI1" terminal of the second HB-LSI 612. Specifically, the detection signal (on/off signal) of the index sensor of the middle reel 3C is input to the “PI1” terminal of the second HB-LSI 612 .

The "PI2" terminal (input terminal) of the second HB-LSI 612 connected to the PIO circuit 705 built into the second HB-LSI 612 is connected to the index sensor (not shown) of the right reel 3R via the control signal line. . Between the PIO circuit 705 built in the second HB-LSI 612 and the right reel 3R, data is output in one direction from the index sensor of the right reel 3R to the "PI2" terminal of the second HB-LSI 612. Specifically, the detection signal (on/off signal) of the index sensor of the right reel 3R is input to the “PI2” terminal of the second HB-LSI 612 .

A detection piece (not shown) of an index sensor provided on each reel is arranged on the inner peripheral portion of the reel. There are two types of detection pieces of the index sensor: a piece type and a plate type. In the single type, a small detection piece (width: 5 mm to 10 mm) is formed on the inner periphery of the reel, and the detection signal of the index sensor is turned on only when the detection piece is detected. On the other hand, in the plate type, a substantially fan-shaped detection piece is formed on the inner circumference of the reel. In this case, the detection signal of the index sensor is turned on in the section where the detection piece is formed (the section within the range of 90° to 180°) in the section where the reel rotates once, and the remaining section ( At 360°-(section where the detection piece is formed), the detection signal of the index sensor is turned off.

(“S0” to “S2” terminals of the second HB-LSI)
The “S0” terminal (main/sub switching terminal) of the second HB-LSI 612 connected to the PIO circuit 705 incorporated in the second HB-LSI 612 is connected to the 5V power supply (turned on), whereby the second HB-LSI 612 is set as main. The “S1” terminal and the “S2” terminal of the second HB-LSI 612 connected to the PIO circuit 705 incorporated in the second HB-LSI 612 are grounded (connected to GND) (turned off). address setting (slave setting) is performed.

[11-6. Configuration of Door Relay Board]
Next, the internal configuration of the door relay board 603 will be described. FIG. 133 is a diagram showing the internal configuration of the door relay board 603 and the connection relationship between the door relay board 603 and external boards and peripheral devices.

The door relay board 603 has a third HB-LSI 613 as shown in FIG. The configuration of the third HB-LSI 613 is the same as that of the HB-LSI 700 described with reference to FIG. 127, so the description of the configuration is omitted here.

Further, the door relay board 603 is provided with an optical communication input connector F and an optical communication output connector G that can be connected to an external board using an optical fiber cable. The optical communication input connector F is a photoelectric conversion connector that converts an optical signal into an electrical signal and outputs the signal, and the optical communication output connector G is an electrical/optical conversion connector that converts an electrical signal into an optical signal and outputs the signal. be.

(“OP_I” and “OP_O” terminals of the 3rd HB-LSI)
The "OP_I" terminal (receiving terminal) of the third HB-LSI 613 connected to the serial bus communication circuit 701 incorporated in the third HB-LSI 613 is connected to the optical communication input connector F of the door relay board 603 via the control signal line. The optical communication input connector F is connected to the optical communication output connector E of the reel device substrate 602 via an optical fiber cable. That is, the serial bus communication circuit 701 incorporated in the 3HB-LSI 613 is connected to the reel device substrate 602 via the optical communication input connector F of the 3HB-LSI 613 and the optical fiber cable. Between the door relay board 603 and the rotary drum device board 602, transmission data (to be described later) is transmitted from the rotary drum board 602 to the "OP_I" terminal of the third HB-LSI 613 in the door relay board 603 by synchronous serial communication. 144) is transmitted in one direction.

The "OP_O" terminal (transmission terminal) of the third HB-LSI 613 connected to the serial bus communication circuit 701 incorporated in the third HB-LSI 613 is connected to the optical communication output connector G of the door relay board 603 via the control signal line. The optical communication output connector G is connected to the optical communication input connector B of the main control board 601 via an optical fiber cable. That is, the serial bus communication circuit 701 incorporated in the third HB-LSI 613 is connected to the main control board 601 via the optical communication output connector G and the optical fiber cable. Between the door relay board 603 and the main control board 601, transmission data (described later in FIG. ) are sent in one direction.

(“POa” to “POg” terminals of the 3rd HB-LSI)
The “POa” to “POg” terminals (output terminals) of the third HB-LSI 613 connected to the LED drive circuit 703 incorporated in the third HB-LSI 613 are connected to the information display device 14 via control signal lines. Note that seven control signal lines are actually connected in parallel between the “POa” to “POg” terminals of the third HB-LSI 613 and the information display device 14, but in FIG. One control signal line is indicated by one thick arrow.

The data (signals) output from the "POa" to "POg" terminals of the third HB-LSI 613 connected to the LED drive circuit 703 incorporated in the third HB-LSI 613 constitute each 7-segment LED in the information display device 14. This is a 7-segment control signal for controlling lighting/extinguishing (on/off) of the 7 segments a to g (see FIG. 125B). Specifically, the 7-segment control signal is output from the terminals “POa” to “POg” of the third HB-LSI 613 to the cathodes of the 7 segments a to g forming the 7-segment LED.

The data (signals) output from the "POa" to "POg" terminals of the third HB-LSI 613 are used to turn on/off (on/off) each status display lamp (see FIGS. 125A and 126) in the information display device 14. off) is an LED control signal. In each status display lamp in the information display device 14, the cathode of the "INSERT" lamp is connected to the "POa" terminal, the cathode of the "START" lamp is connected to the "POb" terminal, and the cathode of the "REPLAY" lamp is connected to the "POb" terminal. The "POc" terminal is connected to the "1BET" lamp cathode, the "POd" terminal is connected to the cathode of the "1BET" lamp, the "POe" terminal is connected to the cathode of the "2BET" lamp, and the "POf" terminal is connected to the cathode of the "3BET" lamp. (see FIG. 125A) are connected.

(“AS0” to “AS15” terminals of the 3rd HB-LSI)
The “AS0” to “AS15” terminals (output terminals) of the third HB-LSI 613 connected to the LED drive circuit 703 incorporated in the third HB-LSI 613 are connected to the information display device 14 via control signal lines. Note that 16 control signal lines are actually connected in parallel between the "AS0" to "AS15" terminals of the third HB-LSI 613 and the information display device 14, but in FIG. One control signal line is indicated by one thick arrow.

The data (signals) output from the “AS0” to “AS15” terminals of the third HB-LSI 613 connected to the LED drive circuit 703 incorporated in the third HB-LSI 613 are mainly provided in the information display device 14. Control signal for anode selection for dynamically controlling various 7-segment LEDs. In addition, the output mode of the data (signal) output from the "AS0" to "AS15" terminals of the third HB-LSI 613 depends on the type of gaming machine (regular gaming machine or medalless gaming machine). different. The output modes of the control signals output from the "AS0" to "AS15" terminals are as follows.

First, the case where the gaming machine is a normal gaming machine will be described. In this case, the control signal for anode selection output from the "AS0" terminal is the second digit (tens place) of the credit display lamp (2-digit 7-segment LED: see FIG. 125A) in the information display device 14. Output to the anode of the 7-segment LED. The control signal for anode selection output from the "AS1" terminal is output to the anode of the 7-segment LED of the first digit (one's place) of the credit display lamp in the information display device 14. FIG.

If the game machine is a normal game machine, the control signal for anode selection output from the "AS2" terminal is 2 of the payout display lamp (2-digit 7-segment LED: see FIG. 125A) in the information display device 14. It is output to the anode of the 7-segment LED of the digit (tens place). The control signal for anode selection output from the “AS3” terminal is output to the anode of the 7-segment LED of the first digit (1's digit) of the payout display lamp in the information display device 14 .

If the game machine is a normal game machine, the control signal for anode selection output from the "AS4" terminal is a three-digit display on the instruction monitor (three-digit seven-segment LED: see FIG. 125A) in the information display device 14. It is output to the anode of the 7-segment LED of the eye (left side in FIG. 125A). The anode selection control signal output from the “AS5” terminal is output to the anode of the 7-segment LED on the second digit (center in FIG. 125A) of the instruction monitor in the information display device 14 . The anode selection control signal output from the "AS6" terminal is output to the anode of the 7-segment LED on the first digit (right side in FIG. 125A) of the instruction monitor in the information display device 14. FIG.

The "AS4" to "AS6" terminals are also used in the same way when the gaming machine is a medalless gaming machine. A control signal for is output. In other words, the "AS4" to "AS6" terminals are shared by the instruction monitor for both the normal game machine and the medalless game machine.

When the gaming machine is a normal gaming machine, the control signal output from the "AS7" terminal is applied to each status display lamp ("INSERT", "START", "REPLAY", "1BET") in the information display device 14. , 2BET, 3BET lamps: see FIG. 125A). When the game machine is a normal game machine, the terminals “AS8” to “AS15” are unused.

The "AS7" terminal is also used when the gaming machine is a medalless gaming machine, and each status display lamp ("START", "REPLAY", "1BET", A control signal is output to the anodes of the “2BET” and “3BET” lamps: see FIG. 126). That is, the "AS7" terminal is shared by the status display lamps of both the normal game machine and the medalless game machine.

Next, the case where the gaming machine is a medalless gaming machine will be described. In this case, the control signal for anode selection output from the "AS8" terminal is the first digit (1 digit: output to the anode of the 7-segment LED located on the rightmost side in FIG. 126). The control signal for anode selection output from the “AS9” terminal is output to the anode of the 7-segment LED in the second digit (tenth place) of the 5-digit 7-segment LED in the information display device 14 . The anode selection control signal output from the “AS10” terminal is output to the anode of the 3rd digit (100th place) 7-segment LED among the 5-digit 7-segment LEDs in the information display device 14 . The control signal for anode selection output from the “AS11” terminal is output to the anode of the 7-segment LED in the 4th digit (1000th place) among the 5-digit 7-segment LEDs in the information display device 14 . In addition, the control signal for anode selection output from the "AS12" terminal is the fifth digit (10000 digit) of the 5-digit 7-segment LED in the information display device 14; 7-segment LED) is output to the anode of the 7-segment LED.

Further, when the gaming machine is a medalless gaming machine, as described above, the control signal for anode selection of the 3-digit 7-segment LED (see FIG. 126) of the instruction monitor 14b in the information display device 14 is "AS4". The control signals for the status display lamps (“START”, “REPLAY”, “1BET”, “2BET”, “3BET” lamps: see FIG. 126) in the information display device 14 are output from terminals to “AS6”. , and "AS7" terminals.

When the gaming machine is a medalless gaming machine, the terminals “AS0” to “AS3” and “AS13” to “AS15” are unused. If the gaming machine is a medalless gaming machine, a control signal is output from the "AS13" terminal to each status display lamp ("START", "REPLAY", "1BET", "2BET", "3BET" lamps). Also, in this case, the "AS7" terminal is unused.

(“PO0”, “PI0” to “PI7” terminals of the 3rd HB-LSI)
The "PO0" terminal (output terminal) and the "PI0" terminal (input terminal) of the third HB-LSI 613 connected to the PIO circuit 705 incorporated in the third HB-LSI 613 are connected to the medal sensor 31S (the medal selector). Data is bi-directionally input/output between the third HB-LSI 613 in the door relay board 603 and the medal sensor 31S (medal selector).

The signal output from the "PO0" terminal of the third HB-LSI 613 to the medal sensor 31S is a control signal for a solenoid provided in the medal selector for ON/OFF control of the medal pressure that enables or disables reception of medals. is. On the other hand, the signal input from the medal sensor 31S (medal selector) to the "PI0" terminal of the third HB-LSI 613 is the signal detected by the medal sensor 31S.

Each input terminal of the "PI1" terminal, the "PI2" terminal and the "PI3" terminal of the third HB-LSI 613 connected to the PIO circuit 705 incorporated in the third HB-LSI 613 is connected to the stop switch 8S ( stop switch board). Data is output in one direction from the stop switch 8S to the third HB-LSI 613 between the 3HB-LSI 613 in the door relay board 603 and the stop switch 8S (stop switch board). Specifically, the signal detected by the stop switch 8S corresponding to the stop button 8L is input to the "PI1" terminal of the third HB-LSI 613, and the "PI2" terminal of the third HB-LSI 613 corresponds to the stop button 8C. A signal detected by the stop switch 8S corresponding to the stop button 8R is inputted to the “PI3” terminal of the third HB-LSI 613 .

The "PI4" terminal (input terminal) of the third HB-LSI 613 connected to the PIO circuit 705 incorporated in the third HB-LSI 613 is connected to the settlement switch 9S (the settlement button 9) via a control signal line. Data is output in one direction from the settlement switch 9S to the third HB-LSI 613 between the third HB-LSI 613 in the door relay board 603 and the settlement switch 9S (settlement button 9). Specifically, the signal detected by the adjustment switch 9S is input to the “PI4” terminal of the third HB-LSI 613 .

The "PI5" terminal (input terminal) of the third HB-LSI 613 connected to the PIO circuit 705 incorporated in the third HB-LSI 613 is connected to the start switch 7S (start lever 7) via a control signal line. Between the 3HB-LSI 613 in the door relay board 603 and the start switch 7S (start lever 7), data is output in one direction from the start switch 7S to the 3HB-LSI 613. FIG. Specifically, the signal detected by the start switch 7S is input to the “PI5” terminal of the third HB-LSI 613 .

The "PI6" terminal (input terminal) of the third HB-LSI 613 connected to the PIO circuit 705 incorporated in the third HB-LSI 613 is connected to the error cancellation switch 57 via the control signal line. Between the third HB-LSI 613 in the door relay board 603 and the error cancellation switch 57 , data is output in one direction from the error cancellation switch 57 to the third HB-LSI 613 . Specifically, the signal detected by the error cancellation switch 57 is input to the “PI6” terminal of the third HB-LSI 613 .

The error canceling switch 57 is not a switch for canceling an actually occurring error detected by the main CPU. When the main CPU detects that the error release switch 57 has been pressed (turned on), it resets an error flag (not shown) in the main RAM. Clear and return to the process before error detection. Therefore, if the error release switch 57 is pressed (turned on) without resolving the cause of the error that is occurring, the error is temporarily released, but the error is immediately detected by the main CPU.

The "PI7" terminal (input terminal) of the third HB-LSI 613 connected to the PIO circuit 705 incorporated in the third HB-LSI 613 is connected to the door open/close monitoring switch 56 via the control signal line. Between the third HB-LSI 613 in the door relay board 603 and the door opening/closing monitoring switch 56 , data is output in one direction from the door opening/closing monitoring switch 56 to the third HB-LSI 613 . Specifically, the signal detected by the door open/close monitoring switch 56 is input to the “PI7” terminal of the third HB-LSI 613 .

(“S0” to “S2” terminals of the 3rd HB-LSI)
The “S0” terminal (main/sub switching terminal) of the third HB-LSI 613 connected to the PIO circuit 705 incorporated in the third HB-LSI 613 is connected to the 5V power supply (set to ON), thereby causing the third HB-LSI 613 to is set as main. The "S1" terminal of the third HB-LSI 613 connected to the PIO circuit 705 incorporated in the third HB-LSI 613 is connected to the 5V power supply (set to ON), the "S2" terminal is grounded (set to OFF), Thereby, address setting (slave setting) of the third HB-LSI 613 is performed.

[11-7. Configuration of Sub Control Unit]
Next, the internal configuration of the sub-controller 620 will be described. FIG. 134 is a diagram showing the internal configuration of the sub-controller 620 and the connection relationship between the sub-controller 620 and external boards and peripheral devices.

The sub-controller 620 has a sub-relay board 621, a sub-control board 622, and a VDP (Video Display Processor) board 623, as shown in FIG. BtoB connections are made between the sub-relay board 621 and the sub-control board 622 and between the sub-control board 622 and the VDP board 623, respectively. The sub-control board 622 and the VDP board 623 are housed in the same case. Although not shown in FIG. 134, a sub ROM (not shown) storing a control program executed by the sub CPU 615 is BtoB connected to the sub relay board 621 .

The sub relay board 621 has a fourth HB-LSI 614 . The configuration of the fourth HB-LSI 614 is the same as that of the HB-LSI 700 described with reference to FIG. 127, so the description of the configuration is omitted here. Further, the sub-relay board 621 is provided with an optical communication input connector H that can be connected to the main control board 601 using an optical fiber cable. The optical communication input connector H is a photoelectric conversion connector that converts an optical signal into an electrical signal and outputs the electrical signal.

The sub-control board 622 includes a sub-CPU 615 that controls various production operations according to command data transmitted from the main control unit 600 (main control board 601), and a sub-CPU that is used as a work area in production control executed by the sub-CPU 615. RAM (not shown); Although not shown in FIG. 134, the sub CPU 615 incorporates a plurality of asynchronous serial communication circuits (UART).

Also, the VDP board 623 (image control board) has a VDP 616 . The VDP 616 is connected to the main display device 210 and the sub display device 220 (with a touch panel) via an LVDS (Low Voltage Differential Signaling) conversion board (not shown) that is BtoB connected to the VDP board 623 . Between the VDP 616 and the main display device 210 and the sub-display device 220 , data is output in one direction from the VDP 616 to the main display device 210 and the sub-display device 220 . Specifically, the VDP 616 creates image data according to the contents of the presentation on the main display device 210 and/or the sub display device 220, and outputs the created image data to the main display device 210 and/or the sub display device 220. to display.

(“O_RX” and “O_TX” terminals of the 4th HB-LSI)
The "O_RX" terminal (receiving terminal) of the fourth HB-LSI 614 connected to the asynchronous serial communication circuit 702 incorporated in the fourth HB-LSI 614 is connected to the optical communication input connector H of the sub relay board 621 via the control signal line. The optical communication input connector H is connected to the optical communication output connector C of the main control board 601 via an optical fiber cable. That is, the serial bus communication circuit 701 incorporated in the fourth HB-LSI 614 is connected to the main control board 601 via the optical communication input connector H of the fourth HB-LSI 614 and the optical fiber cable. Between the sub-relay board 621 and the main control board 601, the main control board 601 transmits command data (described later in FIG. ) are sent in one direction.

The "O_TX" terminal (transmission terminal) of the fourth HB-LSI 614 connected to the asynchronous serial communication circuit 702 built in the fourth HB-LSI 614 is connected to the sub CPU 615 (sub control board 622) built in via the control signal line. It is connected to the "UART_R0" terminal (receiving terminal) of the sub CPU 615 connected to a predetermined asynchronous serial communication circuit. Between the 4th HB-LSI 614 and the sub CPU 615, the command data (see later described FIG. 137) received by the asynchronous serial communication circuit 702 built in the 4th HB-LSI 614 is sent from the "O_TX" terminal of the 4th HB-LSI 614 to the sub CPU 615. is transmitted unidirectionally to the "UART_R0" terminal of the asynchronous serial communication. Specifically, the 4th HB-LSI 614 first reads the transmission data from the main control board 601 via the "O_RX" terminal of the 4th HB-LSI 614, and then converts the game control data included in the transmission data into the received data. By sequentially writing to the buffer 721 (see FIG. 128) and then sequentially writing the game control data written in the reception data buffer 721 to the transmission data buffer 718 (see FIG. 128), from the "O_TX" terminal of the fourth HB-LSI 614 Transmission data from the main control board 601 can be sent to the “UART_R0” terminal of the sub CPU 615 .

That is, in the third game machine, command data, which will be described later, is transmitted from the main control board 601 to the 4 HB-LSI 614 of the sub-relay board 621 via the optical fiber cable, and is transmitted to the optical communication input connector H of the 4 HB-LSI 614. The photoelectrically converted command data is received by the sub CPU 615 via the asynchronous serial communication circuit 702 built in the fourth HB-LSI 614 .

The present invention is not limited to this, and the sub CPU 615 transmits command data from the main control board 601 to the 4 HB-LSI 614 and the sub CPU 615 via a local bus (such as a bus 624) that connects the 4 HB-LSI 614 and the sub-CPU 615. It may be configured to acquire from the LSI 614 . In this case, it is not necessary to connect the “O_TX” terminal of the fourth HB-LSI 614 to the “UART_R0” terminal of the sub CPU 615 . Alternatively, the optical communication input connector H of the sub relay board 621 may be directly connected to the "UART_R0" terminal of the sub CPU 615 via the control signal line. In this case, there is no need to connect the optical communication input connector H and the "O_RX" terminal of the fourth HB-LSI 614 with a control signal line. There is no need to connect to the "UART_R0" terminal of the .

(“PI0” to “PI6” terminals of the 4th HB-LSI)
The "PI0" terminal (input terminal) of the fourth HB-LSI 614 connected to the built-in PIO circuit 705 of the fourth HB-LSI 614 is a PUSH button 631 operated by the player according to the content of the effect via the control signal line. (Direction button 10b in FIG. 3). Data is output in one direction from the PUSH button 631 to the fourth HB-LSI 614 between the fourth HB-LSI 614 and the PUSH button 631 in the sub relay board 621 . Specifically, a signal relating to the player's operation performed on the PUSH button 631 is input to the "PI0" terminal of the fourth HB-LSI 614 .

The "PI1" terminal (input terminal) of the fourth HB-LSI 614 connected to the built-in PIO circuit 705 of the fourth HB-LSI 614 is a chance button 632 operated by the player according to the content of the effect via the control signal line. (Direction button 10a in FIG. 3). Data is output in one direction from the chance button 632 to the fourth HB-LSI 614 between the fourth HB-LSI 614 in the sub relay board 621 and the chance button 632 . Specifically, a signal relating to the player's operation performed on the chance button 632 is input to the “PI1” terminal of the fourth HB-LSI 614 .

The "PI2" to "PI6" terminals (input terminals) of the 4th HB-LSI 614 connected to the PIO circuit 705 built into the 4th HB-LSI 614 can be operated by the player according to the content of the effect via the control signal line. Various operation switches 633 (for example, cross keys (“↑”, “↓”, “→”, “←”), an enter key, etc. provided corresponding to various operation means other than the PUSH button 631 and the chance button 632 ). Between the 4th HB-LSI 614 and various operation switches 633 in the sub-relay board 621, data is output in one direction from the various operation switches 633 to the 4th HB-LSI 614. FIG. Specifically, signals related to the player's operation performed on various operation means other than the PUSH button 631 and the chance button 632 are input to the “PI2” to “PI6” terminals of the fourth HB-LSI 614 .

(“S0” to “S2” terminals of the 4th HB-LSI)
The "S0" terminal (main/sub switching terminal) of the fourth HB-LSI 614 connected to the PIO circuit 705 built in the fourth HB-LSI 614 is grounded (set to OFF), thereby sub-setting the fourth HB-LSI 614. be done. Also, if the "S1" and "S2" terminals of the fourth HB-LSI 614 are set to an open collector state, noise may enter. Grounded.

(Connection form between sub CPU and outside)
A sub CPU 615 in the sub control board 622 is connected to a fourth HB-LSI 614 in the sub relay board 621 via a bus 624 (including a data bus, an address bus, etc.). Specifically, an external bus I/F (not shown) built into the sub CPU 615 and an external bus I/F 707 built into the fourth HB-LSI 614 are connected via a bus 624 (local bus). Data is bi-directionally input/output between the fourth HB-LSI 614 and the sub CPU 615 via the bus 624 . For example, various signals input to the “PI0” to “PI6” terminals of the fourth HB-LSI 614 are input to the sub CPU 615 via the bus 624 . Therefore, the sub CPU 615 can use the fourth HB-LSI 614 not only as a communication circuit but also as an external connection circuit (IC).

Although not shown in FIG. 134, a sub-ROM (not shown) BtoB-connected to the sub-relay board 621 is connected to the sub-CPU 615 not by a local bus but by mSATA (mini Serial ATA). In the third game machine, a configuration example in which the sub-ROM is arranged on the sub-relay board 621 will be described, but the present invention is not limited to this, and the sub-ROM may be directly connected to the sub-control board 622 via mSATA. good.

In addition, although not shown in FIG. 134, the “PO” terminal (output terminal) of the fourth HB-LSI 614 connected to the PIO circuit 705 built into the fourth HB-LSI 614 was mounted to drive the movable part. By connecting a motor, a solenoid, etc. via the driver IC, the sub CPU 615 can control the operation of the movable character (performance by the movable character) via the fourth HB-LSI 614 .

The sub CPU 615 is connected to the VDP 616 in the VDP board 623 via the PCI Express 625 , and bidirectional data input/output is possible between the sub CPU 615 and the VDP 616 via the PCI Express 625 .

The “UART_T1” terminal (transmitting terminal) and “UART_R1” terminal (receiving terminal) of the sub CPU 615 connected to the touch panel asynchronous serial communication circuit built in the sub CPU 615 are connected to the touch panel provided in the sub display device 220 . connected to Between the sub CPU 615 and the touch panel of the sub display device 220, bi-directional data transmission/reception is performed by asynchronous serial communication, and the player's operation information on the touch panel is transmitted to the sub CPU 615, and the sub CPU 615 transmits setting information, etc. to the touch panel. to send.

When the main display device 210 is a projector, an asynchronous serial communication circuit different from the built-in asynchronous serial communication circuit for the touch panel in the sub CPU 615 is connected to the main display device 210, and two-way communication is performed between the two. I do. In this case, sub CPU 615 transmits a projector control command to main display device 210 , and main display device 210 transmits reply information to the transmitted projector control command to sub CPU 615 .

Further, when the main display device 210 is a projector, relaying is performed separately between the touch panel asynchronous serial communication circuit built in the sub CPU 615 and the main display device 210 (projector) and the sub display device 220 (touch panel). A substrate may be provided, and bidirectional communication may be performed between the sub CPU 615 and the main display device 210 and the sub display device 220 using one asynchronous serial communication circuit in the sub CPU 615 . Specifically, the relay board is configured to switch between a configuration in which one asynchronous serial communication circuit in the sub CPU 615 is connected to the projector and a configuration in which one asynchronous serial communication circuit is connected to the touch panel. may

[11-8. Mode of data transmission between main and sub]
Next, the transmission mode of data (command data) transmitted between the main control unit 600 and the sub-control unit 620, the configuration of the command data, etc. will be described.

[11-8-1. Data transmission cycle between main and sub]
FIG. 135 is a diagram showing a mode (time chart) of transmission of command data between the main control section 600 and the sub-control section 620 of the third gaming machine.

FIG. 135 shows an example in which command data is transmitted in the order of a start command, a reel rotation start command, a no-operation command, a no-operation command, . . . by asynchronous serial communication. Note that the periods labeled "start", "rotation start", and "no operation" in FIG. 135 are transmission periods of the start command, rotation start command, and no operation command, respectively. Also, "Data=**" described above the transmission period of each command data in FIG. 135 indicates the data length (number of bytes) of the game control data group included in the command data. For example, the description "Data=6" in the start command indicates that the data length of the game control data group is 6 bytes, that is, the start command includes 6 pieces of game control data (communication parameters). In addition, in FIG. 135, the period from the end of command transmission to the start of the next command transmission is described as “sub-processing time”. It is the time during which the processing can be performed after the command, and is not the time for the effect control processing itself corresponding to the command.

In the third gaming machine, as shown in FIG. 135, the interval (transmission cycle) from the start of transmission of command data from the main control unit 600 to the sub-control unit 620 to the start of transmission of the next command data is approximately 8 ms. be. Note that the command data transmission period is not limited to this example, and can be appropriately set according to, for example, the specifications of the gaming machine, the performance of the control system, and the like. However, in the third gaming machine, as will be described later, the data length of the command data transmitted from the main control unit 600 to the sub-control unit 620 can be variable, so the command data transmission cycle can be Even if the size of the game control data group (1 packet) contained in the data is maximum (32 bytes), it is set to a value that can sufficiently secure the "sub-processing time" in FIG.

The mode of transmitting command data between the main control unit 600 and the sub-control unit 620 in the third gaming machine is not limited to the example shown in FIG. For example, the interval from the end of transmission of command data to the start of transmission of the next command data may be set to approximately 8 ms. FIG. 136 is a diagram showing a transmission mode (time chart) of command data between the main control section 600 and the sub-control section 620 in such an example (modification). FIG. 136 shows an example in which command data are transmitted in the order of a start command, a reel rotation start command, a no-operation command, a no-operation command, .

In the mode of command data transmission shown in FIG. 136, the interval from the end of transmission of command data to the start of transmission of the next command data is constant at approximately 8 ms. interval can change according to the data length of the command data (type of command data) to be transmitted first. If the data length of command data is fixed, the interval from the start of transmission of command data to the start of transmission of the next command data is constant also in the example shown in FIG.

[11-8-2. Configuration of transmission data between main and sub]
Next, the configuration of data (command data) transmitted from the main controller 600 to the sub-controller 620 by asynchronous serial communication will be described. FIG. 137 is a diagram showing the configuration of command data (asynchronous serial communication data) transmitted from the main control section 600 to the sub-control section 620 in the third gaming machine.

The command data transmitted from the main control unit 600 to the sub-control unit 620 is, from the head side, start data (STX), error detection code data (CRC16), game control data group ("d0" to "dn") and End data (ETX) are arranged in this order. The error detection code data (CRC16) may be placed between the game control data group (“d0” to “dn”) and the end data (ETX), or placed after the end data (ETX). You may

The start data (STX) is 1 byte, the error detection code data (CRC16) is 2 bytes, the data length of the game control data group ("d0" to "dn") is 2 bytes to 32 bytes, and the end Data (ETX) is 1 byte. Therefore, in the third game machine, the maximum data length of one command data transmitted from the main control section 600 to the sub-control section 620 is 36 bytes when the DLE control described later is not performed, and the minimum data length is 36 bytes. is 6 bytes. Further, when the data length of the game control data group is 32 bytes and the DLE control described later is performed for all the 32-byte game control data, the maximum data length of the two command data is 68 bytes. Become.

A game control data group (“d0” to “dn”) consisting of a plurality of game control data includes, as game control data (communication parameters), information indicating the command type (command ID), the game status at the time of command transmission, and the game Various information related to progress is included. Various information (communication parameters) regarding the game status and game progress contained in the game control data group (“d0” to “dn”) include, for example, information regarding the internal winning combination, RT status (game status), ball output status, The type of information included in the game control data group, such as navigation data, varies depending on the command type. Therefore, the content and number of information (communication parameters) included in the game control data group change according to the command type, and the data length of the game control data group changes according to the command type.

[11-8-3. DLE control]
In the third game machine, the game control data group (“d0” to “dn”) includes game control data having the same value as any of DLE data (DLE), start data (STX) and end data (ETX). If it is, the option granting circuit (see FIG. 128) in the first HB-LSI611 mounted on the main control board 601, DLE control (conversion) is performed on the game control data, DLE control (conversion) Later game control data is transmitted to the sub-controller 620 together with the DLE data. Then, on the side of the sub-control unit 620, when the DLE data is received, the option check circuit (see FIG. 128) in the fourth HB-LSI 614 mounted on the sub-relay board 621 allows game control after the received DLE control (conversion) Data is restored to the original game control data.

FIG. 138 shows the correspondence between the game control data before DLE conversion, the game control data after DLE conversion (transmission data), the control formula used during DLE conversion, and the control formula used during DLE restoration. It is a table.

In the third gaming machine, as shown in FIG. 138, the start data (STX) and end data (ETX) are set to "7EH" and "7FH" respectively, and the DLE data (DLE) is set to "7DH". is set. Note that the values of the DLE data, start data, and end data are not limited to the values in this example, and can be set to arbitrary values. Hereinafter, with reference to FIG. 138, the transmitting/receiving operation of the game control data to be DLE controlled (converted) and the contents of the DLE control performed on the game control data at that time will be specifically described.

(When game control data is "7DH")
For example, if the game control data to be transmitted is the same data "7DH" as the DLE data (DLE), at the time of data transmission, the main control unit 600 side performs an exclusive OR (xor ) is performed, and “5DH”, which is the result of the calculation, becomes the game control data after the DLE conversion. In this case, "7DH" (DLE data) and "5DH" (game control data after DLE conversion) are transmitted to the sub-control section 620 in this order.

On the other hand, on the side of the sub-control unit 620, when "7DH" (DLE data) is received, the next received "5DH" (game control data after DLE conversion) and the exclusive OR of "20H" ( xor) is performed, the result of which is "7DH", and the original game control data is restored.

(When game control data is "7EH")
For example, if the game control data to be transmitted is the same data "7EH" as the start data (STX), at the time of data transmission, the main control unit 600 side performs an exclusive OR (xor ) is performed, and “5EH”, which is the result of the calculation, becomes the game control data after the DLE conversion. In this case, "7DH" (DLE data) and "5EH" (game control data after DLE conversion) are transmitted to the sub-controller 620 in this order.

On the other hand, on the sub-control unit 620 side, when receiving "7DH" (DLE data), the next received "5EH" (game control data after DLE conversion) and "20H" are exclusive ORed ( xor) is performed, the result of which is "7EH", and the original game control data is restored.

(When game control data is "7FH")
Further, for example, if the game control data to be transmitted is the same data "7FH" as the end data (ETX), the exclusive OR of "20H" and "7FH" is performed on the main control unit 600 side at the time of data transmission. (xor) is calculated, and "5FH", which is the calculation result, becomes the game control data after the DLE conversion. In this case, "7DH" (DLE data) and "5FH" (game control data after DLE conversion) are transmitted to the sub-control section 620 in this order.

On the other hand, on the side of the sub-control unit 620, when "7DH" (DLE data) is received, the next received "5FH" (game control data after DLE conversion) and the exclusive OR of "20H" ( xor) is performed, the result of which is "7FH", and the original game control data is restored.

(Configuration example of command data when DLE control is not performed)
FIG. 139 is a diagram showing a configuration example of command data transmitted from the main control section 600 to the sub-control section 620 when DLE control (conversion) is not performed on the game control data.

In the example of the command data shown in FIG. 139, there are six game control data to be transmitted, and the game control data group ("d0" to "d5") includes start data (STX), end data (ETX) and Data (either of "7DH", "7EH" and "7FH") that is the same as any of the DLE data (DLE) is not included. Therefore, since DLE control is not performed for such a game control data group at the time of data transmission, the data length of the game control data group to be transmitted is 6 bytes, and the data length of the command data is 10 bytes. become a byte.

(Configuration example of command data when DLE control is performed)
FIG. 140 is a diagram for explaining a configuration example of command data transmitted from the main control unit 600 to the sub control unit 620 when DLE control (conversion) is performed on game control data. Figure 140A is a diagram showing a configuration example of a game control data group to be transmitted (before DLE conversion), Figure 140B is a command after performing DLE control (conversion) on the game control data group shown in Figure 140A It is a figure which shows the structural example of data. In addition, in the example shown in FIG. 140, as in the example shown in FIG. 139, the case where the number of game control data to be transmitted is six will be explained.

In this example, as shown in FIG. 140A, the value of the 4th byte game control data "d3" from the head in the game control data group to be transmitted is "7DH", which is the same as the DLE data (DLE). In this case, before transmitting the game control data "d3" written in the transmission data buffer 718, the value "7DH" of the game control data "d3" is converted into "5DH" by DLE control (conversion). In this case, after transmitting the DLE data (7DH), the game control data ("5DH") after DLE conversion is transmitted.

As a result, in the command data shown in FIG. 140B, the DLE data (“7DH”) and the game control data after DLE conversion (“5DH”) are respectively the game control data of the 4th byte from the beginning in the game control data group. It becomes the structure set to "d3" and the game control data "d4" of the 5th byte. At this time, the game control data "d4" at the 5th byte and the game control data "d5" at the 6th byte from the head in the game control data group before DLE conversion shown in FIG. , respectively set to the game control data "d5" of the 6th byte and the game control data "d6" of the 7th byte in the game control data group.

Therefore, in the example shown in FIG. 140B, the data length of the game control data group in the command data is 1 byte longer than the data length of the game control data group before DLE conversion, so the data length of the entire command data is also 1 byte. become longer. In the command data transmission operation shown in FIG. 140B, when the 4th byte DLE data ("7DH") and the 5th byte DLE-converted game control data ("5DH") are transmitted, these data are It is not written to the transmission data buffer 718, but set to the transmission shift register 719 and transmitted directly after DLE control (conversion).

[11-8-4. Example of storage processing of transmission data between main and sub]
Next, a process of generating and storing a game control data group included in data (command data) transmitted from the main control section 600 to the sub-control section 620 by asynchronous serial communication will be described. Here, for the sake of simplification of explanation, it is assumed that one packet of game control data group to be transmitted does not include game control data to be subjected to DLE control. Also, the generation and storage processing of the game control data group described below is executed and controlled by the main CPU of the microprocessor 610 mounted on the main control board 601 .

(Example of processing for generating and storing a group of game control data in a conventional gaming machine)
First, before explaining the process of generating and storing the game control data group performed in the third game machine, in order to clarify its characteristics, A process of generating and storing the game control data group will be described.

Also, here, in order to clarify the characteristics of the game control data group generation and storage processing performed in the third gaming machine, the data length of the game control data group included in the transmission data transmitted to the sub-control unit 620 is a fixed length of 7 bytes, that is, an example in which the number of game control data to be transmitted is seven. Further, here, data indicating the command type (command ID) is set to the game control data arranged at the head of the game control data group, and data relating to the game state is set to the game control data arranged at the end. Various data relating to the game status and progress of the game are set in the game control data (communication parameters 1 to 5, which will be described later) arranged in the second to sixth positions from the top.

In a conventional gaming machine (a gaming machine without HB-LSI), the main CPU has an accumulator A (hereinafter referred to as "A register"), a general-purpose register B (hereinafter referred to as "B register"), a general-purpose Register C (hereinafter referred to as "C register"), general-purpose register D (hereinafter referred to as "D register"), general-purpose register E (hereinafter referred to as "E register"), general-purpose register H (hereinafter referred to as "H register") ), a general-purpose register L (hereinafter referred to as “L register”), and a communication data storage area provided in the main RAM are used to generate and store game control data groups. The data length of each register is 1 byte.

FIG. 141 is a flow chart showing a procedure for generating and storing a game control data group (communication data storing process) executed by the main control unit of a conventional gaming machine.

First, the main CPU determines whether or not there is a free space in the communication data storage area provided in the main RAM (S401). In S401, when the main CPU determines that there is no space in the communication data storage area (when the determination in S401 is NO), the main CPU terminates the game control data group generation and storage process (communication data storage process). .

On the other hand, in S401, when the main CPU determines that there is space in the communication data storage area (when S401 determines YES), the main CPU displays the command ID (game control data "d0") is set (stored) in a communication data temporary area (not shown) of the main RAM (S402).

Next, the main CPU sets (stores) the communication parameter 1 (game control data "d1") relating to the game situation set in the B register in a temporary communication data area (not shown) of the main RAM (S403). Next, the main CPU sets the communication parameter 2 (game control data "d2") relating to the game situation set in the C register in the communication data temporary area (S404). Next, the main CPU sets the communication parameter 3 (game control data "d3") relating to the game situation set in the D register to the communication data temporary area (S405). Next, the main CPU sets the communication parameter 4 (game control data "d4") regarding the game status set in the E register in the communication data temporary area (S406). Next, the main CPU sets the communication parameter 5 (game control data "d5") regarding the game status set in the H register in the communication data temporary area (S407). Next, the main CPU sets the data (game control data "d6") related to the game state set in the L register to the communication data temporary area (S408).

Next, the main CPU sets the data set in the communication data temporary area of the main RAM to the communication data storage area provided in the main RAM (S409). Next, the main CPU generates the sum value (BCC) of the command data to be transmitted using the data set in the A, B, C, D, E, H, and L registers, The sum value is set in the communication data storage area (S410). Then, after the process of S410, the main CPU ends the game control data group generation and storage process (communication data storage process).

(Embodiment 1 of processing for generating and storing a game control data group in the third gaming machine)
Next, execution of a game control data group generation and storage process in the case where the same game control data group as the game control data group generated in the game control data group generation and storage process described with reference to FIG. 141 is generated by the third gaming machine. Example 1 will be explained. FIG. 142 is a flow chart showing the procedure of Example 1 of the game control data group generation and storage processing (communication data storage processing) executed by the main control unit 600 of the third gaming machine. In the first embodiment, the main CPU of the microprocessor 610 mounted on the main control board 601 is the first data set register 711 and the second data set register 712 in the first HB-LSI 611 mounted on the main control board 601. And using the transmission data buffer 718, the generation storage processing of the game control data group is performed.

First, the main CPU determines whether or not the transmission data buffer 718 in the first HB-LSI 611 has space (S411). In this process, the main CPU refers to the information stored in the status register T (see FIG. 129A) provided in the status monitoring circuit 714 in the first HB-LSI 611, and determines whether the transmission data buffer 718 has space. determine whether In S411, when the main CPU determines that there is no space in the transmission data buffer 718 (when the determination in S411 is NO), the main CPU terminates the game control data group generation and storage process (communication data storage process). .

On the other hand, in S411, when the main CPU determines that there is space in the transmission data buffer 718 (when S411 determines YES), the main CPU sends a command ID (game control data "d0") indicating a command type. , is set in the first data set register 711 (S412). Also, by this processing, the command ID set in the first data set register 711 is written in the transmission data buffer 718 .

In S411, if the main CPU determines that there is space in the transmission data buffer 718, bit 0 (B0) of the status register T (see FIG. 129A) is on (“1”) and bit 1 (B1) is on (“1”) or bit 2 (B2) is on (“1”). Further, in S411, the condition for determining that the transmission data buffer 718 has space by the main CPU is that bit 5 (B5) of the status register T is on ("1") and/or bit 6 (B6) is on ( "1") may be added.

Next, the main CPU sets the communication parameter 1 (game control data "d1") regarding the game situation to the first data set register 711 (S413). Also, through this process, the communication parameter 1 set in the first data set register 711 is written to the transmission data buffer 718 . At this time, within the transmission data buffer 718, the communication parameter 1 is written to the address next to the address in which the command ID is stored.

Next, the main CPU sets the communication parameter 2 (game control data "d2") regarding the game situation to the first data set register 711 (S414). Also, through this process, the communication parameter 2 set in the first data set register 711 is written to the transmission data buffer 718 . At this time, in the transmission data buffer 718, the communication parameter 2 is written to the address next to the address where the communication parameter 1 is stored.

Next, the main CPU sets the communication parameter 3 (game control data "d3") regarding the game situation to the first data set register 711 (S415). Also, through this process, the communication parameter 3 set in the first data set register 711 is written to the transmission data buffer 718 . At this time, in the transmission data buffer 718, the communication parameter 3 is written to the address next to the address where the communication parameter 2 is stored.

Next, the main CPU sets the communication parameter 4 (game control data "d4") regarding the game situation to the first data set register 711 (S416). Also, through this process, the communication parameter 4 set in the first data set register 711 is written to the transmission data buffer 718 . At this time, within the transmission data buffer 718, the communication parameter 4 is written to the address next to the address where the communication parameter 3 is stored.

Next, the main CPU sets the communication parameter 5 (game control data "d5") regarding the game situation in the first data set register 711 (S417). Also, through this process, the communication parameter 5 set in the first data set register 711 is written to the transmission data buffer 718 . At this time, in the transmission data buffer 718, the communication parameter 5 is written to the address next to the address where the communication parameter 4 is stored.

Next, the main CPU sets data (game control data "d6") regarding the game state in the second data set register 712 (S418). Also, by this processing, the data regarding the gaming state set in the second data set register 712 is written in the transmission data buffer 718 . At this time, in the transmission data buffer 718, the data regarding the game state is written to the address next to the address where the communication parameter 5 is stored.

Incidentally, in the third gaming machine, as described above, the second data set register 712 stores the last game control data of the one-packet game control data group to be transmitted. Group write completion is determined. Therefore, the main CPU determines that the game control data group for one packet has been written to the transmission data buffer 718 by setting the game control data in the second data set register 712 in the process of S418. . Then, after the process of S418, the main CPU ends the game control data group generation and storage process (communication data storage process).

In addition, in the above-described game control data group generation and storage processing (communication data storage processing), the main CPU sets each game control data in the first data set register 711 or the second data set register 712, and sends the data to the transmission data buffer. 718, check whether or not bit 4 (B4) of the status register T (see FIG. 129A) is set to ON (“1”) (whether or not there is a transfer error). If the bit 4 (B4) of is ON, the process of writing the game control data to the transmission data buffer 718 may be interrupted.

(Embodiment 2 of processing for generating and storing a game control data group in the third gaming machine)
In the first embodiment of FIG. 142, the process of generating and storing a game control data group that can be applied when the data length of the game control data group is set to a fixed length has been described. The data length of the game control data group can be variable. Here, not only when the data length of the game control data group is fixed, but also when the data length of the game control data group is variable, the game control data group generating and storing process (Embodiment 2 ).

FIG. 143 is a flow chart showing the procedure of the second embodiment of the game control data group generation and storage processing (communication data storage processing) executed by the main control unit 600 of the third gaming machine. In addition, in the second embodiment, the main CPU includes not only the first data set register 711, the second data set register 712 and the transmission data buffer 718 in the first HB-LSI 611 mounted on the main control board 601, but also the main RAM, A game control data group is generated and stored using an HL pair register (data length is 2 bytes) composed of a combination of the A register, B register, and H register and L register of the main CPU. Further, in the second embodiment, various game control data (communication parameters relating to game status) transmitted according to the command type (command ID) are stored in a predetermined area in the main RAM (hereinafter referred to as (referred to as a “transmission target storage area”), the data are collectively stored (consecutively in terms of addresses). For example, in the transmission object storage area corresponding to the start command transmitted with the ON state of the start switch 7S, the internal winning combination of the main RAM, the type of lock (reel) effect, the type of freeze effect, etc. are stored as the game control data. (freezing time), RT state, and game state are collectively stored.

First, the main CPU determines whether or not the transmission data buffer 718 in the first HB-LSI 611 has space (S421). In this process, the main CPU refers to the information stored in the status register T (see FIG. 129A) provided in the status monitoring circuit 714 in the first HB-LSI 611, and determines whether the transmission data buffer 718 has space. determine whether In S421, when the main CPU determines that there is no space in the transmission data buffer 718 (when the determination in S421 is NO), the main CPU terminates the game control data group generation and storage process (communication data storage process). .

On the other hand, in S421, when the main CPU determines that there is space in the transmission data buffer 718 (when S421 determines YES), the main CPU stores the command ID (game control data "d0") as the first data. It is set in the set register 711 (S422). Also, by this processing, the command ID set in the first data set register 711 is written in the transmission data buffer 718 .

Next, the main CPU sets the number of remaining game control data to be transmitted (hereinafter referred to as "the number of transmissions") in the B register (S423). The number of transmissions set in the process of S423 is obtained by subtracting 1 from the number "n" of game control data contained in the game control data group of one packet to be transmitted (subtracting the data of the command type (command ID)). value. For example, when the number of game control data contained in one packet of game control data group to be transmitted is "7", "6" is set as the transmission number in the B register in the process of S423.

Next, the main CPU sets the address (top address) of the transmission target storage area in the main RAM corresponding to the command type (command ID) to be processed in the HL pair register (S424).

Next, the main CPU transfers the communication parameters (game control data) stored in the address (leading address or updated address) of the transmission target storage area currently set in the HL pair register to the first data set register. 711 (S425). Also, by this process, the communication parameters (game control data) set in the first data set register 711 are written in the transmission data buffer 718 . At this time, the communication parameters (game control data) are stored in the transmission data buffer 718, the communication parameters written in the transmission data buffer 718 in the previous communication parameter setting process (S422 or S425) to the first data set register 711. (game control data) is written to the next address of the address. After the processing of S425, the main CPU reads the status register T (see FIG. 129A), and if bit 4 (B4) is ON (“1”), interrupts the processing, and generates and stores game control data group. The process (communication data storage process) may be terminated.

Next, the main CPU adds 1 to the value of the HL pair register (S426). By this processing, the address in the transmission object storage area from which the communication parameter (game control data) is read is updated. Next, the main CPU subtracts 1 from the value of the B register (S427). By this process, the number of transmissions (the number of remaining game control data) is updated.

Next, the main CPU determines whether or not the value (the number of transmissions) of the B register is "1" (S428).

In S428, when the main CPU determines that the value of the B register (the number of transmissions) is not "1" (when the determination in S428 is NO), the main CPU returns the process to S425, and performs the processes of S425 to S428. repeat.

On the other hand, if the main CPU determines in S428 that the value (the number of transmissions) of the B register is "1" (if the determination in S428 is YES), the main CPU determines that the HL pair register is currently set. The communication parameter (game state information: game control data "dn") stored at the last address in the transmission target storage area is set in the second data set register 712 (S429). Also, by this process, the communication parameter (game control data “dn”) set in the second data set register 712 is written in the transmission data buffer 718 . At this time, the communication parameter (game control data "dn") is, in the transmission data buffer 718, the communication written in the transmission data buffer 718 in the previous communication parameter setting processing (S425) to the first data set register 711 It is written to the address next to the address of the parameter (game control data "dn-1"). It should be noted that the main CPU determines that the writing of the game control data group for one packet has been completed by setting the second data set register 712 in S429. After the process of S429, the main CPU ends the game control data group generation and storage process (communication data storage process).

In the asynchronous serial communication circuit 702, the communication parameters are set in the second data set register 712 in the process of S429, and the set communication parameters are written in the transmission data buffer 718, thereby writing the game control data group for one packet. is completed. As a result, the data length for one packet is determined, and the determined data length is set in the transmission packet counter of the corresponding packet.

[11-9. Data transmission by synchronous serial communication]
Next, synchronous serial communication of data between the main control board 601, the reel device board 602 and the door relay board 603 in the main control unit 600 will be described.

[11-9-1. Configuration example 1 of data transmitted by synchronous serial communication]
(Overall configuration of transmission data)
FIG. 144 is a diagram showing configuration example 1 of data transmitted by synchronous serial communication between the main control board 601, the reel device board 602, and the door relay board 603. FIG. In FIG. 144, for convenience of explanation, the input/output data for the peripheral device set in the transmission data is not only the value of the data to be transmitted (“value” in the figure), but also the name indicating the type of each data. ("Slave 1 (2nd HB-LSI) output data" in the figure), the storage area (RAM and register ) (such as “FED0H” in the figure) and ports (such as “PO0” in the figure) through which each data is input and output are also described.

In addition, in FIG. 144, for convenience of explanation, the display data of the information display device 14 set in the transmission data is not only the value of the display data (“value” in the figure: “00H to FFH”), but also each display A name indicating the type of data (such as "7-segment display data 1-1" in the figure), a storage area for each display data in the master (1st HB-LSI 611) that is the transmission source and final reception destination of the display data (RAM and register) addresses ("FED4H" in the figure, etc.), and the types of 7-segment LEDs and lamps displayed with each display data ("2-digit 7-segment for credit display" in the figure, etc.) It is

Furthermore, in FIG. 144, for convenience of explanation, in each 1-byte data included in the transmission data, the bit located on the right side of the drawing is regarded as the higher-order bit. Therefore, for example, in the leading 1-byte data in the "slave 1 (second HB-LSI) output data", the leftmost bit (the bit corresponding to the output port "PO0") is the least significant bit ( LSB), and the rightmost bit (the bit corresponding to output port "PO7") becomes the most significant bit (MSB).

As shown in FIG. 144, the transmission data of Configuration Example 1 are 2-byte data called "slave 1 (second HB-LSI) output data" to "slave 4 (preliminary) output data" from the head side, Each 1-byte data called "7-segment display data 1-1" to "7-segment display data 1-4 (shared)", 1-byte data called "status display data (shared)", "7-segment display data 2-1” to “7-segment display data 2-3” each of 1-byte data, and “slave 1 (second HB-LSI) input data” to “slave 4 (preliminary) input data” of 2-bytes each. Data and 2-byte data called "CRC16" are arranged in this order. That is, in configuration example 1, the size (data length) of the data portion in one piece of transmission data is 26 bytes. The actual transmission data is configured in a data format according to the communication specifications of the synchronous serial bus communication to be used, and the transmission data in this data format is transmitted and received between master and slave and between slave and slave. , the description of the communication specifications is omitted here.

Further, in the third gaming machine, when the main CPU of the microprocessor 610 provided on the main control board 601 writes the data to be output to each slave to the transmission data between the main CPU and the master (first HB-LSI 611) , and when reading the data input by each slave from the transmission data, by specifying the address of the data storage area (RAM or register) in the master described in FIG. 144, the memory mapped IO method Data input/output is performed at . The contents of various data set in the transmission data will be described below.

(Slave 1 (second HB-LSI) output data to slave 4 (preliminary) output data)
The data set in the “slave 1 (second HB-LSI) output data” is output (set ). That is, the "slave 1 (second HB-LSI) output data" is output to peripheral devices such as the hopper device 32 connected to the spinning drum device board 602 (PIO circuit 705) and each reel (see FIG. 132). Data (control signal) is set.

The data set in the "slave 2 (3rd HB-LSI) output data" is output (set) to the "PO0" to "PO15" terminals of the 3rd HB-LSI 613 (PIO circuit 705) mounted on the door relay board 603. This is the data to be used. That is, the "slave 2 (3rd HB-LSI) output data" is output to peripheral devices such as the medal sensor 31S and the stop switch 8S (see FIG. 133) connected to the door relay board 603 (PIO circuit 705). Data (control signal) is set.

In the third gaming machine, since HB-LSIs corresponding to "slave 3" and "slave 4" are not provided, 2-byte "slave 3 (preliminary) output data" and "slave 4 (preliminary) output data" "output data" is unused, and arbitrary data can be set to these output data. In the third game machine, 2-byte "slave 3 (preliminary) output data” and “slave 4 (preliminary) output data” are provided. Therefore, when only two HB-LSIs set as slaves are provided in the main control unit 600, "slave 3 (preliminary) output data" and "slave 4 (preliminary) output data" are added to the transmission data. A configuration in which they are not provided may be adopted.

The set processing of "slave 1 (second HB-LSI) output data" to "slave 4 (preliminary) output data" is performed by main control board 601 (first HB-LSI 611) when transmission data is transmitted.

(7-segment display data 1-1, 7-segment display data 1-2)
Each 1-byte display data set in "7-segment display data 1-1" and "7-segment display data 1-2" is output (set) to the third HB-LSI 613 mounted on the door relay board 603. This data is display data used when the gaming machine is a normal gaming machine (non-medalless gaming machine).

The display data set in "7-segment display data 1-1" is display data for lighting/extinguishing control of the credit display lamp (2-digit 7-segment LED: see FIG. 125A) in the information display device . That is, the display data set in the "7-segment display data 1-1" is for the 7-segment LED that is controlled to be turned on/off by the "AS0" terminal and the "AS1" terminal of the third HB-LSI 613 (LED drive circuit 703). is the display data of If the game machine is a medal-less game machine, the "7-segment display data 1-1" is not used, so any data can be set in the "7-segment display data 1-1".

The display data set in the “7-segment display data 1-2” is display data for lighting/extinguishing control of the payout display lamp (2-digit 7-segment LED: see FIG. 125A) in the information display device 14 . That is, the display data set in the "7-segment display data 1-2" is for the 7-segment LED that is controlled to turn on/off at the "AS2" and "AS3" terminals of the third HB-LSI 613 (LED drive circuit 703). is the display data of If the game machine is a medal-less game machine, the "7-segment display data 1-2" is not used, so any data can be set in the "7-segment display data 1-2".

The set processing of "7-segment display data 1-1" and "7-segment display data 1-2" is performed by the main control board 601 (first HB-LSI 611) when transmission data is transmitted.

(7-segment display data 1-3 (shared), 7-segment display data 1-4 (shared))
Each 1-byte display data set in "7-segment display data 1-3 (shared)" and "7-segment display data 1-4 (shared)" is stored in the third HB-LSI 613 mounted on the door relay board 603. This is output (set) data, and is display data that is used (commonly used) regardless of whether the game machine is a normal game machine or a medalless game machine.

The display data set in "7-segment display data 1-3 (shared)" is the third digit ( 7-segment LED on the left side: corresponding to the left reel 3L) and 7-segment LED in the second digit (central 7-segment LED in the figure: corresponding to the middle reel 3C). That is, the display data set in the "7-segment display data 1-3 (shared)" is controlled by the "AS4" terminal and the "AS5" terminal of the third HB-LSI 613 (LED drive circuit 703). This is display data for the segment LED.

The display data set in "7-segment display data 1-4 (shared)" is the first digit ( 7-segment LED on the right: display data for turning on/off the 7-segment LED (corresponding to the right reel 3R). That is, the display data set in the "7-segment display data 1-4 (shared)" is the display data for the 7-segment LED that is controlled to turn on/off at the "AS6" terminal of the third HB-LSI 613 (LED drive circuit 703). Data. In configuration example 1, the display data for the 7-segment LED in the first digit of the instruction monitor is set to the lower 4 bits in the "7-segment display data 1-4 (shared)", and the upper 4-bits are set to Unused (arbitrary data can be set).

The set processing of "7-segment display data 1-3 (shared)" and "7-segment display data 1-4 (shared)" is performed by the main control board 601 (first HB-LSI 611) at the time of transmission of transmission data.

(Status display data (common))
The 1-byte display data set in the “state display data (shared)” is data output (set) to the third HB-LSI 613 mounted on the door relay board 603. This is display data that is used (commonly used) in any of the medalless gaming machines. The 1-byte display data set in the "status display data (common)" is used to turn on/off various status display LEDs (various status display lamps in FIGS. This is display data for extinguishing control. That is, the display data set in the "state display data (shared)" is display data for the state display lamp that is controlled to be turned on/off by the "AS7" terminal of the third HB-LSI 613 (LED drive circuit 703).

Each bit from the least significant bit to the 6th bit in the "status display data (shared)" has an "INSERT" lamp, a "START" lamp, a "REPLAY" lamp, a "1BET" lamp, and a "2BET" lamp. And display data (0 (off)/1 (on) data) for lighting/extinguishing control of the "3BET" lamp are set. The 7th and 8th bits in the "status display data (shared)" are unused, and arbitrary data can be set in these bits. Also, when the gaming machine is a medalless gaming machine, the least significant bit in the "status display data (shared)" is unused.

The "state display data (shared)" setting process is performed by the main control board 601 (first HB-LSI 611) when transmission data is transmitted.

(7-segment display data 2-1 to 7-segment display data 2-3)
Each 1-byte display data set in "7-segment display data 2-1" to "7-segment display data 2-3" is output (set) to the third HB-LSI 613 mounted on the door relay board 603. data, and is display data used when the gaming machine is a medalless gaming machine. In addition, if the game machine is not a medalless game machine, "7 segment display data 2-1" to "7 segment display data 2-3" are not used, so "7 segment display data 2-1" to "7 segment display data 2-3” can be set to arbitrary data.

The display data set in "7-segment display data 2-1" is the first digit (one's place) of the five-digit 7-segment LED (see FIG. 126) provided in the status display monitor 14a of the information display device 14. : Display data for turning on/off control of the 7-segment LED located on the rightmost side in the figure) and the 7-segment LED in the second digit (tenth place). That is, the display data set in the "7-segment display data 2-1" is for the 7-segment LED that is controlled to be turned on/off by the "AS8" terminal and the "AS9" terminal of the third HB-LSI 613 (LED drive circuit 703). is the display data of

The display data set in "7-segment display data 2-2" is the third digit (hundreds place) of the 5-digit 7-segment LED (see FIG. 126) provided in the status display monitor 14a of the information display device 14. ) and the display data for turning on/off the 7-segment LED in the fourth digit (1000's place). That is, the display data set in the "7-segment display data 2-2" is for the 7-segment LED that is controlled to turn on/off at the "AS10" terminal and "AS11" terminal of the third HB-LSI 613 (LED drive circuit 703). is the display data of

The display data set in "7-segment display data 2-3" is the fifth digit (10000 digit) of the 5-digit 7-segment LED (see FIG. 126) provided in the status display monitor 14a of the information display device 14. : Display data for turning on/off the 7-segment LED (7-segment LED located on the leftmost side in the figure). That is, the display data set in the "7-segment display data 2-3" is the display data for the 7-segment LED that is controlled to turn on/off at the "AS12" terminal of the third HB-LSI 613 (LED drive circuit 703). . In configuration example 1, the display data of the 5th digit 7-segment LED is set to the lower 4 bits in "7-segment display data 2-3", and the upper 4-bit display data is unused. (arbitrary data can be set).

The set processing of "7-segment display data 2-1" to "7-segment display data 2-3" is performed by the main control board 601 (first HB-LSI 611) when transmission data is transmitted.

In this embodiment, an example in which the information display device 14 is connected to the third HB-LSI 613 mounted on the door relay board 603 has been described, but the present invention is not limited to this. For example, the information display device 14 may be connected to the second HB-LSI 612 mounted on the reel device substrate 602, and in this case also, the above-described display processing of the information display device 14 is applied as in the present embodiment. can do.

(Slave 1 (second HB-LSI) input data to slave 4 (preliminary) input data)
The data set in the "slave 1 (second HB-LSI) input data" is input to the "PI0" to "PI15" terminals of the second HB-LSI 612 (PIO circuit 705) mounted on the reel device board 602. Data. That is, in the "slave 1 (second HB-LSI) input data", data (detection signal ) is set. It should be noted that the set processing of the "slave 1 (second HB-LSI) input data" is performed after the transmission data is received by the rotary drum device board 602 and before the transmission data is transmitted to the door relay board 603. It is performed on the device substrate 602 (second HB-LSI 612).

The display data set in the "slave 2 (3rd HB-LSI) input data" is input to the "PI0" to "PI15" terminals of the 3rd HB-LSI 613 (PIO circuit 705) mounted on the door relay board 603. Data. That is, the "slave 2 (3rd HB-LSI) input data" is input from peripheral devices such as the medal sensor 31S and the stop switch 8S (see FIG. 133) connected to the door relay board 603 (PIO circuit 705). Data (detection signal) is set. The set processing of "slave 2 (3rd HB-LSI) input data" is performed after the transmission data is received by the door relay board 603 and before the transmission data is transmitted to the main control board 601. 603 (third HB-LSI 613).

Further, in the third gaming machine, as described above, HB-LSIs corresponding to "slave 3" and "slave 4" are not provided. "Slave 4 (preliminary) input data" is unused (not updated even during transmission), and arbitrary data can be set to these input data. In the third game machine, 2-byte "slave 3 (preliminary) input data” and “slave 4 (preliminary) input data” are provided. Therefore, when only two HB-LSIs set as slaves are provided in the main control unit 600, "slave 3 (preliminary) input data" and "slave 4 (preliminary) input data" are added to the transmission data. A configuration in which they are not provided may be adopted.

(CRC16)
The data set in "CRC16" is 2-byte error detection code data for detecting anomalies occurring in data communication. The data set in "CRC16" is read by the HB-LSI 700 that has received the transmission data, and is used to determine whether or not a data communication error has occurred.

Also, when transmitting transmission data, the HB-LSI 700 of each board generates a CRC generation circuit (not shown) in the serial bus communication circuit 701 based on data other than "CRC16" set in the transmission data at the time of transmission. ) is used to calculate the error detection code data, and the calculation result is set in "CRC16". Therefore, when transmission data is transmitted from the rotary drum device board 602 to the door relay board 603, the "slave 1 (second HB-LSI) input data" used for calculating the error detection code data is It becomes the “slave 1 (second HB-LSI) input data” updated by the board 602 . Further, when transmitting transmission data from the door relay board 603 to the main control board 601, "slave 1 (second HB-LSI) input data" and "slave 2 (third HB-LSI) input data" used for calculating error detection code data -LSI) input data” are respectively “slave 1 (second HB-LSI) input data” updated by the reel device board 602 and “slave 2 (third HB-LSI) input data” updated by the door relay board 603 data”.

It should be noted that when the HB-LSI 700 of each board receives the transmission data, the check of whether or not there is an error in the error detection code data set to "CRC16" is performed by a CRC check circuit ( ), but if it is determined that there is an error in the check result, the HB-LSI 700 of each board discards the received transmission data.

As described above, in configuration example 1 of data transmitted between boards in the main control unit 600, the configuration (format) of the transmission data can be changed whether the gaming machine is a normal gaming machine or a medalless gaming machine. Although a configuration example capable of coping with this has been described, the present invention is not limited to this. For example, if the gaming machine is a normal gaming machine, display data dedicated to the medalless gaming machine (“7-segment display data 2-1” to “7-segment display data 2- 3”) may be omitted. Further, for example, if the game machine is a medalless game machine, the transmission data shown in FIG. 1-2”) may be omitted.

[11-9-2. Data transmission operation example 1 in synchronous serial communication]
Next, the transmission data transmission operation example 1 of the configuration example 1 (FIG. 144) in the main control unit 600 will be described. In the transmission data transmission operation example 1, the synchronous serial communication is performed at an interval equal to or less than the periodic interrupt processing cycle (1 interrupt time: 1.1172 ms) performed by the main CPU, and is executed and controlled by the controller 706. be. In addition, in the transmission data transmission operation example 1 described below, the size (26 bytes) of the transmission data generated by the main control board 601 (first HB-LSI 611: master) does not change during transmission. A case in which no transmission error occurs will be described.

First, in the master-set first HB-LSI 611, various output data output from the output ports of each slave (rotating drum board 602 and door relay board 603) and various display data of the information display device 14 are converted into transmission data. set. Specifically, in the first HB-LSI 611, the main CPU outputs "slave 1 (second HB-LSI) output data", "slave 2 (third HB-LSI) output data" and "slave 2 (third HB-LSI) output data" in the transmission data shown in FIG. LSI) output data”, “7-segment display data 1-1” to “7-segment display data 1-4 (shared)”, “status display data (shared)” and “7-segment display data 2-1” to “7 Data is set at addresses corresponding to segment display data 2-3.

At this time, "7-segment display data 1-1" to "7-segment display data 1-4 (shared)" are set in the first segment registers 0 to 3 (not shown) provided in the first HB-LSI 611, respectively. , “state display data (shared)” are set in the first segment register 4 (not shown) provided in the first HB-LSI 611 . At this time, "7-segment display data 2-1" to "7-segment display data 2-3" are set in the second segment registers 0 to 2 (not shown) provided in the first HB-LSI 611, respectively. .

When transmitting transmission data from the first HB-LSI 611, "slave 3 (preliminary) output data", "slave 4 (preliminary) output data", "slave 1 (second HB-LSI) input data", "slave 2 (3rd HB-LSI) input data”, “slave 3 (preliminary) and data”, and “slave 4 (preliminary) input data” are not set. Therefore, the transmission data at the start of data transmission from the main control board 601 (first HB-LSI 611) includes "slave 3 (preliminary) output data", "slave 4 (preliminary) output data", "slave 1 (second HB -LSI) input data”, “slave 2 (third HB-LSI) input data”, “slave 3 (preliminary) and data”, and “slave 4 (preliminary) input data” are the data stored at that time. Become.

Next, 2-byte error detection code data (CRC16) is calculated using various data set in the first HB-LSI 611, and the calculation result is set to "CRC16" in the transmission data. Then, in the main control board 601 (first HB-LSI 611), when the above-described transmission data setting processing (transmission data generation processing) is completed, the generated transmission data is transferred to the first HB-LSI 611 (serial bus communication circuit 701). ) to the drum device board 602 (second HB-LSI 612) via an optical fiber cable.

Next, when the second HB-LSI 612 (serial bus communication circuit 701) of the reel device board 602 receives the transmission data from the main control board 601, the second HB-LSI 612 receives the "slave 1 ( 2nd HB-LSI) output data” (2 bytes) are set to the “PO0” to “PO15” terminals of the 2nd HB-LSI 612 (output terminals of the PIO circuit 705). At this time, in the second HB-LSI 612, detection data of various peripheral devices (reels, etc.) read via the “PI0” to “PI15” terminals (input terminals of the PIO circuit 705) are transferred to “ "slave 1 (second HB-LSI) input data".

Next, in the second HB-LSI 612, error detection code data (CRC16) is calculated using various data set in the transmission data at this time, and the calculation result is set in "CRC16" in the transmission data. As a result, "CRC16" in the transmission data is updated. After the above processing in the second HB-LSI 612 is completed, the transmission data in which new data is set in the "slave 1 (second HB-LSI) input data" is transferred to the second HB-LSI 612 ( It is transmitted from the serial bus communication circuit 701) to the door relay board 603 (third HB-LSI 613) via the optical fiber cable.

Next, when the transmission data from the reel device board 602 is received by the third HB-LSI 613 (serial bus communication circuit 701) of the door relay board 603, the third HB-LSI 613 receives the "slave 2 ( 3HB-LSI) output data” (2 bytes) are set to the “PO0” to “PO15” terminals of the 3HB-LSI 613 (output terminals of the PIO circuit 705). At this time, in the third HB-LSI 613, detection data of various peripheral devices (various sensors, various switches, etc.) read via the "PI0" to "PI15" terminals (input terminals of the PIO circuit 705) are transmitted data. is set to "slave 2 (3rd HB-LSI) input data" in the

Furthermore, when the transmission data is received by the third HB-LSI 613 (serial bus communication circuit 701), in the third HB-LSI 613, under the control of the controller 706, various 7-segment display data and status display data included in the transmission data are Read in the order received. Next, each of the read 7-segment display data (1 byte) is converted into character data in the third HB-LSI 613 under the control of the controller 706 , and the converted display data is input to the LED drive circuit 703 . The read status display data (1 byte) is also input to the LED drive circuit 703 .

The type of 7-segment display data read by the third HB-LSI 613 differs depending on the type of gaming machine. Specifically, when the gaming machine is a normal gaming machine, among the various 7-segment display data included in the transmission data, "7-segment display data 1-1" to "7-segment display data 1-4 ( When the gaming machine is a medalless gaming machine, "7-segment display data 1-3 (shared)", "7-segment display data 1-4 (shared)" and "7-segment display data 2-1” to “7-segment display data 2-3” are read. Also, the “status display data (multipurpose)” included in the transmission data is read by the third HB-LSI 613 regardless of the type of gaming machine.

Next, in the third HB-LSI 613, error detection code data (CRC16) is calculated using various data set in the transmission data at this time, and the calculation result is set in "CRC16" in the transmission data. As a result, "CRC16" in the transmission data is updated. After the above processing in the 3HB-LSI 613 is completed, the transmission data in which new data is set in the "slave 2 (3rd HB-LSI) input data" is transmitted to the 3HB-LSI 613 (serial It is transmitted from the bus communication circuit 701) to the main control board 601 (first HB-LSI 611) via an optical fiber cable.

Next, when the transmission data from the door relay board 603 is received by the first HB-LSI 611 (serial bus communication circuit 701) of the main control board 601, the main CPU outputs the data from the first HB-LSI 611 to the bus 606 (data bus and address (including bus), the data set in the "slave 1 (second HB-LSI) input data" and "slave 2 (third HB-LSI) input data" in the transmission data are read (acquired). . Thereby, the main CPU can grasp the state of the external peripheral devices (hopper device, reel, various sensors, various switches, etc.). Also, when the transmission data is received by the first HB-LSI 611, the main CPU changes the "slave 1 (second HB-LSI) output data" and "slave 2 (third HB-LSI) output data" in the transmission data. By reading the set data, it is possible to confirm whether or not the control signals are normally output from the output ports PO0 to PO15 of the second HB-LSI 612 and the third HB-LSI 613. FIG.

[11-9-3. Configuration example 2 of data transmitted by synchronous serial communication]
The configuration of data transmitted between boards in the main control unit 600 and the mode of transmission thereof are not limited to the modes of configuration example 1 and transmission operation example 1 described above. For example, data transmission between the first HB-LSI 611 set as master and the second HB-LSI 612 and third HB-LSI 613 set as slaves may be performed separately for each slave. In this case, the address of the HB-LSI 700 of the transmission destination is specified, and transmission/reception of transmission data is performed for each transmission destination. Also in configuration example 2, the transmission direction of the transmission data is the direction from the main control board 601 to return to the main control board 601 after circulating through the drum device board 602 and the door relay board 603 .

FIG. 145 is a diagram showing configuration example 2 of data transmitted by synchronous serial communication between the main control board 601, the reel device board 602, and the door relay board 603. FIG. FIG. 145A is a diagram showing the configuration of data transmitted from the main control board 601 to the reel device board 602 or the door relay board 603 by synchronous serial communication (hereinafter referred to as "master transmission data"), and FIG. 6 is a diagram showing the structure of data (hereinafter referred to as "slave transmission data") transmitted from the rotary drum device board 602 or the door relay board 603 to the main control board 601 by synchronous serial communication.

In FIG. 145 as well, for convenience of explanation, the input/output data for the peripheral device set in the transmission data is not only the value of the data to be transmitted (“value” in the figure), but also each Names indicating types of data (“output data” and “input data” in the diagram), storage areas (RAM and registers) addresses (“FE**H”, “FE##H”, “FE$$H”, “FE&&H” in the figure) and ports for inputting and outputting each data (“PO0” in the figure) etc.) are also listed.

In FIG. 145A, "FE**H" and "FE##H", which indicate the addresses of the storage areas of the 2-byte output data, differ depending on the slave type to which the output data is to be sent. For example, when the slave to be the transmission destination is the second HB-LSI 612 (slave 1), "FE**H" and "FE##H" become "FED0H" and "FED1H" respectively. When the slave is the third HB-LSI 613 (slave 2), "FE**H" and "FE##H" become "FED2H" and "FED3H", respectively (see FIG. 144).

Also, in FIG. 145B, "FE$$H" and "FE&&H", which indicate the addresses of the storage areas of the 2-byte input data, differ according to the type of slave that is the transmission source of the input data. For example, when the source slave is the second HB-LSI 612 (slave 1), "FE$$H" and "FE&&H" become "FEF0H" and "FEF1H" respectively, and the source slave is In the case of the third HB-LSI 613 (slave 2), "FE$$H" and "FE&&H" become "FEF2H" and "FEF3H" respectively (see FIG. 144).

In addition, in FIG. 145, for convenience of explanation, the display data of the information display device 14 set in the transmission data is not only the value of the display data (“value” in the figure: “00H to FFH”), but also each display A name indicating the type of data (such as "7-segment display data 1-1" in the figure), a storage area for each display data in the master (1st HB-LSI 611) that is the transmission source and final reception destination of the display data (RAM and register) addresses ("FED4H" in the figure, etc.) and the types of 7-segment LEDs and lamps displayed by each display data ("2-digit 7-segment for credit display" in the figure, etc.) are also described. there is

(master transmission data)
As shown in FIG. 145A, the master transmission data consists of 1-byte data called "destination address data", 1-byte data called "source address data", and 2 bytes called "output data" from the head side. byte data, each 1-byte data called "7-segment display data 1-1" to "7-segment display data 1-4 (shared)", 1-byte data called "status display data (shared)", " 1-byte data called 7-segment display data 2-1 to 7-segment display data 2-3 and 2-byte data called 'CRC16' are arranged in this order. That is, in configuration example 2, the size (data length) is 14 bytes.

In configuration example 2, as shown in FIG. 145A, even if the slave to be the transmission destination is the second HB-LSI 612 (slave 1) that is not connected to the information display device 14, the display data of the information display device 14 is included in the master transmission data for the following reasons. The HB-LSI 700 that has received the master transmission data cannot determine whether or not the LED drive circuit 703 incorporated therein is connected to the information display device 14, regardless of the slave type. Therefore, here, regardless of whether the destination is slave 1 or slave 2, in order to be able to handle both slaves with the same format of master transmission data, the display data of the information display device 14 is transferred to the destination slave. is included in the master transmission data as common data regardless of the type of The present invention is not limited to this, and the master transmission data for slave 1 and the master transmission data for slave 2 may be configured in separate formats. The data may not include the display data of the information display device 14 .

Also, in configuration example 2, an example in which spare output data (“slave 3 (preliminary) output data” and “slave 4 (preliminary) output data” in FIG. 144) is not included in the master transmission data will be described. The invention is not limited to this. Reserve output data may be included in the master transmission data so that it can be applied even when the number of HB-LSIs set as slaves in the main control unit 600 increases for the purpose of function expansion or the like.

(destination address data, source address data)
In the "destination address data" and "source address data" in the master transmission data, the manner of voltage application to the "S0" to "S2" terminals of each HB-LSI 700 (PIO circuit 705) (3-bit data correspondence) is set (“00H” to “07H”).

Specifically, in the first HB-LSI 611 serving as the master, 5V is applied to the terminals “S0” to “S2” (see FIG. 131), so the address data of the first HB-LSI 611 is “07H” (=“ 111B"). In the second HB-LSI 612 serving as slave 1, 5V is applied to the "S0" terminal and the "S1" and "S2" terminals are grounded (see FIG. 132), so the address data of the second HB-LSI 612 is "04H ” (=“100B”). In addition, in the third HB-LSI 613, which is the slave 2, 5V is applied to the "S0" and "S1" terminals, and the "S2" terminal is grounded (see FIG. 133), so the address data of the third HB-LSI 613 is "06H" (="110B").

Therefore, when the master transmission data is transmitted from the main control board 601 (master) to the reel device board 602 (slave 1), "04H" is set in the "destination address data" in the master transmission data. , "07H" is set in the "source address data". On the other hand, when the master transmission data is transmitted from the main control board 601 (master) to the door relay board 603 (slave), "06H" is set in the "destination address data" in the master transmission data, and "transmission "Original address data" is set to "07H".

(output data)
"Output data" in the master transmission data is set to output data corresponding to the type of the slave that is the transmission destination.

For example, when the master transmission data is transmitted from the main control board 601 (master) to the rotary drum device board 602 (slave 1), the "output data" in the master transmission data is the configuration example 1 shown in FIG. Data similar to the "slave 1 (second HB-LSI) output data" in the transmission data is set. On the other hand, when the master transmission data is transmitted from the main control board 601 (master) to the door relay board 603 (slave 2), the "output data" in the master transmission data is the transmission of configuration example 1 shown in FIG. Data similar to "slave 2 (third HB-LSI) output data" in the data is set.

(7-segment display data 1-1 to 7-segment display data 1-4 (shared))
"7-segment display data 1-1" to "7-segment display data 1-4 (shared)" in the master transmission data are, for example, "7-segment display data" in the transmission data of configuration example 1 shown in FIG. Data 1-1” to “7-segment display data 1-4 (shared)” are set.

That is, in the "7-segment display data 1-1" and "7-segment display data 1-2" in the master transmission data, the information display device 14 (FIG. 125A) used when the gaming machine is a normal gaming machine ), the display data of the credit display lamp (2-digit 7-segment LED) and the payout display lamp (2-digit 7-segment LED) are set. In addition, regardless of the type of game machine, the information display device 14 (Fig. and FIG. 126) is set.

(Status display data (common))
For example, the same data as the “status display data (shared)” in the transmission data of configuration example 1 shown in FIG. 144 is set in the “status display data (shared)” in the master transmission data. In other words, the display data of various status display lamps in the information display device 14 (see FIGS. 125 and 126) are set in the "status display data (common use)" in the master transmission data regardless of the type of gaming machine. be. When the gaming machine is a medalless gaming machine, the least significant bit in the "status display data (shared)" is unused.

(7-segment display data 2-1 to 7-segment display data 2-3)
"7-segment display data 2-1" to "7-segment display data 2-3" in the master transmission data are, for example, "7-segment display data 2- 1” to “7-segment display data 2-3” are set. That is, in the "7-segment display data 2-1" to "7-segment display data 2-3" in the master transmission data, the information display device 14 (see FIG. 126) used when the gaming machine is a medalless gaming machine ), the display data of the 5-digit 7-segment LED is set.

(CRC16)
"CRC16" in the master transmission data contains "output data", "7-segment display data 1-1" to "7-segment display data 1-4 (shared)", "status display data (shared)" and "7 2-byte error detection code data calculated using the segment display data 2-1 to 7-segment display data 2-3 is set.

As described above, in configuration example 2 of the data transmitted between the boards in the main control unit 600, the configuration (format) of the master transmission data is changed even if the gaming machine is a normal gaming machine. Although a configuration example capable of coping with the above has been described, the present invention is not limited to this. For example, if the gaming machine is a normal gaming machine, display data (“7-segment display data 2-1” to “7-segment display data 2- 3”) may be omitted. Further, for example, if the game machine is a medalless game machine, the transmission data shown in FIG. 1-2”) may be omitted.

(slave transmission data)
As shown in FIG. 145B, the slave transmission data consists of 1-byte "destination address data", 1-byte "source address data", 2-byte data called "input data", and 2-byte "CRC16" is arranged in this order. That is, in configuration example 2, the size (data length) is 6 bytes.

In configuration example 2, an example will be described in which preliminary input data (“slave 3 (preliminary) input data” and “slave 4 (preliminary) input data” in FIG. 144) is not included in the slave transmission data. However, the invention is not so limited. Backup input data may be included in the slave transmission data so that it can be applied even when the number of HB-LSIs set as slaves in the main control unit 600 increases for the purpose of function expansion or the like.

(destination address data, source address data)
The address data of the master (first HB-LSI 611) to be the transmission destination is set in the "destination address data" in the slave transmission data. Specifically, the address "07H" of the main control board 601 (master) is set as the "destination address data" in the slave transmission data.

The address data of the slave (HB-LSI) that is the transmission source is set in the "source address data" in the slave transmission data. Specifically, when slave transmission data is transmitted from the spinning drum device board 602 (slave 1) to the main control board 601 (master), the address data "04H" of the second HB-LSI 612 is changed to "source address data ” is set. On the other hand, when slave transmission data is transmitted from the door relay board 603 (slave 2) to the main control board 601 (master), the address data "06H" of the third HB-LSI 613 is set as the "source address data". be.

(Input data)
Input data corresponding to the type of the slave that is the transmission source is set to "input data" in the slave transmission data.

When transmitting slave transmission data from the drum device board 602 (slave 1) to the main control board 601 (master), the "input data" in the transmission data is, for example, the transmission of the configuration example 1 shown in FIG. Data similar to "slave 1 (second HB-LSI) input data" in the data is set. That is, in this case, in the second HB-LSI 612, detection data of various peripheral devices (reels, etc.) read via the "PI0" to "PI15" terminals (input terminals of the PIO circuit 705) are included in the slave transmission data. is set to the "input data" of

On the other hand, when slave transmission data is transmitted from the door relay board 603 (slave 2) to the main control board 601 (master), the "input data" in the transmission data includes, for example, Data similar to the "slave 2 (third HB-LSI) input data" in the transmission data is set. That is, in this case, in the third HB-LSI 613, detection data of various peripheral devices (various sensors, various switches, etc.) read via the "PI0" to "PI15" terminals (input terminals of the PIO circuit 705) are Set to "input data" in slave transmission data.

(CRC16)
2-byte error detection code data calculated using the "input data" is set to "CRC16" in the slave transmission data.

[11-9-4. Data transmission operation example 2 in synchronous serial communication]
Next, an operation example 2 for transmitting transmission data in the configuration example 2 (FIG. 145) in the main control unit 600 will be described. In the transmission data transmission operation example 2, the synchronous serial communication is performed at an interval equal to or less than the periodic interrupt processing cycle (1 interrupt time: 1.1172 ms) performed by the main CPU, and is executed and controlled by the controller 706. be. Further, in the transmission operation example 2 of the transmission data described below, a case where no transmission error occurs during transmission of the transmission data will be described.

In addition, in transmission operation example 2 of transmission data, the transmission operation of master transmission data performed when the destination is slave 1 and the transmission operation of master transmission data performed when the destination is slave 2 are continuously performed. shall be performed. In this case, the order of the former data transmission operation and the latter data transmission operation is arbitrary. In addition, the present invention is not limited to this, and the former data transmission operation and the latter data transmission operation are not performed continuously, but are performed independently and periodically (at an interval equal to or less than the period of the periodic interrupt processing). It may be configured to

In addition, in the transmission operation example 2 of transmission data, the transmission operation of the slave transmission data from the slave 1 to the master starts when the slave 1 receives the master transmission data, and the slave transmission data is transmitted from the slave 2 to the master. It is assumed that operation starts when slave 2 receives master transmission data. Note that the present invention is not limited to this, and the transmission operation of the slave transmission data in each slave is independent of the reception timing of the master transmission data, and is independent and periodic (interval equal to or less than the period of periodic interrupt processing). may be performed at

(Data transmission operation when the destination of master transmission data is slave 1)
First, the data transmission operation when the master transmission data is transmitted from the main control board 601 (master) to the spinning drum device board 602 (slave 1) will be described.

First, in the main control board 601 (first HB-LSI 611), the address (04H) of slave 1 (second HB-LSI 612) is set to the "destination address" in the master transmission data, and the master (first HB-LSI 611) address (07H) is set to the "source address".

Next, in the main control board 601 (first HB-LSI 611), the data to be output from the output port of slave 1 (second HB-LSI 612) is set to "output data" in the master transmission data by the memory-mapped IO method. , the display data of the information display device 14 are "7-segment display data 1-1" to "7-segment display data 1-4 (shared use)", "state display data (shared use)" and "7-segment display data (shared use)" in the master transmission data. Display data 2-1” to “7-segment display data 2-3”.

At this time, "7-segment display data 1-1" to "7-segment display data 1-4 (shared)" are set in the first segment registers 0 to 3 (not shown) provided in the first HB-LSI 611, respectively. , “state display data (shared)” are set in the first segment register 4 (not shown) provided in the first HB-LSI 611 . At this time, "7-segment display data 2-1" to "7-segment display data 2-3" are set in the second segment registers 0 to 2 (not shown) provided in the first HB-LSI 611, respectively. . Since the information display device 14 is not connected to the reel device board 602 (slave 1), arbitrary data can be set as the display data of the information display device 14. FIG.

Next, 2-byte error detection code data (CRC16) is calculated using various data set in the first HB-LSI 611, and the calculation result is set in "CRC16" in the master transmission data. Then, in the main control board 601 (first HB-LSI 611), when the above-described master transmission data setting processing (master transmission data generation processing) ends, the generated master transmission data is transferred to the first HB-LSI 611 (serial bus The information is transmitted from the communication circuit 701) to the reel device board 602 (second HB-LSI 612) via an optical fiber cable.

Next, when the second HB-LSI 612 (serial bus communication circuit 701) of the reel device board 602 receives the master transmission data, the second HB-LSI 612 converts the data of the "destination address" included in the master transmission data. It is read, and determination processing of whether or not it is its own address (04H) is performed. If the "destination address" data is its own address, the "output data" included in the master transmission data is read, and if the "destination address" data is not its own address, the first The master transmission data is transferred to the door relay board 603 without reading the “output data” by the 2HB-LSI 612 .

In the operation example just described, the data of the "destination address" is the address of itself (the second HB-LSI 612). The "output data" is set to the "PO0" to "PO15" terminals of the second HB-LSI 612 (output terminals of the PIO circuit 705).

At this time, the display data included in the master transmission data is also temporarily read into the LED drive circuit 703 in the second HB-LSI 612, but since the information display device 14 is not connected to the second HB-LSI 612, the LED The control by the drive circuit 703 becomes idle control.

Also, in the second HB-LSI 612 that received the master transmission data addressed to the slave 1, the address (07H) of the master (the first HB-LSI 611) is set to the "destination address" in the slave transmission data, and its own address ( 04H) is set to the "source address". Next, in the second HB-LSI 612, the detection data of various peripheral devices (reel, etc.) read via the “PI0” to “PI15” terminals (input terminals of the PIO circuit 705) are converted into the “input data ” is set.

Next, in the second HB-LSI 612, error detection code data (CRC16) is calculated using various data set in the slave transmission data, and the calculation result is set in "CRC16" in the slave transmission data. When the slave transmission data setting process (transmission data generation process) is completed, the generated slave transmission data is transferred from the reel device board 602 (second HB-LSI 612) through the optical fiber cable to the door relay board. 603 (third HB-LSI 613).

Next, when the third HB-LSI 613 (serial bus communication circuit 701) of the door relay board 603 receives the slave transmission data from the reel device board 602, the third HB-LSI 613 receives the "transmission data" included in the slave transmission data. The data of "destination address" is read, and determination processing of whether or not it is its own address (06H) is performed. In the operation example just described, the "destination address" data is not the address of itself (the 3rd HB-LSI 613). The slave transmission data is transferred to the main control board 601 without being transferred.

Next, when the slave transmission data transferred from the door relay board 603 is received by the first HB-LSI 611 (serial bus communication circuit 701) of the main control board 601, the first HB-LSI 611 reads " The data of "destination address" is read, and determination processing of whether or not it is its own address (07H) is performed. In the operation example just described, the data of the "destination address" is the address of itself (the first HB-LSI 611). Detection data of various peripheral devices (reels, etc.) are read.

Then, the main CPU acquires the read "input data" (detection data of various peripheral devices (such as reels)) from the first HB-LSI 611 via the bus 606 (including a data bus and an address bus). Thereby, the main CPU can grasp the state of various peripheral devices (reels, etc.) connected to the spinning drum device board 602 .

(Communication operation when the destination of master transmission data is slave 2)
Next, a data transmission operation when master transmission data is transmitted from the main control board 601 (master) to the door relay board 603 (slave 2) will be described.

First, in the main control board 601 (first HB-LSI 611), the address (06H) of slave 2 (third HB-LSI 613) is set to the "destination address" in the master transmission data, and the master (first HB-LSI 611) address (07H) is set to the "source address".

Next, in the main control board 601 (first HB-LSI 611), the data to be output from the output port of slave 2 (third HB-LSI 613) is set to "output data" in the master transmission data by the memory-mapped IO method. , the display data of the information display device 14 are "7-segment display data 1-1" to "7-segment display data 1-4 (shared use)", "state display data (shared use)" and "7-segment display data (shared use)" in the master transmission data. Display data 2-1” to “7-segment display data 2-3”.

Next, 2-byte error detection code data (CRC16) is calculated using various data set in the first HB-LSI 611, and the calculation result is set in "CRC16" in the master transmission data. Then, in the main control board 601 (first HB-LSI 611), when the above-described master transmission data setting processing (master transmission data generation processing) ends, the generated master transmission data is transferred to the first HB-LSI 611 (serial bus The information is transmitted from the communication circuit 701) to the reel device board 602 (second HB-LSI 612) via an optical fiber cable.

Next, when the second HB-LSI 612 (serial bus communication circuit 701) of the reel device board 602 receives the master transmission data, the second HB-LSI 612 converts the data of the "destination address" included in the master transmission data. It is read, and determination processing of whether or not it is its own address (04H) is performed. In the operation example just described, the data of the "destination address" is not the address of itself (the second HB-LSI 612), so the "output data" included in the master transmission data is The master transmission data is transmitted (transferred) to the door relay board 603 without being read.

Next, when the master transmission data transmitted (transferred) from the drum device board 602 is received by the third HB-LSI 613 (serial bus communication circuit 701) of the door relay board 603, the third HB-LSI 613 receives the master transmission data. The data of the "destination address" included in the is read, and determination processing of whether or not it is the own address (06H) is performed.

In the operation example just described, the data of the "destination address" is the address of itself (the 3rd HB-LSI 613). The "output data" are read and set to the "PO0" to "PO15" terminals of the third HB-LSI 613 (output terminals of the PIO circuit 705).

Also, at this time, various display data included in the master transmission data are read in the third HB-LSI 613 , and the various display data are input to the LED drive circuit 703 in the third HB-LSI 613 . In the third gaming machine, since the information display device 14 is connected to the third HB-LSI 613, the display operation of the information display device 14 is controlled based on the input various display data. At this time, the type of display data read by the third HB-LSI 613 differs depending on the type of gaming machine. Specifically, when the game machine is a normal game machine, among the various display data included in the master transmission data, "7-segment display data 1-1" to "7-segment display data 1-4 (shared )” and “status display data (common)” are read, and if the gaming machine is a medalless gaming machine, “7-segment display data 1-3 (common)”, “7-segment display data 1-4 (common) )”, “status display data (common use)”, and “7-segment display data 2-1” to “7-segment display data 2-3” are read.

Also, in the 3rd HB-LSI 613 which received the master transmission data addressed to the slave 2, the address (07H) of the master (1st HB-LSI 611) is set to the "destination address" in the slave transmission data, and its own address ( 06H) is set to the "source address". Next, in the third HB-LSI 613, detection data of various peripheral devices (various sensors, various switches, etc.) read via the “PI0” to “PI15” terminals (input terminals of the PIO circuit 705) are included in the slave transmission data. is set to the "input data" of

Next, in the third HB-LSI 613, error detection code data (CRC16) is calculated using various data set in the slave transmission data, and the calculation result is set in "CRC16" in the slave transmission data. When the slave transmission data set processing (transmission data generation processing) is completed, the generated slave transmission data is transferred from the door relay board 603 (third HB-LSI 613) to the main control board 601 via the optical fiber cable. (first HB-LSI 611).

Next, when the slave transmission data transmitted from the door relay board 603 is received by the first HB-LSI 611 (serial bus communication circuit 701) of the main control board 601, the first HB-LSI 611 stores " The data of "destination address" is read, and determination processing of whether or not it is its own address (07H) is performed. In the operation example just described, the data of the "destination address" is the address of itself (the first HB-LSI 611). Detection data of various peripheral devices (various sensors, various switches, etc.) are read.

Then, in the main CPU, "input data" (detection data of various peripheral devices (various sensors, various switches, etc.)) read from the first HB-LSI 611 via the bus 606 (including a data bus and an address bus) is is obtained. Thereby, the main CPU can grasp the state of various peripheral devices (various sensors, various switches, etc.) connected to the door relay board 603 .

[11-10. Various effects obtained with the third gaming machine]
In the third game machine, as described above, in the main control unit 600, each relay board is provided with an input/output port, and the input/output port is connected to an external peripheral device (reel, various switches, various sensors, etc.). equipment) are connected, and the main control board 601 and each relay board are connected by communication cables. Therefore, in the third game machine, the number of connection ports (input/output ports) with external peripheral devices provided on the main control board 601 can be reduced, thereby reducing the size of the main control board 601. be able to.

In addition, in the third gaming machine, the main control board 601 and each relay board are connected by communication cables. Therefore, in the third gaming machine, it is possible to reduce the number of harnesses connecting between the main control board 601 and each relay board.

Also, in the third gaming machine, an external peripheral device is connected to the input/output port of each relay board. Therefore, in the third gaming machine, it is possible to shorten the length of the wiring cable connecting between the external peripheral device and the input/output port to which it is connected.

Further, as described in FIG. 141, in a conventional gaming machine (see, for example, Japanese Unexamined Patent Application Publication No. 2018-027130), a RAM (main RAM) on the main control side is used to store generated command data. There is a need. Furthermore, as a limitation peculiar to game machines, the capacity that can be used in the main RAM of the main controller is restricted to a small capacity by regulation. Therefore, in a configuration in which a main RAM is used to store command data as in a conventional gaming machine, the capacity of the main RAM for use in other processes is squeezed.

On the other hand, in the third game machine, as described above, when data is transmitted from the main control unit 600 to the sub control unit 620 (asynchronous serial communication), the first HB-LSI 611 mounted on the main control board 601 (see FIGS. 142 and 142), and then transmits the command data. That is, in the third game machine, a data buffer (transmission data storage area) used for communication is provided outside the microprocessor (main RAM) mounted on the main control board 601 . Therefore, in the third game machine, there is no need to secure a storage area (storage area) for the data to be transmitted to the sub-controller 620 in the main RAM in the microprocessor, and that area can be used for the processing of game characteristics. can be assigned to a workspace for use in As a result, in the third gaming machine, it is possible to reduce pressure on the capacity of the main RAM caused by restrictions specific to the gaming machine.

In addition, in the configuration of a conventional general game machine, the necessary number of ICs (Integrated Circuits) for PIO circuits are mounted on the main control board, and the main control board is directly or indirectly connected to reels, switches, etc. (relay board via). On the other hand, in the configuration of the third gaming machine described above, one HB-LSI 700 (first HB-LSI 611) provided on the main control board 601 is directly or indirectly connected to reels, switches, etc. Therefore, the configuration is simplified and the cost can be reduced as compared with conventional general game machines.

In addition, in each board on the main side of the conventional game machine, as described above, there are an ASIC (master) equipped with a random number generation circuit, a PIO circuit, and a serial bus communication circuit between the master and slave, a PIO circuit, and a An ASIC (slave) comprising a serial bus communication circuit and an LED drive circuit, and an ASIC (security LSI) comprising an asynchronous serial communication circuit (encrypted communication circuit) between the main and sub circuits are separately provided. The configuration of the HB-LSI 700 mounted on each board on the main side of the gaming machine No. 3 is a configuration in which these conventional three types of ASICs are combined into one. Therefore, in the third gaming machine, the configuration can be further simplified and the cost can be further reduced as compared with the conventional general gaming machine. Further, in the third game machine, the HB-LSI 700 mounted on each board has the same configuration (specification), so the cost can be further reduced.

Furthermore, conventionally, when synchronous serial communication is performed between master and slave between boards in the main control unit, a technique has been proposed in which one error detection code data (CRC) is added to every 2-byte data. In the third game machine, as described above, one error detection code data (CRC16) is added to each packet of game control data group. Therefore, in the third game machine, the volume of transmission data transmitted and received by synchronous serial communication between the master and the slave can be reduced as compared with the conventional technique.

[11-11. Note]
In a conventional game machine, a CPU (Central Processing Unit) of a main control unit is proposed to be connected to an input/output port, a basic random number generator, etc. via an internal bus (for example, Japanese Patent Laid-Open No. 2009-268481). Gazette).

However, for example, in the gaming machine disclosed in Japanese Patent Application Laid-Open No. 2009-268481, since the main control device is provided with an input/output port, the main control device includes, for example, an input device such as a start lever, a reel, etc. output devices must be connected via wiring cables (for example, what is called a flat cable that can be connected with a harness). Therefore, in the configuration of the conventional game machine, there was a problem that the number of wiring cables connected to the board increased, and the size of the board of the main control device increased. In addition, in the configuration of the conventional game machine, there is also the problem that the wiring cables between the board of the main control device and the peripheral devices are long.

The present invention has been made in view of these points, and is a game that can reduce the board size of the main control unit and shorten the length of the wiring cable that connects the main control unit and peripheral devices. The purpose is to provide

In order to achieve the above object, according to the gaming machine according to the present embodiment, it is possible to provide a gaming machine having the following configuration.

A main control unit (for example, a main control unit 600) that controls the progress of the game;
A sub-control unit (for example, sub-control unit 620) that controls the production device according to the command from the main control unit;
A plurality of peripheral devices connected to the main control unit and capable of inputting and/or outputting signals with the main control unit,
The main control unit has at least a main control board and a plurality of relay boards (for example, a reel device board 602 and a door relay board 603),
Each of the main control board and the plurality of relay boards includes a signal input/output unit (for example, a PIO circuit 705) for inputting and outputting the signal, and a first communication unit capable of communicating with the outside using a first communication method. (for example, serial bus communication circuit 701) and a second communication unit (for example, asynchronous serial communication circuit 702) capable of communicating with the outside by the second communication method (for example, HB-LSI 700) is implemented and
each of the plurality of peripheral devices is connectable to the signal input/output unit of the input/output communication means;
Between the main control board and the relay board, the first communication section built in the input/output communication means of the main control board and the first communication section built in the input/output communication means of the relay board A game machine characterized in that it is possible to perform communication by connecting with a device.

In the gaming machine of the present invention, the plurality of peripheral devices include an information display device capable of displaying information including the number of accumulated game values,
The input/output communication means includes a display driving section (for example, LED driving circuit 703) capable of executing the information display operation on the information display device, and a random number generating section (for example, , random number generation circuit 708) may be further incorporated.

In the gaming machine of the present invention, the first communication method is a synchronous serial communication method, the second communication method is an asynchronous serial communication method,
The second communication section built in the input/output communication means of the main control board and the sub control section may be connected to each other for communication.

In the gaming machine of the present invention, the signal input/output unit built in the input/output communication means has a plurality of input terminals (for example, "S0" to "S2" terminals) for setting addresses of the input/output communication means. is provided,
The address of the input/output communication means may be set by applying a voltage value to the plurality of input terminals for setting the address.

Further, in the gaming machine of the present invention, the second communication unit includes a first register (for example, first data set register 711) and a second register (for example, second data set register 712) in which transmission data is set. and a data buffer (e.g., transmission data buffer 718) into which transmission data is written from the first register and the second register,
When transmitting a transmission data group consisting of a plurality of transmission data transmitted in one transmission operation, among the plurality of transmission data included in the transmission data group, the transmission data other than the last transmission data is The transmission data that is set in the first register, written in the data buffer, and transmitted last is written in the data buffer after being set in the second register, and is transmitted last. After the transmission data is written in the data buffer, the transmission data group written in the data buffer may be transmitted to the outside.

Further, in the gaming machine of the present invention, the gaming machine is a medalless gaming machine,
The information display device may have a 5-digit 7-segment LED capable of displaying the information.

Further, in the gaming machine of the present invention, the random number generating section has a random number monitoring section (for example, a random number monitoring circuit 738) that monitors the predetermined period, which is the update period of the random number value,
The random number monitoring unit may determine that an abnormality (for example, "decrease in clock signal frequency") has occurred when the random number value is updated in a period equal to or longer than a specific period longer than the update period. .

In the gaming machine of the present invention, the random number monitoring unit sets first status information indicating that an abnormality has occurred and second status information indicating an abnormality history, and then sets the When the abnormality is resolved, the first status information is cleared, but the second status information may be retained until power is turned off without being cleared.

Further, in the gaming machine of the present invention, the first communication unit adds one error detection data (for example, "CRC16") to the transmission data group transmitted in one transmission operation. good too.

Further, in the gaming machine of the present invention, the main control board includes an arithmetic processing unit (for example, a main CPU) that performs arithmetic processing for controlling game operations; A first storage unit (eg, main ROM) that stores necessary information and a second storage unit (eg, main RAM) that stores information required for execution of the arithmetic processing by the arithmetic processing unit. A game control means (for example, a microprocessor 610) may be mounted separately from the input/output communication means.

According to the gaming machine of the present invention having the above configuration, the board size of the main control section can be reduced, and the length of the wiring cable connecting the main control section and the peripheral devices can be shortened.

[12. Fourth gaming machine]
Next, with reference to FIGS. 146 to 170, another specific example (one embodiment) of the pachi-slot machine will be described as a "fourth game machine." It should be noted that part or all of the configuration described as the fourth gaming machine in the present embodiment can be applied to other gaming machines described in the present embodiment. Part or all of the configuration described as the gaming machine in 1 can be applied to the configuration described as the fourth gaming machine in the present embodiment. In other words, an appropriate combination of these can be used as the invention according to the present embodiment.

[12-1. Appearance structure]
First, referring to FIGS. 146 and 147, the structure of the pachi-slot machine 901 as the fourth gaming machine will be described. 146 is a perspective view showing the external structure of the pachi-slot machine 901. FIG. FIG. 147 is a front view of the pachi-slot machine 901 with the front panel 910 of the pachi-slot machine 901 removed.

The pachi-slot machine 901 has an exterior body 902 as shown in FIG. The exterior body 902 has a cabinet 902a that houses reels, circuit boards, etc., and a front door 902b attached to the cabinet 902a so that it can be opened and closed.

Handles 907 are provided on both sides of the cabinet 902a (only the handle 907 on one side is shown in FIG. 146). This handle 907 is a recess that a carrier puts his/her hand on when carrying the pachi-slot machine 901 .

Inside the cabinet 902a, three reels 903L, 903C, and 903R are provided side by side. The reels 903L, 903C, and 903R are hereinafter also referred to as the left reel 903L, middle reel 903C, and right reel 903R, respectively. Each of the reels 903L, 903C, and 903R includes a reel body formed in a cylindrical shape, a translucent sheet material attached to the peripheral surface of the reel body, and the back surface of the sheet material irradiated from the inside of the reel body. It has a reel backlight (reel light source). A plurality of (for example, 21) patterns are drawn on the surface of the sheet material at predetermined intervals along the circumferential direction. Among the plurality of patterns, a part of the 7 red patterns (not shown) is translucent. In addition, the reel backlight (8th lamp group 1018, which will be described later) is controlled by the sub-control circuit 942, which will be described later, to turn on and off.

The front door 902 b includes a door body 909 , a front panel 910 and a light emitting display device 911 . The door body 909 is attached to the cabinet 902a using a hinge (not shown) so that it can be opened and closed. The hinge is provided at the left end of the door body 909 when the door body 909 is viewed from the front of the pachi-slot machine 901 .

The light-emitting display device 911 is provided above the door body 909 as shown in FIG. The light-emitting display device 911 includes a dot matrix section 1019 (see FIG. 147) composed of a plurality of light source sections arranged in a matrix and a cover member provided facing the dot matrix section 1019 of the front panel 910. have

The dot matrix unit 1019 turns on (blinks) a light source unit at an arbitrary location in a plurality of light source units, so that an arbitrary location of the design applied to the front panel 910 (a firework pattern in the pachislot machine 901) can be seen from the back. Illuminate. As a result, an effect is performed in which an arbitrary part of the design applied to the front panel 910 is made to emit light.

Display windows 904L, 904C, and 904R for displaying patterns drawn on the three reels 903L, 903C, and 903R are provided below the light-emitting display device 911 . Hereinafter, the display windows 904L, 904C, and 904R are also referred to as left display window 904L, middle display window 904C, and right display window 904R, respectively.

The display windows 904L, 904C, 904R are made of a transparent member such as an acrylic plate. The display windows 904L, 904C, 904R are provided at positions overlapping the arrangement areas of the three reels 903L, 903C, 903R when viewed from the front (player's side), and the three reels 903L, 903C, 903R. It is provided so as to be positioned in front (on the side of the player). Therefore, the player can visually recognize the three reels 903L, 903C and 903R provided behind the display windows 904L, 904C and 904R through the display windows 904L, 904C and 904R.

In the pachi-slot machine 901, the display windows 904L, 904C, 904R display a plurality of types of symbols drawn on the respective reels 903L, 903C, 903R when the rotation of the corresponding reels 903L, 903C, 903R provided behind them stops. Among them, the size is set so that three patterns arranged in succession can be displayed. That is, within the frames of the display windows 904L, 904C and 904R, upper, middle and lower areas are provided for each reel, and one symbol is displayed in each area.

A front panel 910 is attached to the top of the door body 909 . The front panel 910 includes an upper display portion 1001, a reel illumination portion 1002, reel side effect display portions 1003A and 1003B, edge effect display portions 1004A and 1004B, a reel lower display portion 1005, a specific information display portion 1006A, 1006B.

The upper display section 1001 is arranged above the light-emitting display device 911 , and the reel illumination section 1002 is arranged between the reels 903 L, 903 C, and 903 R and the light-emitting display device 911 . The reel side effect display section 1003A is arranged on the left side of the left reel 903L, and the reel side effect display section 1003B is arranged on the right side of the right reel 903R. The edge effect display portion 1004A is arranged on the left side of the reel side effect display portion 1003A, and the edge effect display portion 1004B is arranged on the right side of the reel side effect display portion 1003B. The reel lower display section 1005 is arranged below the reels 903L, 903C, and 903R. Specific information display sections 1006A and 1006B are arranged above the upper display section 1001 .

Upper display portion 1001, reel illumination portion 1002, reel side effect display portions 1003A and 1003B, edge effect display portions 1004A and 1004B, reel lower display portion 1005, and specific information display portions 1006A and 1006B are provided on door body 909 and will be described later. lamp group (first lamp group 1011 to seventh lamp group 1017, special lamp group 1120). The upper display section 1001, the reel illumination section 1002, the reel side effect display sections 1003A and 1003B, the edge effect display sections 1004A and 1004B, the reel lower display section 1005, and the specific information display sections 1006A and 1006B are various lamp groups ( Light from the first lamp group 1011 to the seventh lamp group 1017 and the special lamp group 1120) emits light.

For example, the reel side effect display portion 1003A is provided with three BET light emitting portions aligned in the vertical direction. The number of lights on the three BET light emitting parts indicates the number of medals (game value) used for one game. In the pachi-slot machine 901, the number of medals used for one game is set to 1-3. For example, when the number of medals used in one game is set to "1", one BET light emitting section (for example, the lowest BET light emitting section) lights up, and the other BET light emitting section (middle BET light emitting section) lights up. and the BET light emitting part located at the top) are extinguished.

A base portion 912 is formed in the center of the door body 909 as shown in FIG. The pedestal 912 is provided with various devices to be operated by the player (a medal slot 913, a MAX bet button 914, a 1 bet button 915, a start lever 916, and stop buttons 917L, 917C, and 917R).

A medal slot 913 is provided for receiving medals dropped into the pachi-slot machine 901 from the outside by a player. The medals received from the medal slot 913 are used for one game with a preset number (for example, 3) as the upper limit, and the amount exceeding the preset number is deposited inside the pachi-slot machine 901. (so-called credit function).

A MAX bet button 914 and a 1 bet button 915 are provided to determine the number of medals (game value) deposited inside the pachi-slot machine 901 to be used for one game. Below the base portion 912, as shown in FIG. 147, a checkout button 921 is provided. The checkout button 921 is provided for withdrawing (discharging) medals deposited inside the pachi-slot machine 901 to the outside.

A start lever 916 is provided to start rotation of all reels (903L, 903C, 903R). Stop buttons 917L, 917C and 917R are provided corresponding to the left reel 903L, middle reel 903C and right reel 903R, respectively, and each stop button is provided to stop rotation of the corresponding reel. The stop buttons 917L, 917C, and 917R are hereinafter also referred to as the left stop button 917L, middle stop button 917C, and right stop button 917R, respectively.

In addition, the base portion 912 is provided with a 7-segment display 906 (the “information display device 14” in the above-described first game machine) consisting of a 7-segment LED (Light Emitting Diode). The 7-segment display 906 displays the number of medals (game value) to be paid out to the player as a privilege (number of payouts) and the number of medals deposited inside the pachi-slot machine 901 (the number of credits (stored number)). , information such as the number of inserted medals (BET number) for playing a game is digitally displayed.

As shown in FIG. 146, a medal payout port 918, a medal receiving tray 919, speakers 920L and 920R, and the like are provided at the lower portion of the door body 909. As shown in FIG. The medal payout port 918 guides to the outside the medals discharged by driving the medal payout device 933, which will be described later. The medal receiving tray 919 stores medals discharged from the medal payout port 918 . Also, the speakers 920L and 920R output sounds such as sound effects and music corresponding to the content of the presentation.

Further, the door body 909 is provided with a waist panel display portion 1006 as shown in FIG. The waist panel display section 1006 is arranged above the speakers 920L and 920R. The waist panel display portion 1006 covers a light source portion (light source portion associated with the port number of No. 53) provided on the door body 909, which will be described later. Then, the waist panel display section 1006 emits light when irradiated with light from the light source section (the light source section associated with the port number of No. 53).

[12-2. Various lamp groups]
FIG. 148 is a diagram (LED layout port diagram) showing the arrangement of ports provided for a plurality of light source units that irradiate light to the various display units described above in the pachi-slot machine 901 . It should be noted that the various lamp groups described below are specific examples of the light emitting means according to the present invention.

As shown in FIG. 0 to No. 337, No. 400 and no. A light source unit with a port number of 401 (light source units with a total of 340 ports) is provided. At least one LED is arranged as a light emitter in the light source unit of each port number. Specifically, one LED is arranged in the light source part of the port number that emits light in a single color (white or orange), and the light source part (full color LED) of the port number that can emit full color light (multicolor light emission) is Three LEDs (a red light emitting LED, a green light emitting LED and a blue light emitting LED) or one LED in which three LED elements (a red light emitting element, a green light emitting element and a blue light emitting element) are combined are arranged. When a full-color LED is statically controlled, three LED elements (buffers) constitute one LED, so the combination of the light emission modes of the three LED elements determines the brightness and emission color of the full-color LED. Note that the full-color LED is one specific example of the multicolor light emitting means according to the present invention. In addition, in the present embodiment, an example in which an LED element is arranged in each light source (an example in which LEDs are used) will be described, but the present invention is not limited to this. You may arrange|position another light-emitting body.

Thirty-one light source units associated with port numbers No. 0 to No. 30 constitute a first lamp group 1011 . Then, the first lamp group 1011 irradiates the upper display portion 1001 (see FIG. 147) with light. Since the light emission mode of the first lamp group 1011 is full-color light emission, each light source section (each port) in the first lamp group 1011 has three LEDs (a red light emitting LED, a green light emitting LED and a blue light emitting LED). ) is provided.

Four light source units associated with port numbers No. 49 to No. 52 constitute a second lamp group 1012 . Then, the second lamp group 1012 emits light to the reel illumination section 1002 (see FIG. 147). Since the light emission mode of the second lamp group 1012 is full-color light emission, each light source section (each port) in the second lamp group 1012 has three LEDs (a red light emitting LED, a green light emitting LED and a blue light emitting LED). ) is provided.

The five light source units associated with port numbers No. 66 to No. 70 constitute the third lamp group 1013, and the five light source units associated with port numbers No. 71 to No. 75 constitute the fourth lamp. Construct the group 1014 . The third lamp group 1013 emits light to the reel side effect display portion 1003A (see FIG. 147), and the fourth lamp group 1014 emits light to the reel side effect display portion 1003B (see FIG. 147). The three light source units with port numbers No. 68 to No. 70 in the third lamp group 1013 are arranged to face the above-mentioned three BET light emitting units, and each light source unit lights up to correspond The BET light emitting unit to be played is illuminated. Further, since the light emission mode of the third lamp group 1013 and the fourth lamp group 1014 is full-color light emission, each light source section (each port) in the third lamp group 1013 and the fourth lamp group 1014 has three LEDs. (a red-emitting LED, a green-emitting LED and a blue-emitting LED) are provided.

Six light source units associated with port numbers No. 54 to No. 59 constitute the fifth lamp group 1015, and six light source units associated with port numbers No. 60 to No. 65 constitute the sixth lamp. Make up the group 1016 . The fifth lamp group 1015 emits light to the edge effect display portion 1004A (see FIG. 147), and the sixth lamp group 1016 emits light to the edge effect display portion 1004B (see FIG. 147). Since the light emission mode of the fifth lamp group 1015 and the sixth lamp group 1016 is full-color light emission, each light source section (each port) in the fifth lamp group 1015 and the sixth lamp group 1016 has three LEDs. (a red-emitting LED, a green-emitting LED and a blue-emitting LED) are provided.

The 49 light source units associated with port numbers No. 108 to No. 156 constitute the seventh lamp group 1017 . The seventh lamp group 1017 has 7-digit (7 pieces) 7-segment LEDs, and irradiates the reel lower display portion 1005 (see FIG. 147) with light. Each of the 7-segment LEDs included in the seventh lamp group 1017 represents a specific example of segment light-emitting means according to the present invention.

The 14 light source units associated with port numbers No. 108 to No. 121 in the seventh lamp group 1017 constitute 2-digit 7-segment LEDs. The accumulated number, which is the number of game values), is displayed. Twenty-one light source units associated with port numbers No. 122 to No. 142 in the seventh lamp group 1017 constitute three-digit seven-segment LEDs, and display, for example, the number of medals won during a bonus. The 14 light source units corresponding to port numbers No. 143 to No. 156 in the seventh lamp group 1017 constitute two-digit seven-segment LEDs, and display, for example, the number of medals to be paid out. Since the light emission mode of the seventh lamp group 1017 is monochromatic light emission, each light source section (each port) in the seventh lamp group 1017 is provided with one LED.

Thirty-six light source units associated with port numbers No. 31 to No. 48 and No. 76 to No. 93 constitute an eighth lamp group 1018 .

The six light source units associated with port numbers No. 31 to No. 36 in the eighth lamp group 1018 function as a reel light source (reel backlight) for the left reel 903L. The six light source units associated with port numbers No. 37 to No. 42 in the eighth lamp group 1018 function as reel light sources (reel backlights) for the middle reel 903C. The six light source units corresponding to port numbers No. 43 to No. 48 in the eighth lamp group 1018 function as reel light sources (reel backlights) for the right reel 903R. Since the light emission mode of the eighth lamp group 1018 is full-color light emission, each light source section (each port) in the eighth lamp group 1018 has three LEDs (a red light emitting LED, a green light emitting LED and a blue light emitting LED). ) is provided.

The 177 light source units associated with port numbers No. 161 to No. 337 constitute the dot matrix unit 1019 . The dot matrix portion 1019 functions as a light source of the light emitting display device 911 (see FIG. 146). Since the dot matrix section 1019 emits light in a single color, each light source section (each port) in the dot matrix section 1019 is provided with one LED.

Although the dot matrix section 1019 of the present embodiment uses monochromatic LEDs, all the LEDs of the group of monochromatic LEDs constituting the dot matrix section 1019 or the required number of LEDs are used in full color. The dot matrix section 1019 may be configured with a light-emitting LED to enhance the rendering effect. In this case, in the dot matrix unit 1019, the port number (the number of ports) used by the LEDs for full-color light emission is three times as large as that for single-color light emission, depending on the number of LEDs for full-color light emission. You will need the port number.

Two light source units 1120 a and 1120 b associated with port numbers No. 400 and No. 401 constitute a special lamp group 1120 . The light sources 1120a and 1120b irradiate the specific information display sections 1006A and 1006B with light from below the specific information display sections 1006A and 1006B (see FIG. 147). Since each of the light source units 1120a and 1120b (special lamp group 1120) emits full-color light, each of the light source units 1120a and 1120b (each port) has three LEDs (a red LED, a green LED, and a A blue emitting LED) is provided. Each LED constituting the light source units 1120a and 1120b has a frequency of, for example, 110 Hz and is controlled to blink by static lighting with a duty ratio of 50%.

The light source units 1120a and 1120b are a group of lamps provided for lighting in colors corresponding to the state of the pachi-slot machine 901. FIG. Specifically, the light source units 1120a and 1120b are controlled by the sub CPU 981a described later (see FIG. ) to control light emission.

When the light source units 1120a and 1120b having such a configuration are provided, for example, a data display device (not shown) having a camera such as a CMOS image sensor is provided in the island facility above the pachislot machine 901, and the camera of the data display device By photographing the specific information display portions 1006A and 1006B, the data display machine can recognize the state of the pachi-slot machine 901. FIG. By recognizing the state of the pachi-slot machine 901, the data display machine can display game data, execute effects, and transmit information on the pachi-slot machine 901 to a management server (not shown).

The light source unit associated with the No. 53 port number illuminates the waist panel display unit 1006 (see FIG. 147). The light source unit associated with the port number No. 157 irradiates the MAX bet button 914 with light. The light source unit associated with port number No. 158 emits light to the left stop button 917L. The light source unit associated with the No. 159 port number illuminates the middle stop button 917C. Also, the light source unit associated with the port number No. 160 illuminates the right stop button 917R.

[12-3. Internal structure]
Next, the internal structure of the pachi-slot machine 901 will be described with reference to FIG. 149 is a perspective view showing the internal structure of the pachi-slot machine 901. FIG.

The cabinet 902a is formed of a substantially rectangular parallelepiped member with one open surface on the front side. A main substrate 931 constituting a main control circuit 941 (see FIG. 150, which will be described later) is provided in the upper part of the cabinet 902a. The main control circuit 941 is a circuit that controls the main operations of the game in the pachi-slot machine 901, such as determining the internal winning combination, spinning and stopping each reel, and determining whether or not a prize has been won, and the flow between the operations. A specific configuration of the main control circuit 941 will be described later.

Three reels (a left reel 903L, a middle reel 903C and a right reel 903R) are provided in the central part within the cabinet 902a. Although not shown in FIG. 149, each reel is connected to a corresponding stepping motor (one of stepping motors 961L, 961C, and 961R in FIG. 150, which will be described later) through a gear having a predetermined reduction ratio. be done.

A medal payout device 933 (hereinafter referred to as a hopper 933) having a structure capable of accommodating a large amount of medals and discharging them one by one is provided in the lower part of the cabinet 902a.

Inside the cabinet 902a, one side of the hopper 933 (the right side in the example shown in FIG. 149) is provided with a medal auxiliary storage 937 for storing medals overflowing from the hopper 933. As shown in FIG. A power supply device 934 is provided on the other side of the hopper 933 (the left side in the example shown in FIG. 149) in the cabinet 902a to supply necessary power to each device of the pachi-slot machine 901. .

A sub-board 932 constituting a sub-control circuit 942 (see FIGS. 150 and 151 to be described later) is provided on the upper portion of the rear surface side (the portion opposite to the display screen side) of the front door 902b. The sub-control circuit 942 is a circuit that controls execution of effects such as video display. A specific configuration of the sub-control circuit 942 will be described later.

Further, a selector 935 is provided at a substantially central portion on the rear side of the front door 902b. The selector 935 is a device for selecting whether or not the material, shape, etc. of medals inserted from the outside through the medal slot 913 (see FIG. 146) are appropriate. guide to. Also, although not shown in FIG. 149, a medal sensor 935S (see FIG. 150 described later) is provided on the path through which the medals pass in the selector 935 for detecting that a proper medal has passed.

[12-4. Electrical Configuration of Pachislot Machine]
Next, the circuit configuration of the pachi-slot machine 901 will be described with reference to FIGS. 150 and 151. FIG. FIG. 150 is a block configuration diagram of the entire circuit provided in the pachi-slot machine 901. As shown in FIG. FIG. 151 is a block diagram showing the internal configuration of the sub-control circuit 942. As shown in FIG.

As shown in FIG. 150, the pachi-slot machine 901 comprises a main control circuit 941, a sub-control circuit 942, and peripheral devices (actuators) electrically connected to these circuits.

[12-4-1. Main control circuit]
The main control circuit 941 is mainly composed of a microcomputer 950 installed on the circuit board (main board 931). Other components of the main control circuit 941 include a clock pulse generation circuit 954, a frequency divider 955, a random number generator 956, a sampling circuit 957, a display drive circuit 964, a hopper drive circuit 965, and a payout completion signal circuit. Including 966.

The microcomputer 950 is a so-called one-chip microcomputer composed of a main CPU 951, a main ROM (Read Only Memory) 952, a main RAM (Random Access Memory) 953, and various built-in circuits (not shown).

The main ROM 952 stores control programs for various processes executed by the main CPU 951, data tables such as an internal lottery table, data for transmitting various control instructions (commands) to the sub-control circuit 942, and the like. . The main RAM 953 is provided with a storage area for storing various data such as an internal winning combination determined by executing the control program.

A clock pulse generation circuit 954 , a frequency divider 955 , a random number generator 956 and a sampling circuit 957 are connected to the main CPU 951 . A clock pulse generation circuit 954 and a frequency divider 955 generate clock pulses. Note that the main CPU 951 executes the control program based on the generated clock pulse. Also, the random number generator 956 generates random numbers within a predetermined range (eg, 0 to 65535). The sampling circuit 957 then extracts one value from the generated random numbers.

Various switches and sensors are connected to the input port of the microcomputer 950 . The main CPU 951 receives input signals from various switches and the like, and controls operations of peripheral devices such as stepping motors 961L, 961C, and 961R.

The stop switch 917S detects that the left stop button 917L, middle stop button 917C, and right stop button 917R have been pressed by the player (stop operation). The stop switch 917S represents a specific example of stop operation detection means according to the present invention. The start switch 916S detects that the start lever 916 has been operated by the player (start operation). It should be noted that the start switch 916S represents a specific example of the start operation detection means according to the present invention. The settlement switch 914S detects that the settlement button 921 has been pressed by the player.

The medal sensor 935S detects that the medal inserted into the medal slot 913 has passed through the selector 935 . Note that the medal sensor 935S represents a specific example of the insertion operation detection means according to the present invention. Also, the bet switch 912S detects that a bet button (MAX bet button 914 or 1 bet button 915) has been pressed by the player.

Peripheral devices whose operations are controlled by the microcomputer 950 include three stepping motors 961L, 961C, 961R, a 7-segment display 906, and a hopper 933. Further, the output port of the microcomputer 950 is connected with a drive circuit for controlling the operation of each peripheral device.

A motor drive circuit 962 controls driving of three stepping motors 961L, 961C, and 961R provided corresponding to the left reel 903L, middle reel 903C, and right reel 903R, respectively. A reel position detection circuit 963 detects a reel index indicating that the reel has made one rotation for each reel by means of an optical sensor having a sensor light emitting portion and a sensor light receiving portion.

Each of the three stepping motors 961L, 961C, and 961R has a momentum proportional to the number of pulse outputs, and has a configuration capable of stopping the rotating shaft at a specified angle. Also, the driving force of each stepping motor is transmitted to the corresponding reel via a gear having a predetermined reduction ratio. Each time one pulse is output to each stepping motor, the corresponding reel rotates at a constant angle. The three reels 903L, 903C, 903R and the three stepping motors 961L, 961C, 961R represent a specific example of the variable display means according to the present invention.

After detecting the reel index of each reel, the main CPU 951 counts the number of times a pulse is output to the corresponding stepping motor to determine the rotation angle of each reel (specifically, how many symbols the reel has). only rotated).

Here, management of the rotation angle of each reel will be specifically described. The number of pulses output to each stepping motor is counted by a pulse counter (not shown) provided in the main RAM 953 . Then, each time the pulse counter counts the pulse output a predetermined number of times (for example, 16 times) required for one symbol rotation, the value of the symbol counter (not shown) provided in the main RAM 953 is changed to "1". ” is added. A symbol counter is provided for each reel. The symbol counter value is cleared when the reel position detection circuit 963 detects the reel index.

That is, in the pachi-slot machine 901, by managing the value of the symbol counter, it is managed how many symbols have been rotated since the reel index was detected. Therefore, the position of each symbol on each reel is detected with reference to the position where the reel index is detected.

Note that the display drive circuit 964 controls the operation of the 7-segment display 906 . Hopper drive circuit 965 controls the operation of hopper 933 . A payout completion signal circuit 966 manages medal detection performed by a medal detection unit 933S provided in the hopper 933, and checks whether or not the number of medals discharged outside from the hopper 933 has reached a predetermined payout number. Also, an external terminal board 918S is connected to the main control circuit 941 . The main control circuit 941 is connected to the hall computer or calling device 1000 via the external terminal board 918S.

[12-4-2. Sub control circuit]
The sub-control circuit 942 is electrically connected to the main control circuit 941 as shown in FIG. The sub control circuit 942 has a sub microprocessor 981 , sub ROM 982 , sub RAM 983 , oscillation circuit 984 , backup RAM 985 , RTC (Real-Time Clock) 986 and battery 987 . The sub-control circuit 942 also has a sound IC (Integrated Circuit) 988 for driving the speaker group (speakers 920L, 920R) connected to the sub-control circuit 942 .

Further, the sub-control circuit 942 has a plurality of lamps for driving various lamp groups (first lamp group 1011 to eighth lamp group 1018, dot matrix section 1019, special lamp group 1120) connected to the sub-control circuit 942. It has an LED driver IC (LED driver IC 1021 to LED driver IC 1030 described later). It should be noted that the LED driver IC represents a specific example of the light emission driving means according to the present invention. In the pachi-slot machine 901 of this embodiment, the maximum number of LED driver ICs that can be mounted in the sub-control circuit 942 is 32, of which 24 LED driver ICs are mounted in the sub-control circuit 942 . In FIG. 151, three LED driver ICs that are used as dummies this time and are not actually mounted are indicated by dashed lines.

The sub microprocessor 981 has a sub CPU 981a, an internal RAM 981b and a synchronous serial communication circuit 981c. The sub microprocessor 981 represents a specific example of control means according to the present invention.

The sub CPU 981a controls the output of sound and light during execution of the effect in accordance with the control program stored in the sub ROM 982 in accordance with the command transmitted from the main control circuit 941 .

The built-in RAM 981b has a buffer area (hereinafter referred to as a “lamp buffer”) that stores light emission drive data (light emission data) for driving (lighting/flashing/lighting out) each LED included in each lamp group. . The internal RAM 981b is directly connected to the synchronous serial communication circuit 981c. Therefore, when the light emission drive data is set (stored and stored) in the lamp buffer in the built-in RAM 981b, the lamp data, which will be described later, including the light emission drive data is directly transmitted from the lamp buffer through the synchronous serial communication circuit 981c. is sent to the LED driver IC group consisting of the LED driver ICs. That is, the lamp buffer provided in the built-in RAM 981b also operates as a communication buffer for lamp data, which will be described later. The configuration of the ramp buffer and the configuration of the light emission drive data stored in the ramp buffer will be described in detail with reference to FIGS. 155 and 156 described later. The ramp buffer is a specific example of data storage means according to the present invention.

The synchronous serial communication circuit 981c is a communication circuit for transmitting lamp data, which will be described later, to an LED driver IC group consisting of a plurality of LED driver ICs. A synchronous serial driver (API: Application Program Interface) (not shown) is provided in the synchronous serial communication circuit 981c. is sent. In this embodiment, as a synchronous communication method, a clock synchronous two-wire serial communication method (I2C compliant: data line/clock line) is adopted. : data line, clock line, select line) may be adopted. The synchronous serial communication circuit 981c is a specific example of the light emission data transmission means according to the present invention.

Depending on the circuit configuration of the synchronous serial communication circuit 981c, the synchronous serial communication circuit 981c may have a built-in buffer (communication buffer). may be used as a ramp buffer for Even if the synchronous serial communication circuit 981c having such a configuration is used, the sub CPU 981a can set (store or memorize) the light emission driving data in the lamp buffer.

The sub ROM 982 basically has a program storage area and a data storage area. Various control programs executed by the sub CPU 981a are stored in the program storage area of the sub ROM 982 . The control program stored in the program storage area includes, for example, a main board communication task for controlling communication with the main control circuit 941, a random number value for effect extraction, determination of effect content (effect data), and A production registration task for registration, a lamp control task for controlling light output from various lamp groups (including the dot matrix unit 1019) based on the decided production content, and a control of sound output from the speakers 920L and 920R. programs such as a sound control task for In addition, the data storage area of the sub ROM 982 includes, for example, a storage area for storing various data tables, a storage area for storing effect data constituting various effect contents, a storage area for storing sound effect data related to BGM and sound effects, Various storage areas are included, such as a storage area for storing lamp effect data relating to the pattern of turning on and off the light.

The sub-RAM 983 is composed of a rewritable storage device with a higher access speed than the sub-ROM 982, and can be composed of, for example, a DRAM (Dynamic Random Access Memory) or an SRAM (Static Random Access Memory). The sub-RAM 983 has a storage area for registering determined performance contents and performance data, and a performance state storage area for storing various data such as game states and internal winning combinations transmitted from the main control circuit 941 .

The oscillation circuit 984 is a circuit (clock generation circuit) for generating (oscillating) a clock of a predetermined frequency, for example, 22 MHz, for operating the sub CPU 981a.

The backup RAM 985 is composed of a rewritable non-volatile memory that does not require a power supply, and can be composed of, for example, FRAM (Ferroelectric Random Access Memory) (registered trademark). The backup RAM 985 can be composed of, for example, an SRAM. In this case, the battery 987 that supplies power to the RTC 986 is also connected to the SRAM.

In addition, the backup RAM 985 includes a date and time storage area for storing the date and time measured by the RTC 986, a game information area for storing information on the game state of the sub-control circuit 942 and information on performance, and a storage area for storing error information history. and a storage area for storing various settings of the pachi-slot machine 901 set in the hall menu. In addition, in the game information area of the backup RAM 985, at any timing (for example, when the power supply to the sub-control circuit 942 is cut off (when a power failure occurs), when a start command is received, etc.) Various data stored in the effect state storage area are copied. Various data stored in the game information area of the backup RAM 985 are copied to the effect state storage area of the sub RAM 983 immediately after the power-on process (see FIG. 162 described later). In the pachi-slot machine 901, by copying various data stored in the game information area of the backup RAM 985 to the effect state storage area of the sub RAM 983, it is possible to restart the game effect that was being executed before the power was turned on. .

When the pachislot machine 901 is powered on, the RTC 986, like the electronic components mounted on the sub-control circuit 942, operates with power supplied from a power supply board (not shown) to keep time. On the other hand, when the power supply of the pachi-slot machine 901 is in an off state, it operates by the power supplied from the battery 987 to keep the date and time. Also, the RTC 986 is connected to the sub CPU 981a by an I2C (Inter-Integrated Circuit), and transmits date and time data representing the date and time measured in response to a request from the sub CPU 981a to the sub CPU 981a. The battery 987 is composed of, for example, a primary battery such as a coin-shaped lithium battery, a lithium ion secondary battery, or the like.

Sound IC 988 is connected to speakers 920L and 920R. The sound IC 988 is connected to the sub CPU 981a by serial bus communication, and outputs audio ("stereo" or "monaural") signals such as BGM from the speakers 920L and 920R according to the sound data transmitted from the sub CPU 981a. Specifically, the sound IC 988 is composed of a digital amplifier. The sound IC 988 converts the sound data received from the sub CPU 981a according to the volume set in the initialization process (see S501 in FIG. 162 described later) during the power-on process described later and the volume stored in the sub RAM 983. converts (and "amplifies") to an audio signal.

[12-4-3. LED driver IC group]
The sub-control circuit 942 has an LED driver IC group consisting of 24 LED driver ICs, as shown in FIG. In addition, in this embodiment, the 24 LED driver ICs have the same configuration. However, the present invention is not limited to this, and at least some of the 24 LED driver ICs may include LED driver ICs with different configurations (for example, configurations with different numbers of output ports, different gradations, etc.). . Also, in FIG. 151, "ADR:**" assigned to each LED driver IC indicates an address (decimal number) assigned to each LED driver IC. For example, "ADR:23" assigned to the LED driver IC 1027 indicates that the address of the LED driver IC 1027 is "23" in decimal ("10111B" in binary and "17H" in hexadecimal).

The sub-control circuit 942 is provided with four LED driver ICs 1021 a to 1021 d connected to the first lamp group 1011 for driving the first lamp group 1011 . The sub control circuit 942 is provided with one LED driver IC 1022 connected to the second lamp group 1012 for driving the second lamp group 1012 . The sub control circuit 942 is provided with one LED driver IC 1023 connected to the third lamp group 1013 for driving the third lamp group 1013 . The sub control circuit 942 is provided with one LED driver IC 1024 connected to the fourth lamp group 1014 for driving the fourth lamp group 1014 .

The sub control circuit 942 is provided with one LED driver IC 1025 connected to the fifth lamp group 1015 for driving the fifth lamp group 1015 . The sub-control circuit 942 is connected to the sixth lamp group 1016 and provided with one LED driver IC 1026 for driving the sixth lamp group 1016 . The sub control circuit 942 is provided with one LED driver IC 1027 connected to the seventh lamp group 1017 for driving the seventh lamp group 1017 . The sub-control circuit 942 is connected to the eighth lamp group 1018 and provided with five LED driver ICs 1028 a to 1028 e for driving the eighth lamp group 1018 .

The sub-control circuit 942 is provided with eight LED driver ICs 1029 a to 1029 h connected to the dot matrix section 1019 and for driving the dot matrix section 1019 . Also, the sub-control circuit 942 is provided with one LED driver IC 1030 connected to the special lamp group 1120 for driving the special lamp group 1120 .

Each LED driver IC is connected to a synchronous serial communication circuit 981c in the sub microprocessor 981 by serial bus communication. Also, each LED driver IC is connected to other LED driver ICs so as to be able to transmit and receive data. Each LED driver IC is composed of an LED driver IC with 64 gradations or 127 gradations.

In this embodiment, when the sub microprocessor 981 (synchronous serial communication circuit 981c) transmits each light emission drive data for driving each lamp group to emit light to the LED driver IC group (LED driver ICs 1021 to 1030), For each LED driver IC, the data (data set) in which the address data of the LED driver IC and the corresponding light emission drive data are combined into one transmission data (hereinafter referred to as "lamp Data": see FIGS. 155 and 156 described later) is sent to the LED driver IC group. At this time, the transmitted lamp data is transmitted so as to circulate in a predetermined order within the 24 LED driver ICs (LED driver IC group), but the transmission order of the lamp data within the LED driver IC group is arbitrary. can be set to

Upon receiving the lamp data transmitted to the LED driver IC group, each LED driver IC acquires light emission drive data associated with its own address from the lamp data. Specifically, each LED driver IC has its own address setting terminals (“AD0” terminal to “AD4” terminal described later in FIG. 152) set (ON/OFF), and lamp data. The included address data is compared, and if the comparison result indicates a match, light emission drive data corresponding to (added to) 24 bytes corresponding to the address data is obtained from the lamp data. As will be described later, the valid bits of the light emission drive data for each port number included in the lamp data are 6-bit data, not 1-byte (8-bit) data. The amount of data stored is not 24 bytes. Therefore, it is expressed here as "light emission drive data corresponding to 24 bytes".

Further, the mode of transmitting the lamp data is not limited to the above mode of the present embodiment. It may be transmitted separately for each LED driver IC. Also in this case, the transmission order of the data can be arbitrarily set. In this case, for example, only data sets in which the light emission drive data has changed may be transmitted to the corresponding LED driver ICs. In this case, the transmission time of the light emission drive data can be shortened.

The lamp data transmitted from the sub microprocessor 981 (synchronous serial communication circuit 981c) is transmitted in a predetermined order between the 24 LED driver ICs (within the LED driver IC group). At this time, each LED driver IC that has received the lamp data acquires light emission drive data associated with its own address from the lamp data. The transmission order of the lamp data within the LED driver IC group can be arbitrarily set.

[12-4-4. Mode of Connection between Seventh Lamp Group and LED Driver IC]
In this embodiment, among the first lamp group 1011 to eighth lamp group 1018, the dot matrix section 1019, and the special lamp group 1120, the lamp groups other than the seventh lamp group 1017 are driven by static control. Group 1017 is driven by dynamic control.

FIG. 152 shows the connection relationship between the seventh lamp group 1017 and the LED driver IC 1027 that drives it. In the following description, as shown in FIG. 152, the number of accumulated medals is displayed among seven-digit (seven) seven-segment LEDs (hereinafter referred to as "seven-segment LEDs") constituting the seventh lamp group 1017. The 2-digit 7-segment LEDs are called “1st segment” and “2nd segment”, and the 3-digit 7-segment LEDs that display the number of medals acquired during the bonus are “3rd segment” to “5th segment”. , and the two-digit 7-segment LED that displays the number of medals to be paid out will be referred to as the “sixth segment” and the “seventh segment”.

In addition, the 3rd to 5th segments (three-digit 7-segment LEDs) receive push order information (left stop button 917L, middle stop button 917L, middle stop button 917C and the pressing order of the right stop button 917R) is transmitted ("AT state" and "ART state" in the above-described first gaming machine), the pressing order information of the internal winning combination may be displayed. In this case, any one of the 3rd to 5th segments is displayed according to the pressing order information of the internal winning combination, or the pressing order code corresponding to the pressing order information of the internal winning combination is displayed in the 4th segment.

For example, when displaying any of the 3rd to 5th segs according to the pressing order information of the internal winning combination, when the start command is received, if the first stop is the middle stop button 917C, the number is displayed on the 4th seg. "1" (information determined in S532 and S533 in FIG. 165 to be described later) is displayed. Also, when the reel stop command is received, if the second stop is the left stop button 917L, the number "2" (information determined in S535 in FIG. 165 described later) is displayed in the third segment, and the third stop is displayed. If it is the right stop button 917R, the number "3" (information determined in S535 in FIG. 165 described later) is displayed in the fifth segment.

On the other hand, for example, when the pressing order code corresponding to the pressing order information of the internal winning combination is displayed in the fourth segment, if the first stop is the right stop button 917R when the start command is received, the character " R" (information determined in S532 and S533 in FIG. 165 to be described later) is displayed. Also, when the reel stop command is received, if the second stop is the middle stop button 917C, a code imitating the letter "C" (information determined in S535 in FIG. 165 described later) is displayed in the fourth segment, If the third stop is the left stop button 917L, a code imitating the letter "L" (information determined in S535 in FIG. 165 described later) is displayed in the fourth segment.

In addition, when the main control circuit 941 and/or the sub-control circuit 942 detects the occurrence of an error, the sixth segment and the seventh segment (two-digit seven-segment LED) display the number of medals paid out instead of displaying the number of medals. , the error code (the error code corresponding to the error state of the first game machine and the lamp effect data (display data) registered in S573 in FIG. 167) are displayed. Note that the error code may be displayed by the first and second segments (2-digit 7-segment LED) instead of the sixth and seventh segments.

(7 segment LED)
The 1st to 7th segments have the same configuration. Each 7-segment LED of the 1st segment to the 7th segment is composed of 7 segments A to G (LED elements), as shown in FIG. ).

A 7-segment LED has one anode terminal and seven cathode terminals a to g. Note that the configuration of the 7-segment LED that can be used in this embodiment is not limited to the example shown in FIG. For example, a 7-segment LED having segments called dot segments may be used in addition to the 7 segments A to G as the segments constituting the 7-segment LED. FIG. 153 is a block diagram of a 7-segment LED with dot segments. The dot segment H is normally provided near the lower right corner of the 7-segment LED on the top of FIG. 153 (on the display surface of the 7-segment LED). In the 7-segment LED having the dot segment H, in addition to the seven cathode terminals a to g provided for the segments A to G, one cathode terminal h corresponding to the dot segment is provided.

(Configuration of LED driver IC)
As shown in FIG. 152, the LED driver IC 1027 has four communication terminals, a "CLK_IN" terminal, a "CLK_OUT" terminal, a "DATA_IN" terminal and a "DATA_OUT" terminal. The 'CLK_IN' terminal and 'CLK_OUT' terminal are connected to the clock line in the I2C-compliant serial communication method, and the 'DATA_IN' terminal and the 'DATA_OUT' terminal are connected to the data line in the I2C-compliant serial communication method. . Note that LED driver ICs other than the LED driver IC 1027 also have the same configuration as the LED driver IC 1027 shown in FIG.

The "CLK_IN" terminal is an input (receiving) terminal for a synchronization clock signal for synchronizing the serial data input to the "DATA_IN" terminal. The "CLK_IN" terminal is connected to the output (transmission) terminal of the synchronous clock signal (not shown) of the sub microprocessor 981 (synchronous serial communication circuit 981c) or the output (transmission) from the "CLK_OUT" terminal of another LED driver IC. synchronous clock signal is input.

For example, when the lamp data is first transmitted to the LED driver IC 1027 in the transmission order of the lamp data, the "CLK_IN" terminal of the LED driver IC 1027 is connected to the synchronous clock of the sub microprocessor 981 (synchronous serial communication circuit 981c). A synchronizing clock signal output from a clock signal output terminal is input. On the other hand, for example, when the lamp data is transmitted to the LED driver IC 1027 in the second or subsequent order in the transmission order of the lamp data, the "CLK_IN" terminal of the LED driver IC 1027 is connected to the lamp one before the LED driver IC 1027. A synchronizing clock signal output from the "CLK_OUT" terminal of another LED driver IC to which data is to be sent is input.

A "CLK_OUT" terminal is an output (transmission) terminal for a synchronization clock signal. The "CLK_OUT" terminal outputs (transmits) the synchronizing clock signal input to the "CLK_IN" terminal of the LED driver IC 1027 as it is to the "CLK_IN" terminal of another LED driver IC or ground (hereinafter referred to as "GND"). ) to (through).

For example, when the lamp data is transmitted to the LED driver IC 1027 last in the transmission order of the lamp data, a synchronizing clock signal is output (transmitted) from the "CLK_OUT" terminal of the LED driver IC 1027 to GND. On the other hand, for example, when the lamp data is transmitted to the LED driver IC 1027 in an order other than the last in the transmission order of the lamp data, another LED to which the next lamp data is transmitted from the "CLK_OUT" terminal of the LED driver IC 1027 A synchronous clock signal is output (transmitted) to the "CLK_IN" terminal of the driver IC.

A “DATA_IN” terminal is an input (receiving) terminal for lamp data (serial data). The "DATA_IN" terminal receives data output (transmitted) from the serial data output (transmission) terminal (not shown) of the sub microprocessor 981 (synchronous serial communication circuit 981c) or from the "DATA_OUT" terminal of another LED driver IC. Ramp data is entered.

For example, when the lamp data is first transmitted to the LED driver IC 1027 in the transmission order of the lamp data, the "DATA_IN" terminal of the LED driver IC 1027 receives the serial data of the sub microprocessor 981 (synchronous serial communication circuit 981c). Ramp data output from the output terminal of is input. On the other hand, for example, when the lamp data is transmitted to the LED driver IC 1027 in the second or later order in the transmission order of the lamp data, the "DATA_IN" terminal of the LED driver IC 1027 is connected to the lamp one before the LED driver IC 1027. Lamp data output from the "DATA_OUT" terminal of another LED driver IC to which data is to be sent is input.

A "DATA_OUT" terminal is an output (transmission) terminal for lamp data (serial data). The "DATA_OUT" terminal outputs (transmits) (through) the lamp data input to the "DATA_IN" terminal of the LED driver IC 1027 as it is to the "DATA_IN" terminal of another LED driver IC or GND.

For example, when the lamp data is transmitted to the LED driver IC 1027 last in the transmission order of the lamp data, the lamp data is output (transmitted) from the "DATA_OUT" terminal of the LED driver IC 1027 to GND. On the other hand, for example, when the lamp data is transmitted to the LED driver IC 1027 in an order other than the last in the transmission order of the lamp data, another LED to which the next lamp data is transmitted from the "DATA_OUT" terminal of the LED driver IC 1027 Lamp data is output (transmitted) to the "DATA_IN" terminal of the driver IC.

In the transmission mode (transmission path) of the lamp data within the group of LED driver ICs in this embodiment, a plurality of LED driver ICs are connected in series to the sub microprocessor 981. The invention is not so limited. As is clear from the mode of connection between the sub microprocessor 981 and various LED driver ICs shown in FIG. A connected configuration is also possible. In this case, the "CLK_OUT" terminals and "DATA_OUT" terminals of all the LED driver ICs are connected to GND, and all the LED driver ICs output (transmit) the synchronization clock signal and lamp data to GND (through). .

In this embodiment, the LED driver IC is provided on the sub control circuit 942. For example, an LED driver IC (Master IC) dedicated to relay is provided between the sub microprocessor 981 and the LED driver IC. , the LED driver ICs 1021 to 1030 may be arranged on LED substrates corresponding to respective lamp groups. In this case, a plurality of LED driver ICs are connected in series and/or in parallel according to the internal structure (see FIG. 149) of the pachi-slot machine 901 including the lamp group and the sub-control circuit 942 . For example, a relay dedicated LED driver IC (Master IC) provided on the sub-control circuit 942 and the LED driver IC 1021a, the LED driver ICs 1022 to 1027, the LED driver IC 1028a, the LED driver IC 1029a and the LED driver IC 1030 are connected in parallel. LED driver ICs 1021a to 1021d, LED driver ICs 1028a to 1028e, and LED driver ICs 1029a to 1029h are connected in series.

In addition, as shown in FIG. 152, the LED driver IC 1027 has “AD0” to “AD4” terminals which are five address setting terminals. Each address setting terminal is connected to a 5V power supply (ON=1) or GND (OFF=0), and the connection mode of the five address setting terminals (ON/OFF mode: 5-bit value (binary number)) sets the address of the LED driver IC.

For example, in the LED driver IC 1027, the "AD0" to "AD2" terminals and the "AD4" terminal are connected to the 5V power supply, and the "AD3" terminal is connected to GND. becomes "10111B" (binary). That is, as the address of the LED driver IC 1027, "17H" in hexadecimal and "23" in decimal are set. In the 5-bit value indicating the address of the LED driver IC, the 0-bit to 4-bit values (0/1) correspond to the OFF/ON mode of the "AD0" terminal to "AD4" terminal, respectively. "AD" of terminals "AD0" to "AD4" means "Address", and terminals "AD0" to "AD4" are input ports.

Further, the LED driver IC 1027 has 24 output terminals, “P0” to “P23”, as shown in FIG. Each output terminal is appropriately connected to, for example, the anode terminal or cathode terminal of the corresponding 7-segment LED, GND, or the like. "P" of terminals "P0" to "P23" means "port", and terminals "P0" to "P23" are output ports.

The “P0” to “P6” terminals of the LED driver IC 1027 are connected to the anode terminals of the 1st to 7th segments, respectively, as shown in FIG. Drive signals corresponding to anode selection data “A0” to “A6” (7-byte light emission drive data), which will be described later, are output from “P0” to “P6” terminals of the LED driver IC 1027, respectively. to the anode terminals of the seventh segment, respectively.

The “P8” to “P14” terminals of the LED driver IC 1027 are connected to the cathode terminals a to g of the 7-segment LEDs (1st to 7th segments, respectively), as shown in FIG. . Although not shown in FIG. 152 for simplification of explanation, cathode terminals a to g of each 7-segment LED (first segment to seventh segment, respectively) are connected to terminals “P8” to “ P14” terminal is connected in parallel.

Drive signals corresponding to segment data “C0” to “C6” (7-byte light emission drive data), which will be described later, are output from the “P8” to “P14” terminals of the LED driver IC 1027, respectively. (1st segment to 7th segment, respectively) are input to cathode terminals a to g, respectively. In the configuration of this embodiment, since the light emission operation of the seventh lamp group 1017 is dynamically controlled, segment data (cathode output data), which will be described later, is provided for all seven-segment LEDs constituting the seventh lamp group 1017. Although it is input, only the 7-segment LEDs selected by anode selection data, which will be described later, are lit by reflecting the segment data, and the other 7-segment LEDs are not lit.

Also, the “P7” terminal and the “P15” to “P23” terminals of the LED driver IC 1027 are connected to GND as shown in FIG. That is, in the LED driver IC 1027, the "P7" terminal and the "P15" to "P23" terminals are not used. However, when all the 7-segment LEDs constituting the seventh lamp group 1017 are composed of 7-segment LEDs having dot segments H shown in FIG. Any one of the "P23" terminals (for example, the "P15" terminal) is connected to the cathode terminal h of each 7-segment LED. In this case, light emission drive data for driving the dot segment H is set in segment data "C7" (8-bit (1 byte) light emission drive data), which will be described later.

Although not shown in FIG. 152, each LED driver IC is provided with an output setting terminal. Each LED driver IC can set the output of the output terminal to either constant current output or sink output according to the state (High/Low) of the output setting terminal. That is, in each LED driver IC, the output mode can be set to either constant current output or sink output according to the connection state of the LED.

In addition, each LED driver IC has a 6-bit register corresponding to the number of output terminals (“P0” terminal to “P23” terminal) corresponding to each output terminal (channel), and a 6-bit register corresponding to each. A PWM circuit (not shown) for the number of output terminals is built in. The PWM circuit generates a drive signal with a duty ratio according to the value set in the register, and the generated drive signal (PWM signal) is sent to each output terminal. (channel) with a period of 63 μs. For example, when the value of the register is "63", a drive signal with a duty ratio of 100% (that is, a pulse width of 63 μs) is output to the corresponding output terminal (channel) from the LED driver IC, and the corresponding output terminal The LED connected to (channel) emits at the highest brightness (100%). On the other hand, when the value of the register is "0", a drive signal with a duty ratio of 0% (that is, a pulse width of 0) is output from the LED driver IC to the corresponding output terminal (channel). channel) is extinguished.

(Comparative example)
In order to clarify the characteristics of the connection mode between the seventh lamp group 1017 and the LED driver IC when the seventh lamp group 1017 shown in FIG. 152 is dynamically controlled, the seventh lamp group 1017 is shown in FIG. The connection mode between the seventh lamp group 1017 and the LED driver IC for control is shown. The LED driver IC shown in FIG. 154 has 24 output terminals (“P0” terminal to “P23” terminal in FIG. 154) like the LED driver IC used in this embodiment.

When driving 7-digit (7 pieces) 7-segment LEDs (1st segment to 7th segment) by static control, the anode terminal of each 7-segment LED is connected to a 5V power supply. In this case, the output terminal for cathode connection of the LED driver IC is separately connected for each 7-segment LED.

In the example shown in FIG. 154, terminals “P0” to “P6” of the LED driver IC are connected to the cathode terminals 1-a to 1-g of the first segment, respectively, and “P8” of the LED driver IC is connected. The terminals to "P14" are connected to the cathode terminals 2-a to 2-g of the second segment, respectively, and the terminals "P16" to "P22" of the LED driver IC are connected to the cathode terminals of the third segment. 3-a to cathode terminal 3-g. However, in this case, as is clear from FIG. 154, one LED driver IC cannot control all the 7-digit 7-segment LEDs (1st segment to 7th segment). Since 49 output terminals are required to drive a 7-digit 7-segment LED by static control, it is necessary to prepare 3 LED driver ICs each having 24 output terminals.

On the other hand, as in the pachi-slot machine 901 of the present embodiment, when the seventh lamp group 1017 composed of seven-digit (seven) seven-segment LEDs is dynamically controlled, as shown in FIG. It suffices to prepare one LED driver IC having output terminals. Therefore, as in the pachislot machine 901 of the present embodiment, when the seventh lamp group 1017 composed of 7-digit (7 pieces) 7-segment LEDs is dynamically controlled, the LED driver mounted in the sub-control circuit 942 The number of ICs can be reduced, and the price and development cost of the pachislot machine 901 can be reduced.

[12-5. Ramp buffer and ramp data]
(Overall configuration of ramp buffer)
155 and 156 are diagrams showing the configuration of the ramp buffer provided in the built-in RAM 981b. 155 and 156 show the relationship between the type of light source unit (port number) assigned to each 1-byte buffer area constituting the lamp buffer and the address of each LED driver IC. For convenience of explanation, FIGS. 155 and 156 also show the correspondence relationship between the address of each LED driver IC and the type of lamp group driven and controlled by each LED driver IC. 156. The buffer area corresponding to the "dummy lamp" described in the "lamp group" column in FIG. ADR: 24-26)”) is a buffer area provided corresponding to ADR.

155 and 156, "ADR: 0" to "ADR: 23" described in the "Driver Address" column are assigned to the 24 LED driver ICs mounted on the sub-control circuit 942. are the address values (0 to 23 (decimal)), and "ADR: 24" to "ADR: 26" are for the three LED driver ICs (dummy) that are not mounted on the sub-control circuit 942 this time. is the address value assigned by As described above, the address value corresponds to the connection (ON/OFF) setting of the five address setting terminals (“AD0” terminal to “AD4” terminal shown in FIG. 152) provided in the LED driver IC. handle. Addresses described as "static" in the "driver address" column mean that the LED driver ICs corresponding to the addresses are statically controlled by the sub CPU 981a, and addresses described as "dynamic" are , means that the LED driver IC corresponding to the address is dynamically controlled by the sub CPU 981a. Indicates that the LED driver IC is not mounted.

155 and 156, in the column of "Ramp buffer allocation mode for each port number (each light source unit)", the lamp buffer configuration has one square in which one number indicating the port number of the light source unit is written. (For example, one square with "161" etc. in FIG. 155) corresponds to a 1-byte buffer area (hereinafter referred to as "ramp buffer unit area"). In addition, in FIGS. 155 and 156, unused ramp buffer unit areas are marked with "-". As will be described later, a PWM (Pulse Wide Modulation) value (drive pulse duty ratio) corresponding to luminance (0% to 100%) is set (stored or stored) in the lamp buffer unit area as light emission drive data. be done.

Further, the characters "(R)", "(G)", and "(B)" added next to the port number of the light source described in each lamp buffer unit area in FIGS. A red light emitting LED, a green light emitting LED, and a blue light emitting LED that constitute the light source unit of the port number are shown. For example, in the buffer area assigned to the first ramp group 1011 in the ramp buffer, the ramp buffer unit area described as "0 (R)" is the No. 1 in the first ramp group 1011. A buffer area assigned to a red light-emitting LED associated with a port number of 0, and a lamp buffer unit area described as “0 (G)” corresponds to No. 1 in the first lamp group 1011 . A buffer area assigned to the green light emitting LED associated with the port number 0, and the lamp buffer unit area described as "0 (B)" corresponds to No. 1 in the first lamp group 1011. This is the buffer area allocated for the blue light emitting LED associated with port number 0. FIG. Therefore, in lamp groups such as the first lamp group 1011 to the sixth lamp group 1016, the eighth lamp group 1018, and the special lamp group 1120, the light source portion of each port number is composed of three LEDs (full-color LEDs). , a 3-byte buffer area is assigned to each light source unit (each port number).

On the other hand, in a lamp group such as the dot matrix portion 1019 in which the light source portion of each port number is composed of one LED (single-color light emitting LED), as shown in FIGS. Only the number of the port number of the light source unit is described. For example, in the buffer area assigned to the dot matrix section 1019 in the ramp buffer, the ramp buffer unit area described as “161” is the No. 1 in the dot matrix section 1019 . 161 is a buffer area allocated to LEDs associated with port numbers.

155 and 156, the notation of the lamp buffer unit area of the seventh lamp group 1017 is different from the notation of the other lamp groups, and port numbers are indicated in each lamp buffer unit area assigned to the seventh lamp group 1017. However, this is because the seventh lamp group 1017 is driven by dynamic control, and the port number of the 7-segment LED to be controlled, that is, the light source section to be controlled, changes with time. The configuration of the buffer area assigned to the seventh lamp group 1017 will be detailed later.

In the ramp buffers shown in FIGS. 155 and 156, the ramp buffer unit area indicated as "0(R)" in FIG. 0 (B)", ..., "2 (R)", "2 (G)", "2 (B)", ..., "5 (R)", "5 (G)", ..., "5 ( R)", "5 (G)", ..., "7 (B)", "8 (R)", ..., "10 (G)", "10 (B)", ..., "155", " 156”, the lamp buffer unit areas are arranged in terms of addresses.

In the pachi-slot machine 901 of this embodiment, each LED driver IC has 24 output ports (see FIG. 152). A 24-byte buffer area is provided (assigned) for each address. In this embodiment, an LED driver IC with 12 output ports can also be used. is provided (assigned).

In addition, in the pachi-slot machine 901 of the present embodiment, 24 LED driver ICs are mounted in the sub-control circuit 942, but as described above, the maximum number of LED driver ICs that can be mounted in the sub-control circuit 942 is The lamp buffer provided in the built-in RAM 981b is also provided with a buffer area of a size capable of supporting 27 LED driver ICs. That is, the lamp buffer includes a buffer area of 72 bytes allocated to the addresses "24" to "26" of the three LED driver ICs that are not mounted this time, and is provided in the built-in RAM 981b. The total size of the ramp buffer is 648 bytes (24 bytes x 27).

155 and 156, four LED driver ICs assigned addresses (ADR) "0" to "3" are four LED driver ICs 1021a to 1021d for driving the first lamp group 1011. correspond to each other. The eight LED driver ICs assigned addresses (ADR) "4" to "11" correspond to the eight LED driver ICs 1029a to 1029h for driving the dot matrix section 1019, respectively. The LED driver ICs assigned addresses (ADR) "12", "13", "14", "15" and "16" are LED driver ICs 1022 for driving the second lamp group 1012, The LED driver IC 1023 for driving the lamp group 1013, the LED driver IC 1024 for driving the fourth lamp group 1014, the LED driver IC 1025 for driving the fifth lamp group 1015, and the sixth lamp group 1016 are driven. corresponds to the LED driver IC 1026 for

155 and 156, the five LED driver ICs assigned addresses (ADR) "17" to "21" are five LED driver ICs 1028a to 1028a for driving the eighth lamp group 1018. 1028e respectively. The LED driver IC assigned address (ADR) “22” corresponds to LED driver IC 1030 for driving special lamp group 1120 . The LED driver IC assigned the address (ADR) “23” corresponds to the LED driver IC 1027 for driving the seventh lamp group 1017 . The addresses (ADR) “24” to “26” are addresses that can be assigned to the three LED driver ICs that are not mounted on the sub-control circuit 942 this time.

(Configuration of Buffer Area Assigned to Each Lamp Group Statically Controlled)
In this embodiment, as shown in FIGS. 155 and 156, in the lamp buffer, buffer areas (inside the lamp buffer) allocated to four LED driver ICs with addresses (ADR) "0" to "3" ), the light emission drive data for driving the first lamp group 1011 is stored. Specifically, port numbers No. 0 to No. 30 (see FIG. 148) are assigned to the lamp buffer unit areas of the 1st to 93rd bytes in the buffer area for the first lamp group 1011, respectively. Light emission drive data for each light emission color (red, green, and blue) for driving the 31 light source units are stored in ascending order of the port number from the leading side. Each lamp buffer unit area from the 93rd byte in the buffer area for the first lamp group 1011 to the end of the buffer area is an unused area. The buffer area of the lamp group (for example, the first lamp group 1011, etc.) configured by light source units (full-color LEDs) emitting multicolor light is a specific example of the first storage area according to the present invention. .

In the lamp buffer, a dot Light emission drive data for driving the matrix section 1019 is stored. Specifically, port numbers No. 161 to No. 337 (see FIG. 148) are assigned to each lamp buffer unit area from the first byte to the 177th byte in the buffer area for the dot matrix section 1019. The light emission drive data for driving the 177 light source units are stored in ascending order of the port number from the leading side. Each ramp buffer unit area from the 178th byte in the buffer area for the dot matrix section 1019 to the end of the buffer area is an unused area.

In the lamp buffer, a second lamp group 1012 is stored in the buffer area (area of 289th to 312th bytes in the lamp buffer) allocated to one LED driver IC with address (ADR) "12". light emission driving data for driving is stored. Specifically, the port numbers No. 49 to No. 52 (see FIG. 148) are assigned to the lamp buffer unit areas from the head (1st byte) to 12th byte in the buffer area for the second lamp group 1012, respectively. ) are stored in ascending order of the port number from the top side, for each emission color (red, green, and blue) for driving the four light source units. Each lamp buffer unit area from the 13th byte in the buffer area for the second lamp group 1012 to the end of the buffer area is an unused area.

In the lamp buffer, the buffer area (the 313rd byte to 336th byte area in the lamp buffer) allocated to one LED driver IC with the address (ADR) “13” is used for the third lamp group 1013. Light emission driving data for driving is stored. Specifically, port numbers No. 66 to No. 70 (see FIG. 148) are assigned to each lamp buffer unit area from the head (1st byte) to 15th byte in the buffer area for the third lamp group 1013. ) are stored in ascending order of the port number from the top side, for each emission color (red, green, and blue) for driving the five light source units. Each lamp buffer unit area from the 16th byte in the buffer area for the third lamp group 1013 to the end of the buffer area is an unused area.

A fourth lamp group 1014 is stored in a buffer area (337th to 360th bytes in the lamp buffer) allocated to one LED driver IC with an address (ADR) of "14" in the lamp buffer. light emission driving data for driving is stored. Specifically, port numbers No. 71 to No. 75 (see FIG. 148) are assigned to the respective lamp buffer unit areas from the first byte to the 15th byte in the buffer area for the fourth lamp group 1014. ) are stored in ascending order of the port number from the top side, for each emission color (red, green, and blue) for driving the five light source units. Each lamp buffer unit area from the 16th byte in the buffer area for the fourth lamp group 1014 to the end of the buffer area is an unused area.

A fifth lamp group 1015 is stored in a buffer area (361st to 384th bytes in the lamp buffer) allocated to one LED driver IC with an address (ADR) of "15" in the lamp buffer. light emission driving data for driving is stored. Specifically, port numbers No. 54 to No. 59 (see FIG. 148) are assigned to each lamp buffer unit area from the head (1st byte) to 18th byte in the buffer area for the fifth lamp group 1015. ) are stored in ascending order of the port number from the head side for each emission color (red, green, blue) for driving the six light source units. Each lamp buffer unit area from the 19th byte in the buffer area for the fifth lamp group 1015 to the end of the buffer area is an unused area.

In the lamp buffer, a buffer area (385th byte to 408th byte area in the lamp buffer) allocated to one LED driver IC with an address (ADR) of "16" contains a sixth lamp group 1016. light emission driving data for driving is stored. Specifically, port numbers No. 60 to No. 65 (see FIG. 148) are assigned to the respective lamp buffer unit areas from the first byte to the 18th byte in the buffer area for the sixth lamp group 1016. ) are stored in ascending order of the port number from the head side for each emission color (red, green, blue) for driving the six light source units. Each lamp buffer unit area from the 19th byte to the end of the buffer area for the sixth lamp group 1016 is an unused area.

In the lamp buffer, the buffer area (409th byte to 528th byte area in the lamp buffer) allocated to the five LED driver ICs with addresses (ADR) "17" to "21" has the Light emission drive data for driving the 8 lamp group 1018 is stored. Specifically, No. 31 to No. 48 and No. 76 to No. 48 and No. 76 to No. 1 are assigned to the head (1st byte) to 108th byte lamp buffer unit areas in the buffer area for the eighth lamp group 1018, respectively. Light emission drive data for each light emission color (red, green, blue) for driving 36 light source units associated with 93 port numbers (see FIG. 148) are stored in ascending order of port number from the top. Each lamp buffer unit area from the 109th byte in the buffer area for the eighth lamp group 1018 to the end of the buffer area is an unused area.

In the lamp buffer, a special lamp group 1120 is allocated in the buffer area (529th byte to 552nd byte area in the lamp buffer) assigned to one LED driver IC with address (ADR) “22”. Light emission driving data for driving is stored. Specifically, port numbers No. 400 and No. 401 (see FIG. 148) are assigned to each lamp buffer unit area from the head (first byte) to the sixth byte in the buffer area for the special lamp group 1120 (see FIG. 148). The light emission drive data for each light emission color (red, green, and blue) for driving the two light source units are stored in ascending order of the port number from the head side. Each lamp buffer unit area from the 7th byte in the buffer area for the special lamp group 1120 to the end of the buffer area is an unused area.

(Configuration of Buffer Area Assigned to Dynamically Controlled Seventh Lamp Group)
In this embodiment, as shown in FIG. 156, a buffer area (553rd byte to 576th byte in the lamp buffer) allocated to one LED driver IC with address (ADR) "23" In the eye region), the seventh lamp group 1017, that is, the 1st segment to the 7th segment (49 light source units related to port numbers No. 108 to No. 156 (see FIGS. 148 and 152)). Light emission driving data for driving is stored.

Output to the anode terminals of the 1st segment to the 7th segment as light emission drive data in each lamp buffer unit area of the head (1st byte) to 7th byte in the buffer area for the 7th lamp group 1017. light emission drive data "A0" to "A6" (hereinafter referred to as "anode selection data") are stored. In the present embodiment, the seventh lamp group 1017 is composed of seven-digit 7-segment LEDs (first to seventh segments). A buffer unit area (a ramp buffer unit area described as "A7") becomes an unused area.

Of the seven lamp buffer unit areas in which the anode selection data "A0" to "A6" are respectively stored, the lamp buffer unit area corresponding to the 7-segment LED selected during dynamic control has the anode turned on. The light emission drive data for turning off the anode is stored in the lamp buffer unit area corresponding to the other (non-selected) 7-segment LED (see FIG. 157 described later). . The buffer area (anode area) in which the anode selection data "A0" to "A6" are stored is a specific example of the second storage area according to the present invention.

In addition, in each lamp buffer unit area of the 9th to 15th bytes in the buffer area for the seventh lamp group 1017, the 7-segment LEDs (1st to 7th segments) selected during dynamic control are respectively displayed. (any of the above) stores light emission drive data “C0(a)” to “C6(g)” (hereinafter referred to as “segment data”) output to the cathode terminal a of segment A to the cathode terminal g of segment G. be done. The buffer area (cathode area) in which the segment data "C0(a)" to "C6(g)" are stored is a specific example of the third storage area according to the present invention.

In this embodiment, since dot segments H are not provided for each of the 1st to 7th segment LEDs, the 16th byte lamp buffer unit area in the buffer area for the 7th lamp group 1017 (Ramp buffer unit area described as "C7") is an unused area. However, when each 7-segment LED is provided with a dot segment H (see FIG. 153), the 16th byte lamp buffer unit area in the buffer area for the seventh lamp group 1017 has a dot segment H. The light emission drive data "C7" output to the cathode terminal h is stored as segment data.

In this embodiment, since the first to seventh segments (seventh lamp group 1017) are dynamically controlled, the anode selection data "A0" to "A6" stored in the buffer area for the seventh lamp group 1017 ”, and the segment data “C0(a)” to “C6(g)” change each time the 7-segment LED (any of the 1st to 7th segments) to be selected switches during dynamic control. do. Specifically, the anode selection data “A0” to “A6” stored in the buffer area for the seventh lamp group 1017 are updated each time the lamp data is transmitted (every 2.3 msec), Each time the selection data is updated, the segment data stored within the buffer area for the seventh lamp group 1017 is also updated. When updating the segment data, segment data to be selected is read out from a buffer area for dummy lamps, which will be described later, according to the anode selection data set in the buffer area for the seventh lamp group 1017. , is set (stored) in the buffer area for the seventh lamp group 1017 .

Further, in the present embodiment, each lamp buffer unit area from the 17th byte in the buffer area for the seventh lamp group 1017 to the end of the buffer area is an unused area, but constitutes the seventh lamp group 1017. This unused area is used to further increase the number of 7-segment LEDs. That is, the unused area from the 17th byte in the buffer area for the seventh lamp group 1017 to the end of the buffer area is provided in preparation for increasing the number of 7-segment LEDs forming the seventh lamp group 1017. It also acts as a spare area for light emission drive data.

(Configuration of buffer area for dummy lamp)
In this embodiment, as shown in FIG. 156, in the lamp buffer, buffer areas (inside the lamp buffer) allocated to three unmounted LED driver ICs with addresses (ADR) "24" to "26" 577th byte to 648th byte area: hereinafter referred to as “dummy lamp buffer area”), all (seven) 7-segment LED segments A to G Light emission drive data output to each cathode terminal of (49 light source units associated with port numbers No. 108 to No. 156 (see FIG. 148)) is stored. The dummy lamp buffer area is a specific example of the fourth storage area according to the present invention.

In each lamp buffer unit area from the head (1st byte) to 7th byte in the buffer area for the dummy lamp, the cathode terminal a of segment A of the first segment (see FIG. 152) to the cathode terminal of segment G The light emission driving data to be output is stored in g (seven light source units associated with port numbers No. 108 to No. 114 (see FIG. 148)). When the first segment is selected during the dynamic control of the seventh lamp group 1017, the data is stored in each lamp buffer unit area of the 1st byte to the 7th byte in the dummy lamp buffer area. The light emission driving data is read out as segment data "C0(a)" to "C6(g)", and each lamp of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017 Each is set in a buffer unit area. Note that the 8th byte ramp buffer unit area in the dummy lamp buffer area is an unused area.

In each lamp buffer unit area of the 9th byte to the 15th byte in the buffer area for the dummy lamp, the cathode terminal a of the segment A of the second segment (see FIG. 152) to the cathode terminal g of the segment G (No. Light emission drive data output to seven light source units associated with port numbers .115 to No. 121 (see FIG. 148) are stored. When the second segment is selected during dynamic control of the seventh lamp group 1017, the data is stored in each lamp buffer unit area of the 9th to 15th bytes in the dummy lamp buffer area. The light emission driving data is read out as segment data "C0(a)" to "C6(g)", and each lamp of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017 Each is set in a buffer unit area. The 16th byte ramp buffer unit area in the dummy ramp buffer area is an unused area.

In each lamp buffer unit area of the 17th byte to the 23rd byte in the buffer area for the dummy lamp, the cathode terminal a of the segment A of the third segment (see FIG. 152) to the cathode terminal g of the segment G (No. 122 to No. 128 (7 light source units associated with port numbers (see FIG. 148)) are stored. When the third segment is selected during the dynamic control of the seventh lamp group 1017, the data is stored in each lamp buffer unit area of the 17th to 23rd bytes in the buffer area for the dummy lamp. The light emission driving data is read out as segment data "C0(a)" to "C6(g)", and each lamp of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017 Each is set in a buffer unit area. The 24th byte ramp buffer unit area in the dummy lamp buffer area is an unused area.

In each lamp buffer unit area of the 25th byte to the 31st byte in the buffer area for the dummy lamp, the cathode terminal a of the segment A of the fourth segment (see FIG. 152) to the cathode terminal g of the segment G (No. Light emission drive data output to seven light source units associated with port numbers .129 to No. 135 (see FIG. 148) are stored. Then, when the fourth segment is selected during the dynamic control of the seventh lamp group 1017, it is stored in each lamp buffer unit area of the 25th byte to the 31st byte in the dummy lamp buffer area. The light emission driving data is read out as segment data "C0(a)" to "C6(g)", and each lamp of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017 Each is set in a buffer unit area. Note that the 32nd byte ramp buffer unit area in the dummy ramp buffer area is an unused area.

In each lamp buffer unit area of the 33rd byte to the 39th byte in the dummy lamp buffer area, the cathode terminal a of the segment A of the fifth segment (see FIG. 152) to the cathode terminal g of the segment G (No. Light emission drive data output to seven light source units associated with port numbers .136 to No. 142 (see FIG. 148) are stored. When the 5th segment is selected during dynamic control of the 7th lamp group 1017, it is stored in each lamp buffer unit area of the 33rd byte to the 39th byte in the dummy lamp buffer area. The light emission driving data is read out as segment data "C0(a)" to "C6(g)", and each lamp of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017 Each is set in a buffer unit area. Note that the 40th byte ramp buffer unit area in the dummy ramp buffer area is an unused area.

In each lamp buffer unit area of the 41st to 47th bytes in the dummy lamp buffer area, the cathode terminal a of the segment A of the sixth segment (see FIG. 152) to the cathode terminal g of the segment G (No. 143 to No. 149 (seven light source units associated with port numbers (see FIG. 148)) are stored. When the sixth segment is selected during the dynamic control of the seventh lamp group 1017, the data is stored in each lamp buffer unit area of the 41st to 47th bytes in the dummy lamp buffer area. The light emission drive data is read out as segment data “C0(a)” to “C6(g)”, and each lamp of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017 Each is set in a buffer unit area. Note that the 48th byte ramp buffer unit area in the dummy lamp buffer area is an unused area.

In addition, in each lamp buffer unit area of the 49th byte to the 55th byte in the buffer area for the dummy lamp, the cathode terminal a of the segment A of the seventh segment (see FIG. 152) to the cathode terminal g of the segment G are respectively provided. (Seven light source units associated with port numbers No. 150 to No. 156 (see FIG. 148)) store light emission driving data to be output. When the seventh segment is selected during the dynamic control of the seventh lamp group 1017, the data is stored in each lamp buffer unit area of the 49th to 55th bytes in the dummy lamp buffer area. The light emission driving data is read out as segment data "C0(a)" to "C6(g)", and each lamp of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017 Each is set in a buffer unit area. Each ramp buffer unit area from the 56th byte in the dummy ramp buffer area to the end of the buffer area is an unused area.

(Modified example of buffer area for dummy lamp)
In this embodiment, as described above, the buffer area for the dummy lamps assigned to the addresses of the unmounted LED driver ICs is provided in the lamp buffer (built-in RAM 981b), and the buffer area for the dummy lamps is the seventh lamp. Stores light emission drive data (segment data) to be output to the cathode terminals of all the 7-segment LEDs (49 light source units associated with port numbers No. 108 to No. 156 (see FIG. 148)) that make up the group 1017. Although examples have been provided, the invention is not so limited.

For example, a buffer area other than the lamp buffer in the built-in RAM 981b or a buffer area for dummy lamps is separately provided in the sub-RAM 983, and the buffer area for the dummy lamps provided separately from the lamp buffer is provided with the seventh lamp group 1017. may store light emission driving data (segment data) to be output to the cathode terminals of all the 7-segment LEDs constituting the . In this case, when transmitting the lamp data, the segment data of the 7-segment LED (one of the 1st to 7th segments) to be selected is read out from the dummy lamp buffer area provided separately from the lamp buffer. The segment data is stored in the lamp buffer unit area of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017 .

[12-6. Mode of setting light emission drive data during dynamic control]
157A to 157G show the buffer area for the seventh lamp group 1017 (buffer area assigned to address "23" of the LED driver IC) during dynamic control of the seventh lamp group 1017 (7-digit 7-segment LED). ) and segment data “C0(a)” to “C6(g)”.

FIG. 157A shows when the first segment (the first digit 7-segment LED) is selected during dynamic control, that is, seven light sources associated with port numbers No. 108 to No. 114 (see FIG. 148) section is under control, the anode selection data "A0" to "A6" and the segment data "C0(a)" to "C6(g)" stored in the buffer area for the seventh lamp group 1017 ” is shown.

When the first segment is selected, the anode terminal of the first segment among the lamp buffer unit areas from the head (1st byte) to the 7th byte (anode area) in the buffer area for the seventh ramp group 1017. The ON-state anode selection data "A0" is stored in the corresponding head (first byte) ramp buffer unit area. On the other hand, OFF state anode selection data “A1” is stored in the lamp buffer unit areas of the 2nd to 7th bytes in the buffer area for the 7th lamp group 1017 corresponding to the anode terminals of the 2nd to 7th segments. to "A6" are stored respectively.

When the first segment is selected, the cathode of segment A of the first segment is placed in the lamp buffer unit area of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017. Segment data "C0(a)" to "C6(g)" output to terminal a to cathode terminal g of segment G (seven light source units corresponding to port numbers No. 108 to No. 114) are stored respectively. be done.

FIG. 157B shows when the second segment (second digit 7 segment LED) is selected during dynamic control, that is, seven light sources associated with port numbers No. 115 to No. 121 (see FIG. 148) section is under control, the anode selection data "A0" to "A6" and the segment data "C0(a)" to "C6(g)" stored in the buffer area for the seventh lamp group 1017 ” is shown.

When the second segment is selected, the anode terminal of the second segment in the lamp buffer unit area from the head (1st byte) to the 7th byte (anode area) in the buffer area for the seventh ramp group 1017. ON-state anode selection data “A1” is stored in the corresponding ramp buffer unit area of the second byte. On the other hand, in the lamp buffer unit areas of the 1st byte, the 3rd byte to the 7th byte in the buffer area for the 7th lamp group 1017 corresponding to the anode terminals of the 1st segment, the 3rd segment to the 7th segment, the OFF State anode selection data “A0”, “A2” to “A6” are stored respectively.

When the second segment is selected, the cathode of segment A of the second segment is placed in the lamp buffer unit area of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017. Segment data “C0(a)” to “C6(g)” output to terminal a to cathode terminal g of segment G (seven light source units corresponding to port numbers No. 115 to No. 121) are stored respectively. be done.

FIG. 157C shows that when the 3rd segment (3rd digit 7 segment LED) is selected during dynamic control, that is, 7 light sources related to port numbers No. 122 to No. 128 (see FIG. 148) section is under control, the anode selection data "A0" to "A6" and the segment data "C0(a)" to "C6(g)" stored in the buffer area for the seventh lamp group 1017 ” is shown.

When the 3rd segment is selected, the anode terminal of the 3rd segment among the ramp buffer unit areas from the head (1st byte) to the 7th byte (anode area) in the buffer area for the 7th ramp group 1017 ON-state anode selection data “A2” is stored in the third byte lamp buffer unit area in the corresponding buffer area for the seventh lamp group 1017 . On the other hand, the 1st, 2nd, 4th to 7th bytes in the buffer area for the seventh lamp group 1017 corresponding to the anode terminals of the 1st, 2nd, 4th to 7th segments The OFF state anode selection data “A0”, “A1”, “A3” to “A6” are stored in the ramp buffer unit area.

When the third segment is selected, the cathode of segment A of the third segment is placed in the lamp buffer unit area of the ninth to fifteenth bytes (cathode area) in the buffer area for the seventh lamp group 1017. Segment data “C0(a)” to “C6(g)” output to terminal a to cathode terminal g of segment G (seven light source units corresponding to port numbers No. 122 to No. 128) are stored respectively. be done.

FIG. 157D shows when the 4th segment (4th digit 7 segment LED) is selected during dynamic control, that is, 7 light sources associated with port numbers No. 129 to No. 135 (see FIG. 148) section is under control, the anode selection data "A0" to "A6" and the segment data "C0(a)" to "C6(g)" stored in the buffer area for the seventh lamp group 1017 ” is shown.

When the 4th segment is selected, the anode terminal of the 4th segment in the lamp buffer unit area from the head (1st byte) to the 7th byte (anode area) in the buffer area for the 7th ramp group 1017 ON-state anode selection data “A3” is stored in the fourth byte lamp buffer unit area in the corresponding buffer area for the seventh lamp group 1017 . On the other hand, the 1st to 3rd bytes and the 5th to 7th bytes in the buffer area for the seventh lamp group 1017 corresponding to the anode terminals of the 1st to 3rd segments and the 5th to 7th segments. The OFF state anode selection data “A0” to “A2” and “A4” to “A6” are stored in the ramp buffer unit area.

When the fourth segment is selected, the cathode of segment A of the fourth segment is placed in the lamp buffer unit area of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017. Segment data "C0(a)" to "C6(g)" output to terminal a to cathode terminal g of segment G (seven light source units corresponding to port numbers No. 129 to No. 135) are stored respectively. be done.

FIG. 157E shows when the 5th segment (5th digit 7-segment LED) is selected during dynamic control, that is, 7 light sources associated with port numbers No. 136 to No. 142 (see FIG. 148) section is under control, the anode selection data "A0" to "A6" and the segment data "C0(a)" to "C6(g)" stored in the buffer area for the seventh lamp group 1017 ” is shown.

When the 5th segment is selected, the anode terminal of the 5th segment in the lamp buffer unit area from the head (1st byte) to the 7th byte (anode area) in the buffer area for the 7th ramp group 1017 is connected to the anode terminal of the 5th segment. ON state anode selection data “A4” is stored in the fifth byte lamp buffer unit area in the corresponding buffer area for the seventh lamp group 1017 . On the other hand, the 1st to 4th, 6th and 7th bytes in the buffer area for the seventh lamp group 1017 corresponding to the anode terminals of the 1st to 4th, 6th and 7th segments The OFF state anode selection data “A0” to “A3”, “A5” and “A6” are stored in the ramp buffer unit area.

When the 5th segment is selected, the cathode of the segment A of the 5th segment is stored in the lamp buffer unit area of the 9th byte to the 15th byte (cathode area) in the buffer area for the 7th lamp group 1017. Segment data "C0(a)" to "C6(g)" output to terminal a to cathode terminal g of segment G (seven light source units corresponding to port numbers No. 136 to No. 142) are stored respectively. be done.

FIG. 157F shows the case where the 6th segment (the 6th digit 7-seg LED) is selected during dynamic control, that is, the 7 light sources associated with port numbers No. 143 to No. 149 (see FIG. 148) section is under control, the anode selection data "A0" to "A6" and the segment data "C0(a)" to "C6(g)" stored in the buffer area for the seventh lamp group 1017 ” is shown.

When the 6th segment is selected, the anode terminal of the 6th segment in the lamp buffer unit area from the head (1st byte) to the 7th byte (anode area) in the buffer area for the 7th ramp group 1017 ON-state anode selection data “A5” is stored in the sixth byte lamp buffer unit area in the corresponding buffer area for the seventh lamp group 1017 . On the other hand, in the lamp buffer unit areas of the 1st to 5th and 7th bytes in the buffer area for the seventh lamp group 1017 corresponding to the anode terminals of the 1st to 5th and 7th segments, OFF State anode selection data “A0” to “A4” and “A6” are stored respectively.

When the 6th segment is selected, the cathode of segment A of the 6th segment is placed in the lamp buffer unit area of the 9th byte to the 15th byte (cathode area) in the buffer area for the 7th lamp group 1017. Segment data "C0(a)" to "C6(g)" output to terminal a to cathode terminal g of segment G (seven light source units corresponding to port numbers No. 143 to No. 149) are stored respectively. be done.

FIG. 157G shows when the 7th segment (7th digit 7-segment LED) is selected during dynamic control, that is, 7 light sources associated with port numbers No. 150 to No. 156 (see FIG. 148) section is under control, the anode selection data "A0" to "A6" and the segment data "C0(a)" to "C6(g)" stored in the buffer area for the seventh lamp group 1017 ” is shown.

When the 7th segment is selected, the anode terminal of the 7th segment in the lamp buffer unit area from the head (1st byte) to the 7th byte (anode area) in the buffer area for the 7th ramp group 1017 is connected to the anode terminal of the 7th segment. ON-state anode selection data “A6” is stored in the 7th byte lamp buffer unit area in the buffer area for the corresponding 7th lamp group 1017 . On the other hand, OFF-state anode selection data “A0” is stored in the lamp buffer unit areas of the 1st to 6th bytes in the buffer area for the seventh lamp group 1017 corresponding to the anode terminals of the 1st to 6th segments. to "A5" are stored respectively.

When the 7th segment is selected, the cathode of segment A of the 7th segment is provided in the lamp buffer unit area of the 9th byte to the 15th byte (cathode area) in the buffer area for the 7th lamp group 1017. Segment data "C0(a)" to "C6(g)" output to terminal a to cathode terminal g of segment G (seven light source units associated with port numbers No. 150 to No. 156) are stored respectively. be done.

During the dynamic control of the seventh lamp group 1017, the operation of switching the storage mode of the anode selection data and the segment data in the buffer area for the seventh lamp group 1017 shown in FIGS. 157A to 157G takes about 2.3 msec. This is performed in an interrupt control process (see FIG. 168 described later) that is executed by the sub CPU 981a at regular intervals. That is, the switching operation (dynamic control) of the anode selection data and segment data stored in the buffer area for the seventh lamp group 1017 is performed at a constant cycle of approximately 2.3 msec.

Also, the order of the switching operation of the setting mode of the anode selection data and the segment data in the buffer area for the seventh lamp group 1017 is, for example, the first segment (state of FIG. 157A)→second segment (state of FIG. 157B). → 3rd segment (state of Fig. 157C) → 4th segment (state of Fig. 157D) → 5th segment (state of Fig. 157E) → 6th segment (state of Fig. 157F) → 7th segment (state of Fig. 157G) → 1st segment (state in FIG. 157A) → . . .

[12-7. Configuration of Ramp Buffer Unit Area]
158A to 158D are diagrams showing the configuration of light emission drive data stored in the lamp buffer unit area (buffer area in units of 1 byte) that constitutes the lamp buffer shown in FIGS. 155 and 156. FIG. FIG. 158A is a diagram showing the configuration of a lamp buffer unit area in which light emission driving data other than anode selection data is stored when an LED driver IC with 64 gradations is used. FIG. 158B is a diagram showing a configuration of a lamp buffer unit area in which anode selection data is stored as light emission drive data when an LED driver IC with 64 gradations is used. FIG. 158C is a diagram showing the configuration of a lamp buffer unit area in which light emission drive data other than anode selection data is stored when an LED driver IC with 128 gradations is used. FIG. 158D is a diagram showing the configuration of a lamp buffer unit area in which anode selection data is stored as light emission drive data when an LED driver IC with 128 gradations is used.

A PWM value corresponding to luminance (0% to 100%) is set as light emission driving data in each lamp buffer unit area. That is, the ON period/OFF period ratio (duty ratio) of the drive pulse output to the light source unit of each port number is set as the light emission drive data. Here, FIG. 159 shows a correspondence table between luminance and PWM values when a 64-level LED driver IC is used. It should be noted that the illustration of the correspondence table between luminance and PWM values in the case of using an LED driver IC with 128 gradations is omitted.

When a 64-gradation LED driver IC is used, as shown in FIG. 159, the brightness (0% to 100%) of the connected lamp (LED) can be adjusted in 64 steps. In the case of using an LED driver IC with 64 gradations, when setting the light emission drive data in each lamp buffer unit area, the luminance to be set is determined according to the correspondence table between the luminance and the PWM value shown in FIG. A corresponding PWM value (one of "0" to "63") is set as light emission drive data. Also, when an LED driver IC with 128 gradations is used, the brightness (0% to 100%) of the connected lamp (LED) can be adjusted in 128 steps. In the case of using an LED driver IC with 128 gradations, when setting the light emission driving data in each lamp buffer unit area, the PWM value (any of "0" to "127") corresponding to the brightness to be set is set. or) is set as light emission drive data.

When an LED driver IC with 64 gradations is used, in the lamp buffer unit area in which the light emission drive data other than the anode selection data is stored, bit 0 (“D0”) to bit 5 (“D5 ) are used to set the PWM value (brightness 0% to 100%) within the range of 0 (000000B) to 63 (111111B), and bit 6 (“ D6") and bit 7 ("D7") are unused. Note that lamp buffer unit areas for storing light emission drive data other than anode selection data are assigned to the first lamp group 1011 to sixth lamp group 1016, the eighth lamp group 1018, the dot matrix section 1019, and the special lamp group 1120. It corresponds to a lamp buffer unit area in the buffer area and the buffer area (cathode area) in which the segment data in the seventh lamp group 1017 is stored.

When a 64-gradation LED driver IC is used, the lamp buffer unit area storing the anode selection data of the seventh lamp group 1017 has bit 0 (“D0”) to bit 5 as shown in FIG. A PWM value (brightness 0% or 100%) of '0 (000000B)' or '63 (111111B)' is set using 6 bits (valid bits) up to ('D5') and bit 6 (' D6") and bit 7 ("D7") are unused. That is, in the lamp buffer unit area in which the anode selection data of the seventh lamp group 1017 is stored, binary data of ON or OFF is stored, and the PWM value "63" corresponds to the ON state anode shown in FIG. A PWM value of "0" corresponds to anode selection data in the OFF state. However, the ON state anode selection data is not limited to the PWM value "63". value can be adopted.

When an LED driver IC with 128 gradations is used, in the lamp buffer unit area in which the light emission drive data other than the anode selection data is stored, bit 0 (“D0”) to bit 6 (“D6 ) is used to set the PWM value (brightness 0% to 100%) within the range of 0 (0000000B) to 128 (1111111B), and bit 7 (“ D7") is unused. When a 128-gradation LED driver IC is used, the lamp buffer unit area storing the anode selection data of the seventh lamp group 1017 has bit 0 (“D0”) to bit 6 as shown in FIG. A PWM value (brightness 0% or 100%) of '0 (0000000B)' or '128 (1111111B)' is set using the 7 bits (valid bits) up to ('D6') and bit 7 ('D6') D7") is unused. When an LED driver IC with 128 gradations is used, the PWM value "128" corresponds to the ON state anode selection data shown in FIG. 157, and the PWM value "0" corresponds to the OFF state anode selection data. corresponds to

[12-8. Brightness adjustment of light emission drive data]
In the pachi-slot machine 901 of the present embodiment, as described above, the lamp buffer unit area (1-byte area) constituting the lamp buffer contains a PWM value ("0" to "63" or "0" to "127") are stored. Then, in lighting control of each lamp group, if luminance adjustment is required, the PWM value stored in the lamp buffer unit area is adjusted (changed).

Here, referring to FIGS. 160A to 160D, the cathode terminals (cathode terminal a to cathode terminal g: see FIG. 152) of seven segments A to G that constitute the seven segment LED in the seventh lamp group 1017 are An example of adjusting (changing) the output segment data to adjust the brightness of the 7-segment LED will be described. In the present embodiment, the ON-state anode selection data (light emission drive data) output to the anode terminal of the 7-segment LED whose brightness is adjusted (the 7-segment LED selected during dynamic control) has a brightness of 100. The OFF state anode selection data output to the anode terminal of the 7-segment LED whose brightness is not adjusted (the 7-segment LED not selected during dynamic control) is set to the PWM value “63” corresponding to %, and the brightness is 0 A PWM value "0" (OFF state data) corresponding to % is set.

FIG. 160A shows the 7 segments that constitute the predetermined 7-segment LED when the number "0" is lit at 100% luminance in the predetermined 7-segment LED selected during dynamic control (when the luminance is not adjusted). 3 is an example of the configuration of segment data output to cathode terminals (cathode terminals a to cathode terminals g) of segments A to G; In this case, it is necessary to output the segment data (light emission drive data) of the PWM value "63" corresponding to 100% luminance to the cathode terminals of the segments other than the segment D constituting the predetermined 7-segment LED. Therefore, in this case, of the 9th to 15th bytes (cathode area) of the lamp buffer unit area in the buffer area for the seventh lamp group 1017, the 9th to 11th bytes and the 13th byte to In each ramp buffer unit area of the 15th byte, a PWM value of "63" is stored as segment data ("C0(a)" to "C2(c)", "C4(e)" to "C6(g)"). is set, and the PWM value "0" is set as the segment data "C3(d)" in the ramp buffer unit area of the 12th byte.

FIG. 160B shows the 7 segments that constitute the predetermined 7-segment LED when the number "2" is lit at 100% luminance in the predetermined 7-segment LED selected during dynamic control (when the luminance is not adjusted). 3 is an example of the configuration of segment data output to cathode terminals (cathode terminals a to cathode terminals g) of segments A to G; In this case, it is necessary to output the segment data (light emission drive data) of the PWM value "63" corresponding to 100% luminance to the cathode terminals of the segments other than the segments B and F constituting the predetermined 7-segment LED. . Therefore, in this case, of the 9th to 15th bytes (cathode area) of the lamp buffer unit area in the buffer area for the seventh lamp group 1017, the 9th, 11th to 13th bytes, PWM value "63" is stored in each ramp buffer unit area of 15th byte as segment data ("C0(a)", "C2(c)" to "C4(e)", "C6(g)"). is set, and the PWM value "0" is set as the segment data ("C1(b)", "C5(f)") in each ramp buffer unit area of the 10th and 14th bytes.

FIG. 160C shows that when the number “0” is lit at a brightness of 80% in a predetermined 7-segment LED selected during dynamic control (when performing brightness adjustment), the 7 LEDs constituting the predetermined 7-segment LED 2 is a configuration example of segment data output to the cathode terminals (cathode terminals a to cathode terminals g) of segments A to G of . In this case, it is necessary to output the segment data (light emission drive data) of the PWM value "50" corresponding to the luminance of 80% to the cathode terminals of the segments other than the segment D that constitutes the predetermined 7-segment LED. Therefore, in this case, of the 9th to 15th bytes (cathode area) of the lamp buffer unit area in the buffer area for the seventh lamp group 1017, the 9th to 11th bytes and the 13th byte to In each ramp buffer unit area of the 15th byte, a PWM value of "50" is stored as segment data ("C0(a)" to "C2(c)", "C4(e)" to "C6(g)"). is set, and the PWM value "0" is set as the segment data "C3(d)" in the ramp buffer unit area of the 12th byte.

In addition, FIG. 160D shows the configuration of the predetermined 7-segment LED selected during dynamic control when the number "2" is lit at 80% luminance (when performing luminance adjustment). It is a configuration example of segment data output to cathode terminals (cathode terminals a to cathode terminals g) of seven segments A to G. FIG. In this case, it is necessary to output segment data (light emission drive data) with a PWM value of "50" corresponding to a brightness of 80% to the cathode terminals of the segments other than the segments B and F that constitute the predetermined 7-segment LED. . Therefore, in this case, of the 9th to 15th bytes (cathode area) of the lamp buffer unit area in the buffer area for the seventh lamp group 1017, the 9th, 11th to 13th bytes, In each ramp buffer unit area of the 15th byte, a PWM value of "50" is stored as segment data ("C0(a)", "C2(c)" to "C4(e)", "C6(g)"). is set, and the PWM value "0" is set as the segment data ("C1(b)", "C5(f)") in each ramp buffer unit area of the 10th and 14th bytes.

(Modified example of luminance adjustment)
In adjusting the brightness of the seven segment LEDs forming the seventh lamp group 1017 (seven-digit seven-segment LEDs), the anode selection data (light emission drive data) output to the anode terminal may be adjusted (changed). Since the anode selection data output from the LED driver IC to the anode terminal of the 7-segment LED is the ON state data or the OFF-state data as described above, the luminance adjustment for the anode terminal is performed by selecting the selected 7-segment LED. ON state data (PWM value) output to the anode terminal of is adjusted (changed).

The ON-state anode selection data (PWM value) input to the anode terminal is set to less than "63" (luminance less than 100%), and the drive pulse has a duty ratio (ON period/OFF period ratio) corresponding to the PWM value. is input to the anode terminal, the anode terminal is turned ON/OFF according to the duty ratio. In this case, the 7-segment LED emits light during the ON period of the drive pulse, but does not emit light during the OFF period. That is, the light emission period of the 7-segment LED becomes shorter than the pulse period of the drive pulse, and as a result, the luminance decreases. /OFF period ratio).

161A to 161C show the configuration of anode selection data output to anode terminals of 7-segment LEDs that are selected (switched) at intervals of approximately 2.3 msec (every execution of interrupt control processing described later) during dynamic control. FIG. 4 is a diagram showing an example; In the example shown in FIGS. 161A to 161C, a PWM value "63" corresponding to a brightness of 100% is set as segment data to the cathode terminal of the segment to be lighted (lighted) in the 7-segment LED selected by dynamic control. shall be output.

FIG. 161A shows the case where the selected 7-segment LED among the 7 7-segment LEDs (1st segment to 7th segment) constituting the seventh lamp group 1017 is lit at 100% luminance during dynamic control ( 10 is a configuration example of anode selection data output to each anode terminal of the 1st segment to the 7th segment when brightness adjustment is not performed).

For example, when the 1st segment (the 7th segment LED of the 1st digit) is selected during dynamic control and the 1st segment is to emit light with a luminance of 100%, as shown in FIG. 161A, the seventh lamp group 1017 Anode selection data "A0" is stored in the 1st byte ramp buffer unit area corresponding to the anode terminal of the 1st segment among the 1st byte to 7th byte (anode area) of the ramp buffer unit area in the buffer area for , the PWM value "63" (ON state) corresponding to 100% luminance is set. In this case, the lamp buffer unit areas of the 2nd to 7th bytes corresponding to the anode terminals of the 2nd to 7th segments have the anode selection data "A1" to "A6" and the PWM value "0". (OFF state) are set respectively.

For example, when the second segment (second digit 7 segment LED) is selected during dynamic control and the second segment is to emit light with a luminance of 100%, as shown in FIG. 161A, the seventh lamp group 1017 Anode selection data "A1" is stored in the 2nd byte lamp buffer unit area corresponding to the anode terminal of the 2nd segment among the 1st byte to 7th byte (anode area) of the lamp buffer unit area in the buffer area for , the PWM value "63" (ON state) corresponding to 100% luminance is set. In this case, anode selection data "A0", "A2 ” to “A6” are respectively set to the PWM value “0” (OFF state).

For example, when the 3rd segment (the 7th segment LED in the 3rd digit) is selected during dynamic control and the 3rd segment is to emit light with a luminance of 100%, as shown in FIG. 161A, the seventh lamp group 1017 Anode selection data "A2" is stored in the 3rd byte ramp buffer unit area corresponding to the anode terminal of the 3rd segment among the 1st byte to 7th byte (anode area) of the ramp buffer unit area in the buffer area for , the PWM value "63" (ON state) corresponding to 100% luminance is set. Further, in this case, in the ramp buffer unit areas of the 1st, 2nd, 4th to 7th bytes corresponding to the anode terminals of the 1st, 2nd, 4th to 7th segments, anode PWM value "0" (OFF state) is set as selection data "A0", "A1", "A3" to "A6".

For example, when the 4th segment (the 7th segment LED of the 4th digit) is selected during dynamic control and the 4th segment is to emit light with a luminance of 100%, as shown in FIG. 161A, the seventh lamp group 1017 Anode selection data "A3" is stored in the 4th byte lamp buffer unit area corresponding to the anode terminal of the 4th segment among the 1st byte to 7th byte (anode area) of the lamp buffer unit area in the buffer area for , the PWM value "63" (ON state) corresponding to 100% luminance is set. In this case, in the ramp buffer unit areas of the 1st to 3rd bytes and the 5th to 7th bytes corresponding to the anode terminals of the 1st to 3rd segments and the 5th to 7th segments, anode PWM value "0" (OFF state) is set as selection data "A0" to "A2" and "A4" to "A6".

For example, when the 5th segment (the 7th segment LED of the 5th digit) is selected during dynamic control and the 5th segment is to emit light with a luminance of 100%, as shown in FIG. 161A, the seventh lamp group 1017 Anode selection data "A4" is stored in the 5th byte lamp buffer unit area corresponding to the anode terminal of the 5th segment among the 1st byte to 7th byte (anode area) of the lamp buffer unit area in the buffer area for , the PWM value "63" (ON state) corresponding to 100% luminance is set. Further, in this case, in the ramp buffer unit areas of the 1st to 4th, 6th, and 7th bytes corresponding to the anode terminals of the 1st to 4th, 6th, and 7th segments, anode PWM value "0" (OFF state) is set as selection data "A0" to "A3", "A5" and "A6".

For example, when the 6th segment (the 7th segment LED of the 6th digit) is selected during dynamic control and the 6th segment is to emit light with a luminance of 100%, as shown in FIG. 161A, the 7th lamp group 1017 Anode selection data "A5" is stored in the 6th byte ramp buffer unit area corresponding to the anode terminal of the 6th segment among the 1st byte to 7th byte (anode area) of the ramp buffer unit area in the buffer area for , the PWM value "63" (ON state) corresponding to 100% luminance is set. In this case, anode selection data “A0” to “A4 , and “A6” are set to a PWM value of “0” (OFF state).

Further, for example, when the 7th segment (the 7th segment LED of the 7th digit) is selected during dynamic control and the 7th segment is caused to emit light with a luminance of 100%, as shown in FIG. 161A, the 7th lamp Anode selection data " A6” is set to a PWM value of “63” (ON state) corresponding to a luminance of 100%. Further, in this case, in the ramp buffer unit areas of the 1st to 6th bytes corresponding to the anode terminals of the 1st to 6th segments, the anode selection data "A0" to "A5" are stored as the PWM value "0". (OFF state) are set respectively.

FIG. 161B shows the case where the selected 7-segment LED among the 7 7-segment LEDs (1st segment to 7th segment) constituting the seventh lamp group 1017 is lit at a brightness of about 50% during dynamic control. FIG. 10 is a configuration example of anode selection data output to each anode terminal of the first segment to the seventh segment (when adjusting brightness). FIG.

For example, when the 1st segment (the 7th segment LED of the 1st digit) is selected during dynamic control and the 1st segment is to emit light with a brightness of about 50%, as shown in FIG. 161B, the 7th lamp group Anode selection data "A0 ”, the PWM value “31” (ON state) corresponding to a brightness of about 50% is set. In this case, the lamp buffer unit areas of the 2nd to 7th bytes corresponding to the anode terminals of the 2nd to 7th segments have the anode selection data "A1" to "A6" and the PWM value "0". (OFF state) are set respectively.

For example, when the second segment (second digit 7 segment LED) is selected during dynamic control and the second segment is to emit light with a luminance of approximately 50%, as shown in FIG. 161B, the seventh lamp group Anode selection data "A1 ”, the PWM value “31” (ON state) corresponding to a brightness of about 50% is set. In this case, anode selection data "A0", "A2 ” to “A6” are respectively set to the PWM value “0” (OFF state).

For example, when the 3rd segment (the 7th segment LED in the 3rd digit) is selected during dynamic control and the 3rd segment is to emit light with a luminance of about 50%, as shown in FIG. 161B, the 7th lamp group Anode selection data "A2 ”, the PWM value “31” (ON state) corresponding to a brightness of about 50% is set. Further, in this case, in the ramp buffer unit areas of the 1st, 2nd, 4th to 7th bytes corresponding to the anode terminals of the 1st, 2nd, 4th to 7th segments, anode PWM value "0" (OFF state) is set as selection data "A0", "A1", "A3" to "A6".

For example, when the 4th segment (the 7th segment LED of the 4th digit) is selected during dynamic control and the 4th segment is to emit light with a luminance of approximately 50%, as shown in FIG. 161B, the 7th lamp group Anode selection data "A3 ”, the PWM value “31” (ON state) corresponding to a brightness of about 50% is set. In this case, in the ramp buffer unit areas of the 1st to 3rd bytes and the 5th to 7th bytes corresponding to the anode terminals of the 1st to 3rd segments and the 5th to 7th segments, anode PWM value "0" (OFF state) is set as selection data "A0" to "A2" and "A4" to "A6".

For example, when the 5th segment (the 7th segment LED of the 5th digit) is selected during dynamic control and the 5th segment is to emit light with a luminance of approximately 50%, as shown in FIG. 161B, the 7th lamp group Anode selection data "A4 ”, the PWM value “31” (ON state) corresponding to a brightness of about 50% is set. Further, in this case, in the ramp buffer unit areas of the 1st to 4th, 6th, and 7th bytes corresponding to the anode terminals of the 1st to 4th, 6th, and 7th segments, anode PWM value "0" (OFF state) is set as selection data "A0" to "A3", "A5" and "A6".

For example, when the 6th segment (the 6th digit 7-segment LED) is selected during dynamic control and the 6th segment is to emit light with a luminance of approximately 50%, as shown in FIG. 161B, the 7th lamp group Anode selection data "A5 ”, the PWM value “31” (ON state) corresponding to a brightness of about 50% is set. In this case, anode selection data “A0” to “A4 , and “A6” are set to a PWM value of “0” (OFF state).

Further, for example, when the 7th segment (the 7th segment LED of the 7th digit) is selected during dynamic control and the 7th segment is caused to emit light with a luminance of approximately 50%, as shown in FIG. 161B, the 7th segment Among the lamp buffer unit areas of the 1st byte to the 7th byte (anode area) in the buffer area for the lamp group 1017, the anode selection data is stored in the 7th byte lamp buffer unit area corresponding to the anode terminal of the 7th segment. As "A6", a PWM value of "31" (ON state) corresponding to a brightness of approximately 50% is set. Further, in this case, in the ramp buffer unit areas of the 1st to 6th bytes corresponding to the anode terminals of the 1st to 6th segments, the anode selection data "A0" to "A5" are stored as the PWM value "0". (OFF state) are set respectively.

FIG. 161C shows the case where the selected 7-segment LED among the 7 7-segment LEDs (1st segment to 7th segment) constituting the seventh lamp group 1017 is lit at a brightness of 25% during dynamic control ( 10 is a configuration example of anode selection data output to each anode terminal of the 1st segment to the 7th segment when performing luminance adjustment).

For example, when the 1st segment (the 7th segment LED of the 1st digit) is selected during dynamic control and the 1st segment is to emit light with a luminance of 25%, as shown in FIG. 161C, the seventh lamp group 1017 Anode selection data "A0" is stored in the 1st byte ramp buffer unit area corresponding to the anode terminal of the 1st segment among the 1st byte to 7th byte (anode area) of the ramp buffer unit area in the buffer area for , the PWM value "16" (ON state) corresponding to the luminance of 25% is set. In this case, the lamp buffer unit areas of the 2nd to 7th bytes corresponding to the anode terminals of the 2nd to 7th segments have the anode selection data "A1" to "A6" and the PWM value "0". (OFF state) are set respectively.

For example, when the second segment (second digit 7 segment LED) is selected during dynamic control and the second segment is to emit light with a luminance of 25%, as shown in FIG. 161C, the seventh lamp group 1017 Anode selection data "A1" is stored in the 2nd byte lamp buffer unit area corresponding to the anode terminal of the 2nd segment among the 1st byte to 7th byte (anode area) of the lamp buffer unit area in the buffer area for , the PWM value "16" (ON state) corresponding to the luminance of 25% is set. In this case, anode selection data "A0", "A2 ” to “A6” are respectively set to the PWM value “0” (OFF state).

For example, when the 3rd segment (the 7th segment LED in the 3rd digit) is selected during dynamic control and the 3rd segment is to emit light with a luminance of 25%, as shown in FIG. 161C, the seventh lamp group 1017 Anode selection data "A2" is stored in the 3rd byte ramp buffer unit area corresponding to the anode terminal of the 3rd segment among the 1st byte to 7th byte (anode area) of the ramp buffer unit area in the buffer area for , the PWM value "16" (ON state) corresponding to the luminance of 25% is set. Further, in this case, in the ramp buffer unit areas of the 1st, 2nd, 4th to 7th bytes corresponding to the anode terminals of the 1st, 2nd, 4th to 7th segments, anode PWM value "0" (OFF state) is set as selection data "A0", "A1", "A3" to "A6".

For example, when the 4th segment (the 7th segment LED of the 4th digit) is selected during dynamic control and the 4th segment is to emit light with a luminance of 25%, as shown in FIG. 161C, the seventh lamp group 1017 Anode selection data "A3" is stored in the 4th byte lamp buffer unit area corresponding to the anode terminal of the 4th segment among the 1st byte to 7th byte (anode area) of the lamp buffer unit area in the buffer area for , the PWM value "16" (ON state) corresponding to the luminance of 25% is set. In this case, in the ramp buffer unit areas of the 1st to 3rd bytes and the 5th to 7th bytes corresponding to the anode terminals of the 1st to 3rd segments and the 5th to 7th segments, anode PWM value "0" (OFF state) is set as selection data "A0" to "A2" and "A4" to "A6".

For example, when the 5th segment (the 7th segment LED of the 5th digit) is selected during dynamic control and the 5th segment is to emit light with a luminance of 25%, as shown in FIG. 161C, the seventh lamp group 1017 Anode selection data "A4" is stored in the 5th byte lamp buffer unit area corresponding to the anode terminal of the 5th segment among the 1st byte to 7th byte (anode area) of the lamp buffer unit area in the buffer area for , the PWM value "16" (ON state) corresponding to the luminance of 25% is set. Further, in this case, in the ramp buffer unit areas of the 1st to 4th, 6th, and 7th bytes corresponding to the anode terminals of the 1st to 4th, 6th, and 7th segments, anode PWM value "0" (OFF state) is set as selection data "A0" to "A3", "A5" and "A6".

For example, when the 6th segment (the 7th segment LED of the 6th digit) is selected during dynamic control and the 6th segment is to emit light with a luminance of 25%, as shown in FIG. Anode selection data "A5" is stored in the 6th byte ramp buffer unit area corresponding to the anode terminal of the 6th segment among the 1st byte to 7th byte (anode area) of the ramp buffer unit area in the buffer area for , the PWM value "16" (ON state) corresponding to the luminance of 25% is set. In this case, anode selection data “A0” to “A4 , and “A6” are set to a PWM value of “0” (OFF state).

Further, for example, when the 7th segment (the 7th segment LED of the 7th digit) is selected during dynamic control and the 7th segment is caused to emit light with a luminance of 25%, as shown in FIG. 161C, the 7th lamp Anode selection data " A6” is set to a PWM value of “16” (ON state) corresponding to a luminance of 25%. Further, in this case, in the ramp buffer unit areas of the 1st to 6th bytes corresponding to the anode terminals of the 1st to 6th segments, the anode selection data "A0" to "A5" are stored as the PWM value "0". (OFF state) are set respectively.

[12-9. Overview of lamp data transmission operation]
Next, the outline of the lamp data transmission operation in the pachi-slot machine 901 of this embodiment will be described.

First, various light emission drive data (including the segment data and anode selection data described above) for driving various lamp groups are set in the lamp buffers shown in FIGS. Next, when the sub CPU 981a of the sub control circuit 942 executes an LED driver IC transfer process (S615 described later) in the interrupt control process (see FIG. 168 described later), the synchronous serial driver of the synchronous serial communication circuit 981c (API) generates lamp data (transmission data) according to the transmission format of synchronous serial communication, and transmits the lamp data to a group of LED driver ICs (LED driver IC 1021 to LED driver IC 1030) for driving various lamp groups. Send to

The lamp data transmitted from the synchronous serial communication circuit 981c to the LED driver IC group includes the driver address of each LED driver IC and the light emission driving data stored in the lamp buffer. In the lamp data, for each driver address, a light emission driving data group stored in a 24-byte buffer area (24 lamp buffer unit areas) in the lamp buffer assigned to the driver address is added. .

Further, the lamp data includes the driver addresses assigned to the three LED driver ICs that are not mounted (ADR "24" to "26" in FIGS. 155 and 156) and the driver addresses assigned to the driver addresses. It also includes the light emission drive data stored in the buffer area (dummy lamp buffer area) in the lamp buffer. That is, in this embodiment, all the light emission drive data stored in the lamp buffer are transmitted from the synchronous serial communication circuit 981c to the LED driver IC group.

The lamp data transmitted from the synchronous serial communication circuit 981c is transmitted in a predetermined order within the LED driver IC group (LED driver IC1021 to LED driver IC1030). At this time, the light emission drive data actually transmitted to the LED driver IC group is only data for valid bits (6 bits in this embodiment: see FIGS. 158A and 158B). Next, on the lamp data transmission path, the LED driver IC that has received the lamp data acquires a 24-byte light emission drive data group added to its own driver address included in the lamp data. Then, the LED driver IC outputs a drive signal (PWM signal) to the light source unit (LED) of a predetermined port number in the connected (corresponding) lamp group based on the acquired light emission drive data group. , light emission control (lighting/flashing/extinguishing) of the lamp group.

Further, in the group of LED driver ICs (LED driver IC 1021 to LED driver IC 1030), the lamp data is transmitted to the LED driver IC that is the final destination, and the LED driver IC converts the corresponding light emission drive data group from the lamp data. Once acquired, the LED driver IC outputs (discards) the lamp data to GND without returning it to the sub microprocessor 981 (synchronous serial communication circuit 981c). In this embodiment, the lamp data includes the light emission drive data stored in the dummy lamp buffer area. 942, the light emission drive data stored in the buffer area for the dummy lamp is emptied.

[12-10. Explanation of the operation of the sub-control circuit]
Next, contents of various processes (tasks) executed by the sub CPU 981a of the sub control circuit 942 using programs will be described with reference to FIGS. 162 to 170. FIG.

[12-10-1. Power-on processing]
First, referring to FIG. 162, power-on processing of the sub CPU 981a (sub-control circuit 942) executed when power is turned on will be described. FIG. 162 is a flow chart showing the procedure of power-on processing executed by the sub CPU 981a (sub control circuit 942).

First, the sub CPU 981a executes initialization processing (S501). In this processing, the sub CPU 981a performs initialization processing of various drivers in addition to error checking of the sub RAM 983 and the like.

In initialization processing of various drivers, for example, the sound IC 988 and a sound driver (device driver, software) for accessing the sound IC 988 are reset, and then the initialization of the sound IC 988 is performed. Further, in the initialization processing of various drivers, for example, the LED driver ICs 1021 to 1030, and a lamp driver (synchronous serial driver (device driver) of the synchronous serial communication circuit 981c) for accessing these LED driver ICs , software (API)) are reset, and then the initial settings of the LED driver ICs 1021 to 1030 are executed. These initialization processes enable the sound IC 988 and the LED driver ICs 1021 to 1030 to be used.

In the initialization process of various drivers, a sound buffer management area and a sound buffer (not shown) are also initialized ("released" or "cleared"). In the initialization processing of various drivers, various light emission drive data (luminance values) stored in the lamp buffer in interrupt control processing (see FIG. 168), which will be described later, are also initialized (cleared). Furthermore, in the initialization processing of S501, various tasks are also initialized. For example, a main board communication task (see FIG. 163 to be described later), which is a task group of command reception interrupt synchronization, and a sound control task (not shown) and a lamp control task (to be described later), which are a task group of timer interrupt synchronization. 166) are initialized.

Next, the sub CPU 981a activates the lamp control task (S502). In the lamp control task, the sub CPU 981a waits for reception of a timer interrupt event message transmitted every 2 ms, and in response to receiving the timer interrupt event message, controls the light source units and It controls the lighting state (lighting/blinking/lighting out, etc.) of other various light source units (LEDs).

Next, the sub CPU 981a activates the sound control task (S503). In the sound control task, the sub CPU 981a controls the sound output state of various speakers such as the speakers 920L and 920R, as in the lamp control task.

Next, the sub CPU 981a activates the main board communication task (S504). In the main board communication task, the sub CPU 981a receives a command transmitted from the main control circuit 941, analyzes the received command, and determines (lottery) an effect based on the analyzed command.

Next, the sub CPU 981a acquires date and time data from the RTC 986 and stores it in a date and time storage area (not shown) allocated (provided) in the sub RAM 983 (S505).

Next, the sub CPU 981a acquires a count value from a clock counter (not shown) provided in the sub CPU 981a, and stores the clock value (clock count) in the sub RAM 983 (S506). The clock counter is a counter circuit for counting a clock of a predetermined frequency oscillated by an oscillation circuit 984 (see FIG. 151) incorporated in the sub CPU 981a. After the process of S506, the sub CPU 981a ends the power-on process.

[12-10-2. Main board communication task]
Next, with reference to FIG. 163, the main board communication task performed by the sub CPU 981a will be described. FIG. 163 is a flow chart showing the procedure of the main board communication task executed by the sub CPU 981a.

First, the sub CPU 981a performs reception check processing for a command transmitted from the main control circuit 941 (S511). Next, the sub CPU 981a determines whether the received command is valid based on the result of the reception check process (S512).

In the determination process of S512, the sub CPU 981a determines, for example, the first condition that the data length of the received command is 8 bytes, the received command is a start command, a reel stop command, a display command, a payout end command, a bonus start command, When three conditions are met: the second condition that the command is a pre-registered command such as a bonus end command or no-operation command, and the third condition that the sum value stored in the eighth byte of the received command is correct. Then, as a result of reception check processing, it is determined that the received command is valid, and if any condition is not established, it is determined that the received command is not valid as a result of reception check processing.

In S512, when the sub CPU 981a determines that the received command is not valid (when the determination in S512 is No), the sub CPU 981a returns the process to S511 and repeats the processes after S511.

On the other hand, when the sub CPU 981a determines in S512 that the received command is valid (when S512 determines Yes), the sub CPU 981a stores a message in the message queue based on the received command (S513). . A message queue is a mechanism for passing information to other tasks. After the process of S513, the sub CPU 981a returns the process to S511 and repeats the processes after S511.

[12-10-3. Production registration task]
Next, with reference to FIG. 164, the effect registration task performed by the sub CPU 981a will be described. FIG. 164 is a flow chart showing the procedure of the effect registration task executed by the sub CPU 981a.

First, the sub CPU 981a retrieves a message from the message queue (S521). The message in the message queue is a message stored in the message queue based on the command received by the sub CPU 981a by the main board communication task (see FIG. 163).

Next, the sub CPU 981a determines whether or not there is a message in the message queue (S522). In S522, when the sub CPU 981a determines that there is no message in the message queue (when S522 determines No), the sub CPU 981a performs the processing of S526, which will be described later.

On the other hand, when the sub CPU 981a determines in S522 that there is a message in the message queue (when S522 determines Yes), the sub CPU 981a copies game information from the message (S523). In this process, for example, the type of the received command (see "4-9. Command" of the first game machine above), the internal winning combination, and the type of the reel whose rotation has stopped are specified by the parameters in the game information. , display combination, game state flags, etc. are copied to a predetermined storage area (not shown) provided in the sub-RAM 983 .

Next, the sub CPU 981a performs effect content determination processing (S524). In this process, the sub CPU 981a determines the contents of the effect, registers the effect data, etc. according to the various data copied to the sub RAM 983 in S523 and the type of the received command. Details of the effect content determination process will be described later with reference to FIG. 165, which will be described later.

Next, the sub CPU 981a performs special lamp data editing processing (S525). In this process, the sub CPU 981a refers to a lighting pattern table (not shown) of the special lamp group 1120, and sets a pattern number (lighting pattern) according to the type of command received and the various data copied to the sub RAM 983 in S523. to decide.

After the processing of S525, or when the determination in S522 is No, the sub CPU 981a registers the sound effect data (S526). Next, the sub CPU 981a registers the lamp effect data (S527). These registration processes are performed based on the effect data registered in the effect content determination process of S524. In addition, in the pachi-slot machine 901 of the present embodiment, the sub CPU 981a stores the request number of the sound effect data in the registration area of the sub RAM 983 only when the request number of the sound effect data has been determined. register. Further, the sub CPU 981a registers the lamp effect data by storing the request number of the lamp effect data in the registration area of the sub RAM 983 only when the request number of the lamp effect data has been determined. After the process of S527, the sub CPU 981a returns the process to S521, and repeats the processes after S521.

[12-10-4. Production content determination process]
Next, with reference to FIG. 165, the effect content determination process performed at S524 in the flow chart of the effect registration task (see FIG. 164) will be described. FIG. 165 is a flow chart showing the procedure of effect content determination processing executed by the sub CPU 981a.

First, the sub CPU 981a determines whether or not it is time to receive a start command (S531).

In S531, when the sub CPU 981a determines that it is time to receive a start command (if determined as Yes in S531), the sub CPU 981a performs processing when receiving a start command (S532). In this process, the sub CPU 981a extracts a random value for effect, determines and registers the effect number by lottery based on the internal winning combination and the like. Here, the effect number is data specifying the content of the effect to be executed this time.

Next, the sub CPU 981a registers (selects) effect data at the start according to the registered effect number (S533). The effect data is data specifying sound effect data and lamp effect data. Therefore, when the effect data is registered, the corresponding lamp effect data and the like are determined, and effect such as lighting by various lamp groups is executed. After the process of S533, the sub CPU 981a ends the effect content determination process, and returns the process to the process of S525 in the effect registration task (see FIG. 164).

When the pushing order information corresponding to the internal winning combination is displayed in the 3rd to 5th segments, the display data of the pushing order information for the first stop is determined in the processes of S532 and S533.

On the other hand, when the sub CPU 981a determines in S531 that the start command has not been received (when the determination in S531 is No), the sub CPU 981a determines whether or not the reel stop command has been received (S534).

In S534, when the sub CPU 981a determines that it is time to receive the reel stop command (when S534 is determined as Yes), the sub CPU 981a determines the time of stopping according to the registered effect number and the type of the operation stop button. Effect data is selected (S535). After the process of S535, the sub CPU 981a ends the effect content determination process, and returns the process to the process of S525 in the effect registration task (see FIG. 164).

When the pushing order information corresponding to the internal winning combination is displayed in the 3rd to 5th segments, the data for displaying the pushing order information for the 2nd stop and the 3rd stop is determined in the process of S535. .

On the other hand, when the sub CPU 981a determines in S534 that the reel stop command has not been received (when the determination in S534 is No), the sub CPU 981a determines whether or not the display command has been received (S536).

In S536, when the sub CPU 981a determines that it is time to receive the display command (when S536 determines Yes), the sub CPU 981a performs processing when receiving the display command (S537). In this process, the sub CPU 981a determines and registers the effect number by lottery based on the display combination and the like. Here, the effect number is data specifying the content of the effect to be executed this time. After the process of S537, the sub CPU 981a ends the effect content determination process, and returns the process to the process of S525 in the effect registration task (see FIG. 164).

In addition, when the pressing order information corresponding to the internal winning combination is displayed in the 3rd to 5th segments, the information (display) displayed in any of the 3rd to 5th segments is displayed in the process of S537. Display data for erasing (turning off) is also generated.

On the other hand, when it is determined in S536 that the display command is not received (when S536 is determined as No), the sub CPU 981a determines whether or not the payout end command is received (S538). In S538, when the sub CPU 981a determines that it is time to receive the payout end command (when S538 determines Yes), the sub CPU 981a performs payout end command reception processing (S539). After the process of S539, the sub CPU 981a ends the effect content determination process, and returns the process to the process of S525 in the effect registration task (see FIG. 164).

If the number of medals won during the bonus is displayed in the 3rd to 5th segments, the updated number of medals won is displayed in the 3rd to 5th segments in the process of S539. Display data for is generated. Display data for displaying the number of payouts in the sixth and seventh segments is also generated in the process of S539.

On the other hand, when the sub CPU 981a determines in S538 that the payout end command has not been received (when the determination in S538 is No), the sub CPU 981a determines whether or not the bonus start command has been received (S540).

In S540, when the sub CPU 981a determines that it is time to receive the bonus start command (when S540 determines Yes), the sub CPU 981a performs processing when receiving the bonus start command (S541). In this process, the sub CPU 981a registers effect data for starting a bonus. After the process of S541, the sub CPU 981a ends the effect content determination process, and returns the process to the process of S525 in the effect registration task (see FIG. 164).

In addition, when displaying the number of medals acquired during the bonus in the 3rd to 5th segments, the initial display is performed in the 3rd to 5th segments in the processing of S541 (for example, " 0": 3rd segment and 4th segment information for extinguishing the segment and displaying the number "0" in the fifth segment) is generated.

On the other hand, when the sub CPU 981a determines in S540 that the bonus start command has not been received (No determination in S540), the sub CPU 981a determines whether or not the bonus end command has been received (S542).

In S542, when the sub CPU 981a determines that it is time to receive the bonus end command (if determined as Yes in S542), the sub CPU 981a performs bonus end command reception processing (S543). In this process, the sub CPU 981a registers effect data for ending the bonus. After the process of S543, the sub CPU 981a ends the effect content determination process, and returns the process to the process of S525 in the effect registration task (see FIG. 164).

In the process of S543, in order to erase the number of medals won in the bonus displayed in the 3rd to 5th segments, information for erasing the display of the 3rd to 5th segments is generated ( The timing of actually turning off the light is immediately after the medal is inserted, or immediately after the MAX bet button 914 or the 1 bet button 915 is pressed).

On the other hand, when the sub CPU 981a determines in S542 that the bonus end command has not been received (No determination in S542), the sub CPU 981a determines whether or not the no-operation command has been received (S544).

In S544, when the sub CPU 981a determines that it is not time to receive the no-operation command (if the determination in S544 is No), the sub CPU 981a ends the effect content determination process, and shifts the process to the effect registration task (see FIG. 164). return to the processing of S525.

On the other hand, when the sub CPU 981a determines in S544 that the no-operation command is being received (when the determination in S544 is Yes), the sub-CPU 981a performs a no-operation command reception process (S545). After the process of S545, the sub CPU 981a ends the effect content determination process, and returns the process to the process of S525 in the effect registration task (see FIG. 164).

Although omitted in FIG. 165, the effect content determination processing includes processing when receiving a medal insertion command and processing when receiving an initialization command. , according to the contents described in the first game machine above. Further, when a medal insertion command is received, information for displaying the number of stored medals on the first segment and the second segment (2-digit 7-segment LED) is generated.

[12-10-5. Lamp control task]
Next, the lamp control task performed by the sub CPU 981a will be described with reference to FIG. FIG. 166 is a flow chart showing the procedure of the lamp control task executed by the sub CPU 981a. In the lamp control task, as will be described later, lamp control data (light emission drive data) generation processing is performed. Therefore, the lamp control task performed by the sub CPU 981a is a specific example of the light emission data generation means according to the present invention. is shown.

First, the sub CPU 981a executes ramp effect data reading processing (S551). In this process, the sub CPU 981a reads into the sub RAM 983 the lamp effect data registered in the process of registering lamp effect data in the effect registration task (see FIG. 164). The details of the ramp effect data reading process will be described later with reference to FIG. 167, which will be described later.

Next, the sub CPU 981a executes lamp/sound synchronization processing (S552). Next, the sub CPU 981a executes lamp regeneration start processing (S553).

Next, the sub CPU 981a determines whether or not the lamp effect data is being reproduced (S554). In this process, the sub CPU 981a determines whether or not the lamp effect data is being reproduced based on the value of the entry part number storage area (not shown) in the reproduction state management storage area (not shown) provided in the sub RAM 983. determine whether

Specifically, when the lamp effect data is being reproduced, the part number for identifying the part data being reproduced is stored in the entry part number storage area within the reproduction state management storage area. On the other hand, when the lamp effect data is not being reproduced, a specific value (for example, "0") is stored in the entry part number storage area within the reproduction state management storage area. Therefore, in S554, the sub CPU 981a determines that the lamp effect data is being reproduced if the value of the entry part number storage area is not the specific value, and if the value of the entry part number storage area is the specific value, It is determined that the lamp effect data is not being reproduced.

In S554, when the sub CPU 981a determines that the lamp effect data is not being reproduced (when the determination in S554 is No), the sub CPU 981a returns the process to S551, and repeats the processes after S551. On the other hand, when the sub CPU 981a determines in S554 that the lamp effect data is being reproduced (if the determination in S554 is Yes), the sub CPU 981a acquires the attribute data of the part data being reproduced in the lamp effect data ( S555).

Next, the sub CPU 981a determines whether or not the luminance pattern at the reproduction position of the part data being reproduced is an end block (eg, "-1") (S556). In S556, when the sub CPU 981a determines that the luminance pattern at the reproduction position of the part data being reproduced is the end block (when S556 determines Yes), the sub CPU 981a performs the processing of S559 described later.

On the other hand, when the sub CPU 981a determines in S556 that the luminance pattern at the reproduction position of the part data being reproduced is not an end block (if the determination in S556 is No), the sub CPU 981a determines that the luminance pattern at the reproduction position of the part data being reproduced is Lamp control data generation processing is performed from the luminance pattern (S557).

In the process of S557, the sub CPU 981a generates lamp control data (light emission drive data) to be stored in each lamp buffer unit area of the lamp buffers shown in FIGS. 155 and 156 based on the acquired brightness pattern. In this embodiment, as described above, the lamp control data (light emission drive data) is represented by PWM values (see FIG. 158) corresponding to luminance. Specifically, when the gradation of the LED driver IC to be used is 64 gradations, the lamp control data is a 6-bit PWM value (0 to 63) for luminance (0% to 100%). When the gradation of the LED driver IC to be used is 128 gradations, the lamp control data is represented by a 7-bit PWM value (0 to 127) for the brightness (0% to 100%). be. Incidentally, in this embodiment, the brightness of the brightness pattern may be represented by 8 bits (0 to 255). In this case, even if an LED driver IC that supports 7-bit or 6-bit luminance is used, the luminance pattern can be diverted simply by changing the luminance conversion process. That is, even if the type of LED driver IC is different, the lamp performance data can be used.

Further, in the process of S557, mainly lamp control data (light emission drive data) relating to the content of the effect is generated. Specifically, lamp control data for driving and controlling the first lamp group 1011 to the sixth lamp group 1016 and the dot matrix section 1019 connected to the sub-control circuit 942 is generated. The lamp control data (light emission drive data) for driving and controlling the seventh lamp group 1017, the eighth lamp group 1018, and the special lamp group 1120 connected to the sub-control circuit 942 are executed by the sub-CPU 981a. It is generated by interrupt control processing (see FIG. 168 described later).

After the process of S557, the sub CPU 981a registers (sets, stores) the lamp control data (light emission drive data) generated in the lamp control data generation process (S557) in the lamp buffer (see FIGS. 155 and 156) (S558). . The lamp control data (light emission drive data) registered in the lamp buffer by the process of S558 is transferred to the LED driver IC group by the LED driver IC transfer process (S615 described later) during the interrupt control process (see FIG. 168 described later). sent. After the process of S558, the sub CPU 981a returns the process to S551, and repeats the processes after S551.

Here, returning to the process of S556 again, if the determination in S556 is Yes, the sub CPU 981a determines whether or not there is part data next to the part data being reproduced (S559). In this process, the sub CPU 981a determines that there is part data next to the part data being reproduced based on the value of the entry part number storage area and the value of the part number storage area in the playback state management storage area (not shown). or not.

When the sub CPU 981a determines in S559 that there is part data next to the part data being reproduced (if determined as Yes in S559), the sub CPU 981a moves the reproduction position to the next part data (S560). In this process, the sub CPU 981a updates the value of the entry part number storage area in the playback state management storage area (not shown) to the value of the next part number storage area. This process moves the playback position to the next part data. After the processing of S560, the sub CPU 981a returns the processing to S551 and repeats the processing after S551.

On the other hand, when the sub CPU 981a determines in S559 that there is no part data next to the part data being reproduced (if the determination in S559 is No), the sub CPU 981a stores the attribute data of the part data being reproduced acquired in S555. is continuous reproduction (S561).

In S561, when the sub CPU 981a determines that the attribute data of the part data being reproduced is continuous reproduction (when the determination in S561 is Yes), the sub CPU 981a executes attribute search cue processing (S562). In this process, the sub CPU 981a stores a continuous playback/loop playback setting area (not shown) provided in the sub RAM 983 based on the contents stored in the playback state management storage area (not shown) provided in the sub RAM 983. If a value indicating that the attribute data is continuous playback is stored, the part data whose attribute data is continuous playback is searched from the beginning of the identification information of the lamp effect data, and the playback position is set to the beginning of the detected part data. move. After the processing of S562, the sub CPU 981a returns the processing to S551 and repeats the processing after S551.

On the other hand, when the sub CPU 981a determines in S561 that the attribute data of the part data being reproduced is not continuous reproduction (when the determination in S561 is No), the sub CPU 981a reads the attribute data of the part data being reproduced acquired in S555. is loop reproduction (repeated reproduction) (S563). In S563, when the sub CPU 981a determines that the attribute data of the part data being reproduced is not loop reproduction (when S563 determines No), the sub CPU 981a returns the process to S551, and repeats the processes after S551.

On the other hand, when the sub CPU 981a determines in S563 that the attribute data of the part data being reproduced is for loop reproduction (when the determination in S563 is YES), the sub CPU 981a executes the in-part cue processing (S564). . In this process, the sub CPU 981a moves the reproduction position to the beginning of the part data being reproduced. In the part-inside-cue processing, for example, if the part data whose attribute data is loop playback is data that changes from "0" to "9" in ascending order, the data of "9" of the part data After the reproduction of , the head is cued to "0" which is the beginning of the part data, and the data from "0" to "9" are repeatedly reproduced (the repeat function is activated). After the process of S564, the sub CPU 981a returns the process to S551, and repeats the processes after S551.

[12-10-6. Lamp effect data reading process]
Next, referring to FIG. 167, the ramp effect data reading process performed at S551 in the ramp control task flowchart (see FIG. 166) will be described. FIG. 167 is a flow chart showing the procedure of the lamp effect data reading process executed by the sub CPU 981a.

First, the sub CPU 981a determines whether or not an error in the pachi-slot machine 901 is detected (S571). In this process, the sub CPU 981a determines whether or not an error (error occurrence or error occurring) of the pachi-slot machine 901 is detected based on information included in the error command transmitted from the main CPU 951. Errors of the pachi-slot machine 901 include a hopper empty error indicating that the hopper 933 (see FIG. 149) is empty, and an error indicating that the number of medals stored in the medal auxiliary storage 937 (see FIG. 149) has reached a specified amount. There is an error such as an input medal auxiliary storage box full error.

In S571, when the sub CPU 981a determines that an error has been detected in the pachi-slot machine 901 (if the determination in S571 is Yes), the sub CPU 981a displays the lamp effect data being played (display data) is stored in the sub-RAM 983 (S572). Next, the sub CPU 981a registers lamp effect data for error (S573). After the process of S573, the sub CPU 981a executes the process of S578, which will be described later.

In addition, the condition that the determination result of S571 becomes Yes determination is when the main control circuit 941 and/or the sub control circuit 942 detects the occurrence of an error. Specifically, the error of the main control circuit 941 is According to the error state of the first game machine, the error of the sub-control circuit 942 is put into the operating state by checking the operating state of the LED driver IC, the sound IC 988, the RTC 986, and / or the backup RAM 985 (not shown). This is the case when an abnormality is detected. Further, when lamp effect data for error is registered in the process of S573, an error code corresponding to the lamp effect data is displayed in the sixth segment and the seventh segment of the seventh lamp group 1017. FIG. At this time, if the error is detected by the main control circuit 941, the information display device 14 displays the same error code as the error code displayed in the sixth segment and the seventh segment. On the other hand, if the error is detected by the sub-control circuit 942, the error code is displayed in the sixth segment and the seventh segment, but the information display device 14 does not display the error code. Therefore, if an error code is displayed on the sixth and seventh segments of the seventh lamp group 1017 and the information display device 14 when an abnormality occurs in the pachi-slot machine 901, the abnormality detected by the main control circuit 941 If the error code is displayed only in the 6th segment and the 7th segment, it can be determined that the abnormality is detected by the sub-control circuit 942, making it easy to identify the cause of the abnormality. .

On the other hand, when the sub CPU 981a determines in S571 that an error in the pachi-slot machine 901 has not been detected (when the determination in S571 is No), the sub CPU 981a determines whether the error in the pachi-slot machine 901 has been resolved ( S574).

In S574, when the sub CPU 981a determines that the error of the pachi-slot machine 901 has been cleared (when the abnormality (error) occurring in the main control circuit 941 and the sub-control circuit 942 disappears) (when S574 determines Yes) , the sub CPU 981a specifies the request number of the lamp effect data for return from interruption corresponding to the request number saved in S572 (S575). Next, the sub CPU 981a registers the interrupt return lamp effect data of the request number specified in S575 (S576). After the process of S576, the sub CPU 981a executes the process of S578, which will be described later. In the process of S576, the error code displayed in the 6th and 7th segments of the 7th lamp group 1017 is erased, and the display data displayed in the 6th and 7th segments before the error occurs A process for displaying is performed.

On the other hand, when the sub CPU 981a determines in S574 that the error of the pachi-slot machine 901 has not been cleared (when the determination in S574 is No), the sub CPU 981a detects the effect registered in S527 (see FIG. 164) of the effect registration task. It is determined whether or not the lamp effect data has been updated (S577). In S577, when the sub CPU 981a determines that the lamp effect data has not been updated (when S577 is determined as No), the sub CPU 981a ends the lamp effect data reading process, and performs the process as a lamp control task (Fig. 166). reference) to the process of S552.

On the other hand, in S577, when the sub CPU 981a determines that the lamp effect data has been updated (when S577 determines Yes), after the processing of S573 or after the processing of S576, the sub CPU 981a performs S573, S576 or The lamp effect data registered in S527 of the effect registration task is acquired (S578). Next, the sub CPU 981a performs reproduction data generation processing (S579). In this process, the sub CPU 981a generates a reproduction state management storage area (not shown) in the sub RAM 983 based on the lamp effect data acquired in S578. After the process of S573, the sub CPU 981a ends the lamp effect data reading process, and returns the process to the process of S552 in the lamp control task (see FIG. 166).

In the above-described lamp effect data reading process, in the determination process of S577, it is determined whether or not the lamp effect data registered in S527 (see FIG. 164) of the effect registration task has been updated. Even when the data is registered, the sub CPU 981a determines that the lamp effect data has been updated. Also, in the pachi-slot machine 901 of the present embodiment, when the reproduction of the ramp effect data is to be terminated, the sub CPU 981a registers blank ramp effect data in the process of S527 in the effect registration task. When blank lamp effect data is registered, the sub CPU 981a sets a specific value (for example, "0") in the entry part number storage area (not shown) and performs playback state management that does not include the part number storage area. A storage area is generated by the processing of S579.

[12-10-7. Interrupt control processing]
Next, with reference to FIG. 168, interrupt control processing performed by the sub CPU 981a will be described. FIG. 168 is a flow chart showing the procedure of interrupt control processing executed by the sub CPU 981a. In this embodiment, the interrupt control process shown in FIG. 168 is executed at 440 fps, that is, at a constant cycle of approximately 2.3 msec, but the present invention is not limited to this, and is executed at a constant cycle of approximately 4 msec, for example. You may In this embodiment, as will be described later, lamp control data (light emission drive data) generation processing is performed in the interrupt control processing. A specific example is shown.

First, the sub CPU 981a determines whether an error has occurred or is in progress (S601). In addition, the condition of "error occurrence or during error" is when the main control circuit 941 and/or the sub-control circuit 942 detects the occurrence of an error. Specifically, the error of the main control circuit 941 is According to the error state of the first game machine, the error of the sub-control circuit 942 is put into the operating state by checking the operating state of the LED driver IC, the sound IC 988, the RTC 986, and / or the backup RAM 985 (not shown). This is the case when an abnormality is detected.

In S601, when the sub CPU 981a determines that an error has occurred or is in error (if the determination in S601 is Yes), the sub CPU 981a switches each light source unit of the special lamp group 1120 (see FIG. 148) according to the error type. error lighting pattern is generated (S602). In this process, the sub CPU 981a controls the light source unit 1120a (hereinafter referred to as “special LED 1”) associated with the No. 400 port number and the light source unit 1120b (hereinafter referred to as “special LED 2”) associated with the No. 401 port number. ), a lighting pattern corresponding to the error type is generated. After the processing of S602, the sub CPU 981a performs the processing of S606, which will be described later.

The error lighting patterns of the light sources of the special lamp group 1120 (see FIG. 148) have the same meanings as the error codes displayed in the sixth and seventh segments.

On the other hand, when the sub CPU 981a determines in S601 that an error has occurred or is not in error (when the determination in S601 is No), the sub CPU 981a determines whether or not it is in the special light emission state (S603). The "special light emission state" referred to here is a state in which a lighting pattern table (not shown) of the special lamp group 1120 is referred to to determine the lighting pattern of the special LEDs 1 and 2. For example, when the power is turned on, and a state immediately after execution of a predetermined initialization process.

In S603, when the sub CPU 981a determines that the special light emitting state is set (when S603 determines Yes), the sub CPU 981a generates a lighting pattern of the special LEDs 1 and 2 in the special light emitting state (S604). In this process, the sub CPU 981a generates a lighting pattern that changes in time series for the special LEDs 1 and 2 in the special light emission state, based on a lighting pattern table (not shown) of the special lamp group 1120 . After the processing of S604, the sub CPU 981a performs the processing of S606, which will be described later.

On the other hand, in S603, when the sub CPU 981a determines that it is not in the special light emitting state (when S603 is No determination), the sub CPU 981a refers to the lighting pattern table (not shown) of the special lamp group 1120, and the effect registration task ( (See FIG. 164), the lighting pattern of the special LEDs 1 and 2 corresponding to the pattern number determined in the special lamp data editing process (S525) is generated (S605). After the processing of S605, the sub CPU 981a performs the processing of S606, which will be described later.

After the processing of S602, S604 or S605, the sub CPU 981a generates PWM values (light emission drive data) corresponding to RGB lighting luminances of the special LEDs 1 and 2 according to the generated lighting patterns of the special LEDs 1 and 2 ( S606).

Next, the sub CPU 981a determines whether or not it is time to turn off the special LEDs 1 and 2 (S607). Incidentally, in the pachi-slot machine 901 of this embodiment, the special LEDs 1 and 2 are turned on for 9.12 msec and then turned off for 9.12 msec. 9. The purpose of repeating the turning on and off of the special LEDs 1 and 2 every 12 msec is that when the special LEDs 1 and 2 are photographed by the camera of the data display machine, the lighting (mainly fluorescent lamps) in the amusement hall (hall) is This is to reduce the influence of emitted noise (flicker, 50 Hz in eastern Japan and 60 Hz in western Japan).

In S607, when the sub CPU 981a determines that it is not the time to turn off the special LEDs 1 and 2 (when the determination in S607 is No), the sub CPU 981a performs the processing of S609, which will be described later. On the other hand, when the sub CPU 981a determines in S607 that it is time to turn off the special LEDs 1 and 2 (when S607 determines Yes), the sub CPU 981a sets the PWM values ( light emission drive data) is generated (S608).

After the processing of S608, or when the determination is No in S607, the sub CPU 981a determines whether or not the back lamp effect is being performed (S609).

In the backlight effect, the sub CPU 981a performs line mask processing at the time of winning on the backlight of the reel that is normally lit, and performs backlight LEDs (eighth lamp group in FIG. 148) that do not correspond to the winning lines. 1018 (reel backlight)) is lowered to a luminance lower than normal (for example, 0). Alternatively, in the backlight effect, the sub CPU 981a generates a PWM value corresponding to the brightness so that the backlight LED corresponding to the winning line blinks. Note that there are actual pay lines and apparent pay lines (pseudo pay lines). In that case, the line mask processing at the time of winning may be performed not on the actual effective line but on the apparent effective line.

In S609, when the sub CPU 981a determines that the back lamp effect is not being performed (when the determination in S609 is No), the sub CPU 981a performs the processing of S611, which will be described later. On the other hand, when the sub CPU 981a determines in S609 that the backlight effect is being performed (if the determination in S609 is Yes), the sub CPU 981a controls the reel backlight in the lamp buffer (see the eighth lamp group 1018 in FIG. 148). ) area (buffer area) is designated, and the PWM values (light emission drive data) corresponding to the brightness (RGB) of the backlight LEDs to be processed by the line mask are rewritten (S610).

After the processing of S610, or when the determination in S609 is No, the sub CPU 981a designates the buffer areas of the special LEDs 1 and 2 (special lamp group 1120) in the lamp buffer, and calculates the PWM values (light emission) corresponding to the luminance (RGB). driving data) is set in the buffer area (S611). The PWM values corresponding to the luminance (RGB) set as the lamp control data (light emission driving data) in the buffer areas of the special LEDs 1 and 2 are the PWM values corresponding to the RGB lighting luminance generated in S606, or the PWM values corresponding to the RGB lighting luminance generated in S606. It is either one of the PWM values corresponding to the RGB extinguishing luminance generated in .

Next, the sub CPU 981a performs 7-segment data generation processing (S612). In this process, the sub CPU 981a corresponds to the display data (numeral and/or character display data) displayed by the 7-digit 7-segment LEDs (1st segment to 7th segment) that constitute the seventh lamp group 1017. Generate segment data. Details of the 7-segment data generation process will be described later with reference to FIG. 169 described later.

Next, the sub CPU 981a performs 7-segment data registration processing (S613). In this process, the sub CPU 981a stores the segment data (light emission driving data) corresponding to the 7-segment LED lamps selected by the dynamic control of the seventh lamp group 1017 in the buffer area for the seventh lamp group 1017 in the lamp buffer. set (write) to the cathode area of Specifically, the sub CPU 981a stores the segment data "C0(a)" in the lamp buffer unit area of the 9th to 15th bytes (cathode area) in the buffer area for the seventh lamp group 1017 shown in FIG. to set "C6(g)" respectively. Details of the 7-segment data registration process will be described later with reference to FIG. 170 described later.

Next, the sub CPU 981a executes a memory barrier (S614). The memory barrier prevents the lamp buffer from being rewritten by another task or the next interrupt control process before the registration (set, write) of various lamp control data (light emission drive data) in the lamp buffer is completed. is done to

Next, the sub CPU 981a executes LED driver IC transfer processing (API) (S615). In this process, the sub CPU 981a generates lamp data according to the transmission format of synchronous serial communication, and transmits the lamp data to the LED driver IC group.

In the process of S615, after transmitting the lamp data, the sub CPU 981a updates the anode selection data (light emission drive data) set in the anode area of the buffer area for the seventh lamp group 1017 in the lamp buffer. Specifically, the sub CPU 981a outputs the anode selection data " A0” to “A6” are updated. For example, the 7-segment LED in the seventh lamp group 1017 selected in the current interrupt control process is the 1st segment, and the 7-segment LED in the seventh lamp group 1017 selected in the next interrupt control process is the 1st segment. In the case of 2 segments, after the lamp data transmission process is performed, the data in which only the anode selection data “A0” corresponding to the 1st segment is ON (see FIG. 157A) corresponds to the 2nd segment. Only the anode selection data "A1" is updated (rewritten) to the ON state data (see FIG. 157B). That is, in the process of S615, after the lamp data is transmitted, the switching process of the 7-segment LED (anode) to be selected is also performed. After the process of S615, the sub CPU 981a terminates the interrupt control process.

[12-10-8.7 segment data generation processing]
Next, with reference to FIG. 169, the 7-segment data generation process performed at S612 in the interrupt control process flowchart (see FIG. 168) will be described. FIG. 169 is a flow chart showing the procedure of the 7-segment data generation process executed by the sub CPU 981a.

First, the sub CPU 981a selects 7 lamps included in the seventh lamp group 1017 from the sub RAM 983 based on the lamp effect data registered in S524 (see FIG. 164) of the effect registration task and S551 of the lamp control task (see FIG. Display data to be displayed by the digit 7-segment LED (1st segment to 7th segment: see FIG. 152) is acquired (S621). The display data acquired in S621 is data (character data) corresponding to the form of information (numbers and characters) actually displayed by the 7-segment LED of each digit. Alternatively, the display data acquired in S621 may be index data for acquiring character data instead of character data to be actually displayed by the 7-segment LED of each digit, and the character data may be acquired from the index data. good.

Next, the sub CPU 981a converts the display data for each of the 7-digit 7-segment LEDs (1st segment to 7th segment) acquired in S621 into segment data (see FIG. 160A) (S622). In the process of S622, among the segments A to G of each 7-segment LED, the segment to be lit is set to the PWM value "63" corresponding to the luminance of 100% as segment data (light emission drive data). A PWM value "0" corresponding to a luminance of 0% is set as segment data (light emission drive data) for segments that are not to be illuminated.

Next, the sub CPU 981a converts each segment data (No. 108 to No. 156 port numbers (see FIG. 148) of the 7-digit 7-segment LED (1st to 7th segments) acquired in the conversion process of S622. The light emission drive data output to the 49 light source units) is stored (registered, set) in the dummy lamp buffer area (see FIG. 156) in the lamp buffer (S623).

Next, the sub CPU 981a performs luminance (PWM value) adjustment processing (S624). Note that in this process, the sub CPU 981a changes the segment data of the segment to be lit when the instruction information is set to adjust the luminance of the 1st to 7th segments to a predetermined luminance value other than 100%. The PWM value is changed to correspond to the predetermined luminance value. However, if the brightness adjustment instruction information does not indicate that there is adjustment, the sub CPU 981a does not perform the brightness (PWM value) adjustment process. After the process of S624, the sub CPU 981a ends the 7-segment data generation process and returns the process to the process of S613 in the interrupt control process (see FIG. 168).

As the adjustment pattern for brightness adjustment, there are a pattern for uniformly adjusting the 1st to 7th segments (first adjustment pattern), and a pattern for adjusting each of the 1st to 7th segments individually (the 1st adjustment pattern). 2 adjustment pattern), and a pattern (third adjustment pattern) for adjusting in units of three groups of the 1st and 2nd segments, the 3rd to 5th segments, and the 6th and 7th segments. It is

When the luminance is adjusted using the first adjustment pattern, the instruction information includes information indicating whether or not luminance is to be adjusted, and one luminance value (target luminance value) for uniform adjustment. When the luminance is adjusted using the second adjustment pattern, the instruction information includes information indicating whether or not luminance is to be adjusted, and seven luminance values (target luminance values) for adjusting each of the first to seventh segments. set. Then, when the luminance is adjusted using the third adjustment pattern, the instruction information includes information indicating whether or not the luminance is to be adjusted, one luminance value (target luminance value) for adjusting the first segment and the second segment, One luminance value (target luminance value) for adjusting the third to fifth segments and one luminance value (target luminance value) for adjusting the sixth and seventh segments are set. Further, the instruction information for luminance adjustment is stored in a predetermined area in any one of the sub-ROM 982, the sub-RAM 983, and the backup RAM 985. FIG.

Furthermore, the target of luminance adjustment may be a segment unit constituting each 7-segment LED instead of a 7-segment LED unit. In this case, more detailed luminance adjustment can be performed for the seventh lamp group 1017 consisting of the first segment to the seventh segment. In this case, the segment data "C0(a)" to "C6(g)" set in the lamp buffer unit area of the 9th byte to the 15th byte (cathode area) in the buffer area for the seventh lamp group 1017 By individually setting each to a target luminance value (PWM value), the luminance can be adjusted in units of segments. For example, segments A to C and segments E to G of the first segment can be lit with a luminance of 100%, and segment D of the first segment can be lit with a luminance of about 49%. In this case, the adjustment pattern for brightness adjustment is the above-described second adjustment pattern, but the instruction information includes the brightness values (target brightness values) of segments A to G of the first segment to the seventh segment, respectively. It will be.

[12-10-9.7 segment data registration process]
Next, referring to FIG. 170, the 7-segment data registration process performed at S613 in the interrupt control process flowchart (see FIG. 168) will be described. FIG. 170 is a flow chart showing the procedure of the 7-segment data registration process executed by the sub CPU 981a.

First, the sub CPU 981a reads the anode selection data "A0" to "A6" stored in the buffer area (see FIG. 156) for the seventh lamp group 1017 of the lamp buffer (S631).

Next, the sub CPU 981a refers to the anode selection data read out in S631, and selects (lights up) in this interrupt process among the dynamically controlled 7-digit 7-segment LEDs (1st to 7th segments). A 7-segment LED is specified (S632). In this process, the sub CPU 981a sets the read anode selection data "A0" to "A6" to the PWM value "63" (ON state) corresponding to the luminance of 100% (see FIG. 157). ), and the 7-segment LED corresponding to the lamp buffer unit area is specified as the 7-segment LED to be selected in this interrupt process.

Next, the sub CPU 981a outputs segment data from the dummy lamp buffer area (see FIG. 156) of the lamp buffer to the selected 7-segment LED (one of the 1st to 7th segments) specified in S632. (Cathode output data) is read out (S633). For example, if the 7-segment LED to be selected identified in S632 is the 1st segment, the sub CPU 981a selects the lamp buffer unit area of the 1st byte (head) to 7th byte in the dummy lamp buffer area. The light emission driving data (port numbers of No. 108 to No. 114) stored in the data are read out as segment data. Further, for example, when the 7-segment LED to be selected specified in S632 is the 3rd segment, the sub CPU 981a selects the lamp buffer unit area of the 17th byte to the 23rd byte in the buffer area for the dummy lamp. The stored light emission drive data (port numbers No. 122 to No. 128) are read out as segment data.

Next, the sub CPU 981a registers (stores, sets) the segment data (cathode output data) read in S633 in the buffer area for the seventh lamp group 1017 (S634). Specifically, the sub CPU 981a sets the read segment data in the lamp buffer unit area (see FIG. 156) of the 9th to 15th bytes (cathode area) in the buffer area for the seventh lamp group 1017 (see FIG. 156). write). After the process of S634, the sub CPU 981a ends the 7-segment data registration process and returns the process to the process of S614 in the interrupt control process (see FIG. 168).

[12-11. Effect Obtained by the Fourth Gaming Machine]
In the pachi-slot machine 901 (fourth gaming machine) of the above embodiment, as described above, among the various lamp groups driven and controlled by the sub CPU 981a, the 7 digit (7) 7 The segmented LEDs are driven with dynamic control instead of static control. In this case, compared to static control of the seventh lamp group 1017, the number of LED driver ICs mounted in the sub-control circuit 942 can be reduced, and the price and development cost of the pachi-slot machine 901 can be reduced.

[12-12. Note]
In a conventional game machine, there has been proposed a game machine equipped with a segment display device that selectively emits light from a plurality of segments to display arbitrary numbers and characters under the control of a sub-control board (for example, Japanese Unexamined Patent Application Publication No. 2008-2008). 295655). In the gaming machine disclosed in Japanese Patent Application Laid-Open No. 2008-295655, the sub-control board transmits segment image data to the image control board, and the image control board displays the segment image.

However, for example, in the game machine disclosed in Japanese Unexamined Patent Application Publication No. 2008-295655, the purpose is to cope with an increase in segment size at low cost while maintaining good display quality. ), there is a demand for a technology capable of further reducing both manufacturing costs and development costs.

The present invention has been made in view of these points, and makes it possible to further reduce both the manufacturing cost and the development cost in a game machine equipped with a function of controlling the display of a plurality of segments on the sub side. for the purpose.

In order to achieve the above object, according to the gaming machine according to the present embodiment, it is possible to provide a gaming machine having the following configuration.

Light emitting means (for example, various lamp groups),
a plurality of light emission drive means (for example, a group of LED driver ICs) for driving the light emission means;
A control means (for example, a sub microprocessor 981) for driving the plurality of light emission drive means and controlling the light emission operation of the light emission means,
The light emitting means has a plurality of multicolor light emitting means (for example, light source units such as the first lamp group 1011) and a plurality of segment light emitting means (for example, the first segment to the seventh segment of the seventh lamp group 1017). ,
The multicolor light emitting means is composed of light emitting elements capable of emitting color light, the segment light emitting means is composed of a plurality of segment light emitting elements,
The control means is
light emission data generation means (e.g., interrupt control processing, lamp control task) for generating light emission data (e.g., light emission drive data) for controlling the light emission drive means;
and data storage means (for example, a lamp buffer) for storing the light emission data generated by the light emission data generation means.

In the gaming machine of the present invention, the control means may drive the plurality of multicolor light emitting means by static control and drive the plurality of segment light emitting means by dynamic control.

In the gaming machine of the present invention, the data storage means
a first storage area (for example, a buffer area for the first lamp group 1011, etc.) for storing first light emission data for driving and controlling the plurality of multicolor light emitting means;
a second storage area (for example, an anode area in the seventh lamp group 1017) in which selection information for selecting one segment light emitting means from among the plurality of segment light emitting means is stored;
a third storage area (for example, a cathode area in the seventh lamp group 1017) for storing second light emission data for driving and controlling one selected segment light emitting means;
A fourth storage area (for example, a dummy lamp buffer area, etc.) for storing all of the plurality of second light emission data for driving and controlling the plurality of segment light emitting means may be provided. .

In the gaming machine of the present invention, the control means has light emission data transmission means (for example, synchronous serial communication circuit 981c) for transmitting the light emission data stored in the data storage means to the plurality of light emission drive means. ,
The light emission data transmitted by the light emission data transmitting means includes the first light emission data stored in the first storage area, the selection information stored in the second storage area, and the selection information stored in the third storage area. The stored second light emission data and a plurality of the second light emission data stored in the fourth storage area may be included.

In the gaming machine of the present invention, the data storage means may be included in the light emission data transmission means.

In the gaming machine of the present invention, the control means transfers the selection information stored in the second storage area to the plurality of segment light emission means after the light emission data is transmitted by the light emission data transmission means. may be updated to selection information specifying the segment light emitting means to be selected next.

In the gaming machine of the present invention, when the control means sets the second light emission data for driving and controlling the selected one segment light emission means in the third storage area, The second light emission data of the stored corresponding segment light emission means may be read out and set in the third storage area.

In the gaming machine of the present invention, the process of setting the first light emission data in the first storage area and the process of setting the second light emission data in the third storage area are executed at different timings. is,
The processing of setting the second light emission data in the third storage area may be performed at regular intervals (for example, interrupt control processing executed by the sub CPU 981a).

In the gaming machine of the present invention, it is possible to further provide light emission drive means different from the plurality of light emission drive means,
In the data storage means, the first storage area, the second storage area, and the third storage area are storage areas allocated to the plurality of light emission driving means, and the fourth storage area is the It may be a storage area assigned to another light emission driving means.

In the gaming machine of the present invention, the plurality of light emission driving means may have the same structure.

According to the gaming machine of the present invention having the above configuration, both the manufacturing cost and the development cost can be further reduced in the gaming machine having the function of controlling the display of a plurality of segments on the sub side.

[13. Fifth gaming machine]
Next, with reference to FIGS. 171 to 192, another specific example (one embodiment) of the pachi-slot machine will be described as a "fifth game machine." It should be noted that part or all of the configuration described as the fifth gaming machine in the present embodiment can be applied to other gaming machines described in the present embodiment. Part or all of the configuration described as the gaming machine in 1 can be applied to the configuration described as the fifth gaming machine in the present embodiment. In other words, an appropriate combination of these can be used as the invention according to the present embodiment.

[13-1. Configuration of the sub-control circuit of the pachislot machine]
First, referring to FIG. 171, the configuration of the sub-control circuit 200 provided in the fifth gaming machine (pachi-slot machine) will be described. FIG. 171 is a block diagram showing the configuration of the sub-control circuit of the fifth game machine (pachi-slot machine). In addition, in the configuration of the control system of the fifth game machine shown in FIG. The same reference numerals are given, and the description of the constituent parts is omitted.

<Sub-control circuit 200>
FIG. 7 shows the configuration of the sub-control circuit 200 of the pachi-slot machine 10 according to this embodiment.

The sub-control circuit 200 is electrically connected to the main control circuit 100, and performs processing such as determination and execution of effects based on commands transmitted from the main control circuit 100. FIG. The sub control circuit 200 basically includes a CPU 201 (hereinafter referred to as sub CPU 201), a ROM 204 (hereinafter referred to as sub ROM 204), a RAM 203 (hereinafter referred to as sub RAM 203), a rendering processor 258, and a drawing RAM 260. , a driver 262, a DSP 264 (digital signal processor), an audio RAM 266, an amplifier 270 for medium and low to high sounds, a low-pass filter 271, an amplifier 271 for low sounds, and the like.

The sub CPU 201 controls output of video, sound, and light in accordance with a control program stored in the sub ROM 204 in response to commands transmitted from the main control circuit 100 . Further, the sound volume for performing the voice control task in the DSP 264 is adjusted in accordance with the operation signals in the first operation method and the second operation method. The first operation method is an operation method performed by manual operation means that can be operated on the hall side, and the second operation method is an operation method that can be manually operated by the player side. Operations using the first operation method and the second operation method will be described later.

The sub-RAM 203 is provided with a storage area for registering determined effect contents and effect data, and a storage area for storing various data such as internal winning combinations transmitted from the main control circuit 100 . The sub-ROM 204 is basically composed of a program storage area and a data storage area.

A control program executed by the sub CPU 201 is stored in the program storage area. For example, the control program includes a main board communication task for controlling communication with the main control circuit 100, and an effect registration task for extracting a random number for effect and determining and registering effect content (effect data). , a drawing control task for controlling the display of images by the display devices 210 and 220 based on the determined effect content, a lamp control task for controlling light output by the lamp 23, and a sound control task for controlling sound output by the speakers 35a and 35b. Tasks, etc. are included.

The data storage area includes a storage area for storing various data tables, a storage area for storing effect data that constitutes each effect content, a storage area for storing animation data related to video creation, and a storage area for storing sound data related to BGM and sound effects. It includes a storage area, a storage area for storing lamp data relating to the pattern of turning on and off the light, and the like.

Display devices 210 and 220, speakers 35a and 35b, low-frequency speakers and a lamp 23 are connected to the sub-control circuit 200 as peripheral devices whose operations are controlled.

The sub CPU 201, rendering processor 258, drawing RAM 260 (including a frame buffer), and driver 262 create an image in accordance with animation data specified by the effect content, and display the created image on the display devices 210 and 220.

In addition, the sub CPU 201, DSP 264, audio RAM 266, amplifier 270, low-pass filter 271, and bass amplifier 272 output sounds such as BGM from speakers 35a and 35b and bass speakers according to sound data specified by the content of the presentation. . Also, the sub CPU 201 turns on and off the lamp 23 according to the lamp data specified by the content of the effect.

<Sound output control unit>
The sound volume control section is composed of the DSP 264, the amplifier 270, the low-pass filter 271, and the bass amplifier 271, and together with the audio RAM 266 as the sound source section, the sound output control section 269 is configured.

[13-2. How to adjust the volume]
Next, with reference to FIGS. 172 to 176, a first operation method and a second operation method for volume adjustment relating to a fifth game machine (pachi-slot machine) will be described. FIG. 172 is a schematic diagram showing the menu screen of the fifth gaming machine (pachi-slot machine). FIG. 173 is a schematic diagram showing the volume setting mode of the fifth gaming machine (pachi-slot machine). FIG. 174 is an image diagram of the design specifications regarding the setting of the volume adjustment range by the hall side of the fifth gaming machine (pachi-slot machine). FIG. 175 is a schematic explanatory diagram showing a screen in which the player of the fifth gaming machine (pachi-slot machine) can select the sound volume level. FIG. 176 is a schematic explanatory diagram showing a sound volume level setting screen by the player side of the fifth gaming machine (pachi-slot machine).

<First operation method>
In this embodiment, in order to display the setting change operation shown in FIG. 172 on the main display device 210, the normal operation by the staff and the adjustment operation of the volume output from the speakers 35a and 35b are configured.

In normal operation, a staff member rotates the front door 30 to release the lock mechanism and turns on the setting key-type switch 52 shown in FIG. The hall menu screen is displayed. When the staff presses the selection switch (SELECT key) 222 seven times, the selected state can be changed from the "time setting" state to the "volume mode setting" state. By pressing it once more, it is possible to return to the "time setting" state.

By pressing the enter switch (ENTER key) 223 in the "volume mode setting" state, a volume mode setting screen shown in FIG. 173 is displayed on the liquid crystal display area 210a. This screen is a screen that can be operated on the hall side, and is a screen that allows the first operation method in the fifth gaming machine (pachi-slot machine) to be operated. By pressing a selection switch (SELECT key) 222 on this screen, it is possible to switch between "MODE 1"→"ON"→"CANCEL"→"SET"→"MODE 1". When "ON" is selected with the enter key (ENTER key), the player is permitted to adjust the volume level output from the speakers 35a and 35b, as will be described later.

Further, for example, by pressing the determination switch (ENTER key) 223 while "MODE 1" is selected, it is possible to switch from "MODE 1"→"MODE 2"→"MODE 3"→"MODE 1". By pressing a cancel key (CANCEL key), it is possible to abandon the setting contents on this screen and return to the hall menu screen shown in FIG. By pressing the set key (SET key), for example, the content of "MODE 1" selected by the enter key (ENTER key) is determined, and the screen returns to the hall menu screen shown in FIG.

One mode is selected from "MODE1" to "MODE3" with an enter key (ENTER key). When "MODE 1" is selected, the volume adjustment range of mode I shown in FIG. 174(a) is selected. When "MODE2" is selected, the mode II volume adjustment range shown in FIG. 174(b) is selected, and when "MODE3" is selected, the mode III volume adjustment range shown in FIG. 174(c) is selected. be done.

Mode I shown in FIG. 174(a) is a basic mode, and sets a volume adjustment range of volume levels that can be selected by the player. When mode I is set by the hall side, the player can freely select the volume level from 1 to 7 indicated by the volume value within the volume adjustment range in the basic mode. Also, the hall side can set one volume level in advance as an initial setting value from the volume adjustment range in the basic mode.

The initial set value can be set by sliding the slide switch 228 in the order of “large” → “medium” → “small” → “medium”. In the illustrated example, "small" corresponds to a volume level of "1", "medium" corresponds to a volume level of "4", and "large" corresponds to a volume level of "7".
The slide switch 228 is arranged in the circuit board of the sub-control circuit 200 of FIG. 171, and can set the initial set value by sliding it on the hall side.

The correspondence between the slide switch 228 and the volume level described above is an example, and the present invention is not limited to the correspondence described above. Therefore, for example, a relationship is set such that "small" corresponds to a volume level of "2", "medium" corresponds to a volume level of "4", and "loud" corresponds to a volume level of "6". You can also keep it.

In FIG. 171, the encoder data sent from the DSP 264 to the digital amplifier 270 is processed so as to have a volume value corresponding to the initial setting value or the volume level selected by the player, which will be described later, and supplied to the speakers 35a and 35b. will be The data whose volume level has been adjusted is passed through the low-pass filter 271 and supplied to the amplifier 271 for bass. By performing control processing from the DSP 264 on the amplifier 271 for bass, it is possible to adjust the volume for bass.

Mode II shown in FIG. 174(b) is a regulation-compliant mode, in which the volume adjustment range is shifted from the volume adjustment range in mode I to the region with a smaller volume value. Mode III is a more restrictive mode than Mode II, and has a volume adjustment range that is shifted to a region with a smaller volume value than the volume adjustment range in Mode II.

Mode II shows a case where the slide switch 228 is set to "middle" and the volume level is set to "4" as the initial setting values. Mode III shown in FIG. 174(c) shows the case where the slide switch 228 is set to "low" and the volume level is set to "1".

In mode II and mode III, the volume level output from the speakers 35a and 35b can be adjusted from a small volume level to a relatively high volume level according to the request of the hall side. can operate.

The association between the slide switch 228 and the volume level in each mode I to mode III can be arbitrarily set at the design stage. However, in the setting on the hall side on the hall menu screen and the volume adjustment on the player side, which will be described later, it is not possible to set the association between the slide switch 228 and the volume level.

Further, by setting the initial setting value, the volume output from the speakers 35a and 35b can be set to the initial setting value when the gaming machine is turned on and the slide switch 228 is operated. Also, as will be described later, when the gaming machine in which the player has set the volume level is no longer in the gaming state, the volume level can be returned to the initial setting value set on the hall side.

In this way, the hall side can limit the adjustment range of the speaker sound volume that the player can make, so that there is an advantage that the hall can be managed properly. In addition, the player can freely set the volume of the BGM to suit his or her taste, so that the player can enjoy the game in a comfortable environment.

After one mode is selected from "MODE1" to "MODE3" and the volume adjustment range is set, the set volume adjustment range and the initial setting are performed by pressing the set key (SET key) shown in FIG. The value is determined, and the screen returns to the hole menu screen shown in FIG. 175 can be displayed in the liquid crystal display area 210a by turning off the setting key-shaped switch 52 shown in FIG. 3 after various settings are completed.

In the above description, the hall side sets the volume adjustment range using the slide switch 228 provided in the housing. However, the setting of the volume adjustment range is not limited to the slide switch or volume switch provided on the housing. The volume adjustment range may be set using, for example, a setting menu that can be displayed by the hall side (clerk). Also, the fifth gaming machine (pachi-slot machine) may be a gaming machine that does not have a volume adjustment range setting.

<Second method of operation>
In FIG. 173, when the volume mode is set on the hall side and "ON" is selected with the enter key (ENTER key), the player can adjust the volume level output from the speakers 35a and 35b. is possible. After various settings have been completed and the screen is switched to the hall menu screen shown in FIG. 172, the front door 30 is rotated to turn off the setting key-type switch 52 shown in FIG. In 210a, the screen shown in FIG. 175 can be displayed. Then, the front door 30 is rotated to lock the lock mechanism.

The screen shown in FIG. 175 is a screen on which a player can play. This screen is a screen on which the player can operate the sound volume level, and is a screen for operating the second operating method in the present invention.

At the bottom of the display liquid crystal display area 210a, a message to the effect that "the volume can be adjusted by long-pressing the middle button" appears. If the stop button 8C (middle button) shown in FIG. 1 is pressed and held, for example, if it is pressed and held for about 5 seconds, as shown in FIG. , the screen switches to a screen where you can change the volume level.

At this time, the player can select one of seven volume levels, and the hall side selects one of "MODE 1" to "MODE 3" and selects "MODE 1" to "MODE 3" within the volume adjustment range set in advance. A rectangular gauge corresponding to the sound volume level of "7" is shown in seven steps. The rectangular gauge is displayed in a larger shape according to the volume level. The number "4" shown in the center is a number indicating the volume as an indicator, and is interlocked with the gauge shown on the lower side.

Then, the screen displays a state in which the gauge corresponding to the initial set value set on the hall side is colored in green, for example. In the illustrated example, a case where volume level "4" is set as the initial set value is shown, and the gauge up to volume level "4" is hatched.

As the stop button 8R shown in FIG. 1 is pushed, the gauges are colored sequentially up to the volume level selected by the player within the volume adjustment range preset by the hall side. In conjunction with the coloration of the gauge, the number displayed in the center also increases from "4". Moreover, the electronic operation sound of volume level corresponding to the selected gauge is output in conjunction with the selected gauge.

When the gauge corresponding to the maximum sound volume is colored by the player's selection, the number shown in the center displays "7" and the electronic operation sound is output at the maximum sound volume level. In this way, the player can freely set the volume level within the volume adjustment range set in advance by the hall side, and the effect sound, BGM, etc., can be output from the speakers 35a and 35b at the set volume level. can be done.

Also, by pressing the stop button 8L shown in FIG. The numbers shown in , will also change to smaller numbers.

When the player selects a volume level outside the volume adjustment range preset by the hall side, for example, when the player continues to press the stop button 8R despite reaching the maximum volume level, The entire gauge can be colored and flashed, for example, yellow, which is a color different from green. As for the number of flashes, it can be flashed at least once. Also, the volume level is not set to a volume level outside the preset volume adjustment range.

When the player has not performed an adjustment operation for, for example, 30 seconds or more, when the start button 8C (middle button) is operated, or when the start lever 7 is operated, the volume is adjusted. It is possible to reflect the contents of the player's change to and end.

As the first determination condition, it is determined whether or not the value of the inserted number counter is 0 (zero) and the value of the credit counter is 0 (zero). You can set it as when For example, an elapsed time of 30 seconds can be set as the first time.
Also, as a second judgment condition, it is judged whether or not the start switch 7S is turned ON after medal insertion or the value of the credit counter is 1 or more, and the judgment is "YES". You can set it from time to time. As the second time, for example, an elapsed time of one hour can be set. When such a determination condition is satisfied, the volume level can be returned to the initial setting set on the hall side.

Also, when the settlement button 9 for returning the credited game media is operated, the volume level can be returned to the initial setting set on the hall side.
The time when the settlement button 9 is operated may be set as the time when the settlement button 9 is operated, or may be set as when a predetermined third time has passed since the settlement button 9 was operated. be able to. As for the length of the first time to the third time, for example, the third time is set to be shorter than the first time, and the second time is set to be longer than the first time. can be set.
If the player wants to change the sound volume level during the game, he/she can switch to the screen shown in FIG. 176 by pressing the stop button 8C for a long time. Although the configuration for adjusting the sound volume level using the stop buttons 8R, 8C, and 8L has been described, the liquid crystal display area 210a may be provided with a touch panel function to replace the operation with the stop buttons. Further, an operation button for volume adjustment may be provided, and the volume level may be adjusted using the operation button for volume adjustment.

In this way, when a predetermined condition is satisfied, the state set by the player can be canceled and the initial set value set by the hall side can be restored. Under the control of the hall side, the player side can also be allowed to freely select the speaker volume to some extent. Moreover, when a game is not being played in the gaming machine, it is possible to automatically return to the preset initial set value.

In the fifth game machine (pachi-slot machine), the set volume adjustment range, the initial setting value, and the contents of the volume level set by the player are stored in the sub-RAM 203 . Then, even if the power is turned off, it is retained without disappearing. When one mode is selected from "MODE 1" to "MODE 3" and the above-described settings are newly made, or when the player newly sets the sound volume level, the new setting contents are changed. It will be overwritten and saved in the sub-RAM 203 .

Although the time and conditions for returning the volume level set by the player to the initial set value set by the hall side have been described above, the above-described times and conditions are only examples and should be considered when designing the game machine. It can be changed as appropriate. Also, the passage of time can be measured by the clock function incorporated in the sub CPU 201 shown in FIG.

<Other setting screens related to the second operation method>
Next, another setting screen for the second operation method will be described with reference to FIGS. 177 and 178. FIG.
FIG. 177 is a diagram for explaining an operation method for collectively setting volume levels for a plurality of categories. FIG. 178 is a diagram for explaining an operation method for individually setting volume levels for a plurality of categories.

177 and 178, another setting screen for the second operation method displays an overall volume meter 231 and a plurality of categorized volume meters 232-234. The total volume is the unified volume of all categories. Examples of category types include "BGM", "SE", and "VOICE". In this embodiment, the categorized volume meter 232 indicates the volume meter of "BGM". Further, the category-specific volume meter 233 indicates the volume meter of "SE", and the category-specific volume meter 234 indicates the volume meter of "VOICE".

"BGM" is so-called background music, which is output to create an atmosphere in each game state such as a normal game state, an ART game state, or the like. "SE" is a so-called sound effect, which is a sound effect output according to the presentation. “VOICE” is, for example, a voice emitted by a character associated with each type of gaming machine.

Each of the volume meters 231 to 234 shows a rectangular gauge corresponding to the above-mentioned volume levels "1" to "7" in seven stages. The seven gauges are arranged vertically at predetermined intervals. The global volume meter 231 is colored up to the gauge corresponding to the current volume level of global volume. Each categorical volume meter 232-234 is colored up to the gauge corresponding to the current volume level of each category. The volume level increases as the color of the gauge increases. Note that the number of gauges is not limited to seven, and can be set as appropriate.

When the stop button 8C (middle button) shown in FIG. 1 is pressed for a long time, for example, when the stop button 8C is pressed for about 5 seconds, a volume setting screen shown in FIGS. 177 and 178 is displayed. In addition, operate the volume adjustment key. The volume setting screen may be displayed by an operation such as touching the portion where the volume adjustment icon is displayed on the touch panel. All or two or more of the plurality of operations described above may be possible as the operation for displaying the volume setting screen. Then, the player selects the volume meter to be set. In the fifth game machine (pachi-slot machine), the volume meter to be selected is switched each time the effect button 10a (see FIG. 1) is pressed.

To collectively set the volume of all categories to the same volume level, select the overall volume meter 231 as shown in FIG. Each time the stop button 8R (see FIG. 1) is pressed, the gauge of the overall sound volume meter 231 is sequentially colored. Further, in conjunction with the coloration of the gauge of the overall volume level meter 231, the gauges of the category volume meters 232 to 234 are also colored. On the other hand, each time the stop button 8L (see FIG. 1) is pressed, the coloring of the gauge of the overall sound volume meter 231 disappears one by one. Further, in conjunction with the disappearance of the gauge of the overall volume level meter 231, the gauges of the category volume meters 232 to 234 also disappear. By selecting the overall volume meter 231 in this way, the volume level can be quickly set. It should be noted that the operation of increasing or decreasing the volume may be performed using a volume adjustment key or a touch panel instead of the stop button. For example, when using a touch panel, when the third square from the top of seven square volume icons indicating seven levels of volume is touched as shown in FIG. 177, volume level 5 is set. When a button such as a stop button is used, the volume is raised or lowered one step at a time, but when a touch panel is used, there is an advantage that a desired volume can be changed with a single operation.

When setting the volume level of each category individually, as shown in FIG. 178, select the volume meter for each category to be set. At this time, the overall sound volume meter 231 enters a standby state. The entire sound volume meter 231 in the standby state changes the overall color to a translucent or light color in displaying the volume level immediately before the standby state. After selecting the categorical sound volume meter to be set, each time the stop button 8R is pressed, the gauge of the selected categorical sound volume meter is sequentially colored. On the other hand, each time the stop button 8L is pressed, the coloring of the gauge of the volume meter for each selected category disappears one by one. In this way, when the volume level of each category is individually set, for example, the volume level of "VOICE" is set higher than that of other categories to make the character's voice stand out. You can adjust the volume level.
Also, instead of using the stop button, an operation for increasing or decreasing the volume may be performed by operating a volume adjustment key or a touch panel. For example, when a touch panel is used, the volume can be adjusted intuitively by touching the item desired to be adjusted among the categorized volume meters 232 to 234 in FIG. Also, when either the overall volume meter or the category volume meter is touched at the same time, either one may be prioritized, or the volume setting value may not be changed based on the touch operation. . When multiple category-specific volume meters are touched at the same time, if the touch panel is hardware capable of two-point detection, both operations may be reflected, only one operation may be valid, or both operations may be enabled. operation may be invalidated and the volume value may not be changed.
It should be noted that even after the volume has been adjusted by the category-specific volume meters 232 to 234, the overall volume can be adjusted by the overall volume meter 231, and the volume adjustment operation (touch, button, etc.) on the overall volume meter 231 can be performed. ) is performed, the volume value information of the volume meter by category at that time is updated to the value based on the overall volume. For example, after making adjustments using the category-specific volume meter to set volume levels 6, 4, and 5 shown in FIG. It can be changed to 5-5-5. It should be noted that preparing the volume keys for the number of categories increases the cost in terms of hardware configuration. Therefore, a cursor that indicates the currently active volume meter with the four-way controller or production button (instead of the cursor, the active meter or the circumference of the meter, etc. blinks, or is brighter than other meters) Any mode that allows the player to recognize that it is active) may be moved to enable operation of the volume key for the active meter.

In another setting screen related to the second operation method, an overall volume meter 231 is provided for collectively setting the volumes of all categories to the same volume level. However, in the fifth gaming machine (pachi-slot machine), the total volume meter 231 may not be provided, and only a plurality of categorized volume meters 232 to 234 may be provided.

[13-3. Pachislot mobile terminal linkage function]
Hereinafter, the portable terminal cooperation function of the fifth gaming machine (pachi-slot machine) will be described as an example with reference to FIGS. 179 to 185. FIG.

The mobile terminal cooperation function of the fifth gaming machine (pachi-slot machine) is a function of linking the fifth gaming machine (pachi-slot machine) and the mobile terminal. By using the mobile terminal cooperation function of the fifth gaming machine (pachislot machine), it is possible to record detailed information on the game played by the player, or to use the fifth gaming machine (pachislot machine) by satisfying a predetermined condition. It is possible to customize functions that do not affect game results.

As the predetermined condition, for example, a specific minor combination (internal winning combination) is continuously determined, or a specific effect is executed. In addition, customizing functions that do not affect the game results of the fifth gaming machine (pachislot machine) include, for example, changing the music output during ART or pseudo-bonus to a special tune, For example, the costume of the character displayed on the display device 210 or the sub-display device 220 is changed.

When using the mobile terminal cooperation function, first, an initial guide image is displayed in the liquid crystal display area 210a of the main display device 210 (hereinafter referred to as "main screen 210a"). For example, when the performance buttons 10a and 10b (see FIG. 1) are pressed while the unit game is finished, an initial guide image is displayed in the liquid crystal display area 210a.

FIG. 179 shows a state in which the guide initial image is displayed in the liquid crystal display area 210a. 179 and subsequent figures, the sub-display device 220 is arranged on the left side of the gaming machine body 2. As shown in FIG. The position of the sub display device 220 can be set as appropriate.
The initial guide image includes the characters "Unimemo (registered trademark)" and the characters "Please select your favorite menu".

As shown in FIG. 179, when the guide initial image is displayed on the main screen 210a, the guide menu screen is displayed on the liquid crystal display area 220a of the sub display device 220 (hereinafter referred to as "sub screen 220a"). be. A plurality of guide menus are displayed on the guide menu screen. Items of the guide menu include "start Unimemo", "arrangement/dividend", "model site", and "return to game". Each guide menu is displayed as a rectangular button with a character string of the item name arranged in the center.

When "Start Unimemo" is selected from the guide menu, a Unimemo initial image is displayed on the main screen 210a (see FIG. 182). Further, when "arrangement/payout" is selected, an arrangement/payout initial image is displayed on the main screen 210a (not shown). Then, when "model site" is selected, a registration code for model site is displayed on the main screen 210a.

When "return to game" is selected, the display of the guide initial image on the main screen 210a and the display of the guide menu on the sub-screen 220a end. On the main screen 210a and the sub-screen 220a, there are displayed images for effects to be displayed when a game is played, and initial images to be displayed when the fifth gaming machine (pachi-slot machine) is not operated for a predetermined period of time. be. In addition, even if a predetermined time has passed without touching any item of the guide menu, the main screen 210a and the sub-screen 220a display the effect image displayed when playing the game, the fifth game An initial image to be displayed when the machine (pachi-slot machine) has not been operated for a predetermined period of time is displayed.

When the guide menu screen is displayed, the sub CPU 201 detects that each guide menu has been selected by the player when the finger touching the touch input portion overlapping the sub screen 220a leaves the touch input portion. do the execution. Also, the sub CPU 201 displays the guide menu displayed at the position on the sub screen 220a corresponding to the position touched by the player's finger on the touch input unit so as to be distinguishable from other guide menu buttons. In the present embodiment, the sub-CPU 201 performs highlight display in which the button of the target guide menu is illuminated so as to be distinguishable from the buttons of other guide menus. Instead of highlighting, the target guide menu button may be enlarged and displayed so as to be distinguishable from other guide menu buttons.

For example, as shown in FIG. 180, when the player touches the touch input unit, the position corresponding to the position where the guide menu "arrangement/dividend" of the sub-screen 220a is displayed (in this embodiment, the guide menu "arrangement/payout" is displayed). When the finger touches the position facing the "payout" in the front-rear direction, the sub CPU 201 highlights the "arrangement/payout" of the guide menu, that is, displays the "arrangement/payout" of the guide menu with a light. In this state, when the player releases his/her finger from the touch input unit, the sub CPU 201 detects that the player has selected "arrangement/dividend" in the guide menu.

While "Arrangement/Payout" of the guide menu is highlighted, the player touches the screen outside the position corresponding to the position where "Arrangement/Payout" of the guide menu is displayed without releasing the finger from the touch input section. When the finger is moved to , the sub CPU 201 terminates the highlight display of "arrangement/dividend" in the guide menu. In this case, the sub CPU 201 does not detect that the player has selected the "arrangement/dividend" of the guide menu. Then, as shown in FIG. 181, when the player moves his/her finger to a position corresponding to the position where "Start Unimemo" of the guide menu is displayed, the sub CPU 201 displays "Start Unimemo" of the guide menu. highlight. In this state, when the player releases his/her finger from the touch input unit, the sub CPU 201 detects that the player has selected "start Unimemo" in the guide menu.
That is, if the player does not remove his/her finger from the touch input section, the sub-screen 220a is displayed at a position (in this embodiment, facing in the front-rear direction) corresponding to the position outside the position where the touch input section was first touched. You can select any guide menu.

A specific operation of the sub CPU 201 when the guide menu screen as described above is displayed on the sub screen 220a will be described. First, the sub CPU 201 detects that the player has touched the touch input unit with his/her finger, and the position coordinates (the operation XY coordinate data described above) of the position touched by the player's finger. Next, the sub CPU 201 causes the guide menu to be displayed at a position on the sub screen 220a corresponding to the detected position coordinates (in this embodiment, a position opposite to the position touched by the player's finger in the front-rear direction). If so, highlight the guide menu button. Also, the sub CPU 201 acquires the position coordinates of the position touched by the player's finger at a predetermined cycle, every 50 msec in this embodiment. When the sub CPU 201 detects that the player's finger has left the touch input unit, the sub CPU 201 determines the last acquired position coordinates as the selection coordinates, and the guide menu is displayed at the position corresponding to the selection coordinates on the sub screen 220a. If it is displayed, it detects that the guide menu has been selected by the player.

FIG. 182 shows a state in which the Unimemo initial image is displayed on the main screen 210a.
The Unimemo initial image includes the characters "Unimemo" and the characters "Let's customize your favorite character".

As shown in FIG. 182, when the uni-memo initial image is displayed on the main screen 210a, the uni-memo menu screen is displayed on the sub-screen 220a. A plurality of Unimemo menus are displayed on the Unimemo menu screen. Items of the Unimemo menu include "password input", "record", "record and exit", "member registration", "return to game", and "return". Each Unimemo menu is displayed as a rectangular button with a character string of the item name arranged in the center. When the Unimemo menu screen is displayed, the sub CPU 201 detects that each Unimemo menu has been selected by the player when the finger touching the touch input unit leaves the touch input unit, as described above. .

When "password input" is selected, a password display image is displayed on the main screen 210a (see FIG. 183).

FIG. 183 shows a state in which a password display image is displayed on the main screen 210a.
The password display image includes characters "Please enter password".

As shown in FIG. 183, when the password display image is displayed on the main screen 210a, the password input menu screen is displayed on the sub-screen 220a. A plurality of password input menus are displayed on the password input menu screen. Items of the password input menu include "determine", "delete", "0" to "9", "A" to "F", "return to game", and "return". Each password input menu is displayed as a rectangular button with a character string of an item name arranged in the center.

When "0" to "9" and "A" to "F" in the password input menu are selected, the selected characters are input and displayed on the password display image. When "determine" in the password input menu is selected, a plurality of characters displayed in the password display image are determined as the password to be input. Then, when "delete" in the password input menu is selected, the last input character is deleted from the password display image.

When "return to game" in the password input menu is selected, the main screen 210a and the sub-screen 220a display an effect image to be displayed when the game is played, and the fifth gaming machine (pachi-slot machine) is displayed for a predetermined period of time. An initial image to be displayed when no operation is performed is displayed. In addition, even when a predetermined time has passed without any item of the password input menu being selected, the main screen 210a and the sub-screen 220a display an effect image displayed when the game is played, and the fifth game. An initial image to be displayed when the machine (pachi-slot machine) has not been operated for a predetermined period of time is displayed. Further, when "return" of the password input menu is selected, a Unimemo initial image is displayed on the main screen 210a, and a Unimemo menu is displayed on the subscreen 220a (see FIG. 182).

When the password input menu screen is displayed, the sub CPU 201 detects that each password menu has been selected by the player when the finger touching the touch input section leaves the touch input section, as described above. For example, as shown in FIG. 183, when the player touches the position corresponding to the position where “E” of the password input menu is displayed (facing in the front-rear direction) on the touch input unit, the sub CPU 201 will highlight the "E" in the password entry menu. Then, as shown in FIG. 184, when the player moves his/her finger on the touch input unit to a position corresponding to the position where "F" of the password input menu is displayed, the sub CPU 201 displays the password input menu. end the highlighting of "E" in the password input menu and highlight "F" in the password input menu. In this case, the sub CPU 201 does not detect that the player has selected "E" in the password input menu. Further, when the player releases the finger from the touch input unit while "F" in the password input menu is highlighted, the sub CPU 201 detects that "F" in the password input menu has been selected by the player. to detect Then, the sub CPU 201 displays "F" associated with detection of selection on the password display image, as shown in FIG.

[13-4. Examples of other arrangements of the touch panel]
In the above-described embodiment, the main screen 210a and the sub-screen 220a are provided, and a touch input unit (touch panel) using a touch sensor module is arranged so that a touch operation can be performed on the sub-screen 220a. However, the arrangement of the touch input unit (touch panel) is not limited to this. For example, a touch input unit (touch panel) may be arranged in an area corresponding to the main screen 210a so that touch operations can be performed not only on the sub-screen 220a but also on the main screen 210a. In this case, since various input operations can be performed in an area wider than the sub-screen 220a, the touch input section (touch panel) may not be arranged in the area corresponding to the sub-screen 220a. In other words, the main display device 210 may be configured so that the touch operation can be input over the entire area where the normal effect is displayed.

An example in which a touch input unit (touch panel) using a touch sensor module is arranged in a region corresponding to the main screen 210a will be described below with reference to FIGS. 186 to 189. FIG.

186 and 187 are diagrams showing the password display image (password input area 116) and the password input menu screen (keyboard display area 117) displayed on the main screen 210a in this example. 187 shows a state in which all passwords have been entered, and FIG. 187 shows a state in which part of the password has not been entered.

As shown in FIG. 186, characters entered as a password are displayed on the main screen 210a, a password entry area 116 that can be touch-operated, and various characters and symbols to be entered in the password entry area. A keyboard display area 117 that can be designated by a touch operation and an intention operation input area 118 that allows the player to input various intention operations are displayed.

The password input area 116 allows input of 12 characters and symbols, and the number of characters (number of digits) of the password that can be input is constant regardless of the amount of information. The password input area 116 allows the password to be input sequentially from the left side to the right side, and an underline (bar) is displayed at each portion where the password is to be input. In the following description, the leftmost input point in the password input area 116 is PA1, the rightmost input point is PA2, the rightmost input point is PA3, . . . the rightmost input point is PA12. That is, the first character of the password is input to PA1, the second character of the password is input to PA2, the third character of the password is input to PA3, and the 12th character of the password is input to PA12. .

The number of characters (number of digits) of the password that can be entered in the password entry area 116 can be varied depending on the amount of information and the date and time of acquisition. Also, the characters and symbols used for the password are not limited to those shown in FIG. Alphanumeric characters and symbolic symbols representing characters can also be used. In other words, the object to be entered in the password entry area 116 may be some kind of identification information.

The keyboard display area 117 can display 32 characters and symbols, and the characters and symbols to be input to the password input area 116 can be displayed by the player touching the areas corresponding to these characters and symbols. They can be specified sequentially. Although not shown in FIGS. 186 and 187, when any character or symbol is specified in the keyboard display area 117, a ring (or an arrow (or a rectangular frame similar to that displayed in the password input area 116) is displayed, and it is possible to recognize which character or symbol has been specified. ing. However, it is also possible to recognize which character or symbol has been specified by changing the display mode of the corresponding portion of the specified character or symbol.

The display of this cursor is displayed on the main screen 210a or the sub-screen 220a, for example, and an operation to a movement selection operation button (not shown) for receiving a movement selection operation such as a cross key, or an effect button 10a and 10b, the areas PA1 to PA12 in the password input area 116, the areas corresponding to the characters and symbols in the keyboard display area 117, and the input areas in the intentional operation input area 118 are displayed one by one. Move point by point. Here, when the cursor is moved within the password input area 116, the moved portion becomes active. In addition, in the keyboard display area 117 and the intentional operation input area 118, the cursor is displayed on the main screen 210a or the sub screen 220a, for example, with the cursor aligned with the various areas (buttons) to which it has been moved, and When a decision button (not shown) for accepting an operation is operated, or the production buttons 10a and 10b are operated, the corresponding characters and symbols are input to the password display area 116, and various types of characters described later are entered. Intentional manipulation is performed. That is, in this example, each area in the password input area 116 can be activated without touch operation, characters and symbols in the keyboard display area 117 can be designated and input, and intentional operation can be performed. A button in the input area 118 can be specified/determined.

However, since the cursor is basically moved one place at a time in the operation of the movement selection operation button and the effect buttons 10a and 10b, for example, "A" in the keyboard display area 117 If you want to specify the area corresponding to the character "H" in the keyboard display area 117 while the cursor is on the area corresponding to the character "H", it is necessary to perform seven horizontal operations. . For example, when the cursor is placed on the area corresponding to the letter "A" in the keyboard display area 117, if you want to specify the area in the password input area 116, execute the vertical operation once. In this case, it is uniformly moved to the place where the next character or symbol is entered (that is, the first place) in the non-input area. Further, for example, when the cursor is placed in any area within the password input area 116, if the area within the keyboard display area 117 is desired to be specified, the cursor can be moved by performing one vertical operation. However, in this case, it is uniformly moved to the area corresponding to the letter “A” in the keyboard display area 117 . Note that these are examples of the regularity of cursor movement when touch operations are not used.

The intention operation input area 118 is a release operation input area (FIGS. 186 and 187, where "return" is displayed) and a delete operation input area (where "delete one character" is displayed in Figs. , and a decision operation input area (where “OK” is displayed in FIGS. 186 and 187) in which a decision operation for confirming the executed operation (for example, confirming the entered password) can be entered.

Here, in the determination operation input area, when any character or symbol is not input in all of PA1 to PA12 in the password input area 116 (that is, when part of the password is not input), Operation input is not possible (see FIG. 187, where the display of "OK" is reversed in black and white with respect to the display in FIG. 186), and all of PA1 to PA12 in password input area When the or symbol is entered (that is, when all the passwords are entered), the decision operation can be entered (see the display location of "OK" in FIG. 186) .

As a result, for example, when the player forgets one character to be input, the player can immediately recognize that there is an error in the input contents of the password, and the player is confused. It is possible to prevent unnecessary time from being wasted, and improve the convenience of password input.

Although not shown in FIGS. 186 and 187, the deletion operation input area is an area (input area) in which any character or symbol has already been input in PA1 to PA12 in the password input area 116. Only when the final area (that is, the rightmost area) is selected, the delete operation can be input, and in other cases, the delete operation cannot be input. .

Also, although not shown in FIGS. 186 and 187, when characters are input in any of PA1 to PA12 of the password input area 116, the player does not respond for a predetermined period (for example, 40 seconds). Even if the demonstration screen (standby screen) is displayed on the main display device 210 because no operation is performed, the input contents are held at least until the next game start operation is performed. It has become. Further, even if the guide menu screen returns to the previous state due to the release operation being performed on the above release operation input area, at least until the next game start operation is performed, The input content is retained. That is, even when the display of the password display image is interrupted, the input contents are held until the next game is started.

Also, although not shown in FIGS. 186 and 187, when characters are input in any of PA1 to PA12 of the password input area 116, the main display is caused by operating the checkout button (not shown). Even if the demonstration screen (standby screen) is immediately displayed on the device 210, the input contents are held at least until the next game start operation is performed. That is, even when the display of the password display image is forcibly ended, the input contents are held until the next game is started.

In FIGS. 186 and 187, the password input area 116 in which a password is input is described as an example of an area (character input area) in which characters are input. The columns are not limited to passwords for presentations. For example, it may be a character input area (character input area 116) that is displayed when various types of information (for example, the name of the amusement arcade entered by the store clerk of the amusement arcade, etc.) are entered in the hall menu described above. Also, at this time, the keyboard display area 117 and the intention operation input area 118 are similarly displayed, and the same control as the various display controls in the password input area 116 described above or later is performed. good. In other words, the fifth game machine (pachi-slot machine) is applicable to all forms in which identification information related to predetermined information can be input to the game machine.

188, 189 and 190 are enlarged views of the password display image (password input area 116) displayed on the main screen 210a in this example, and are diagrams for explaining the transition of the display mode.

First, with reference to FIG. 188, the transition of the display mode when the player sequentially inputs the password in the password input area 116 will be described. In FIG. 188, “A” is input to PA1, “B” to PA2, “C” to PA3, “D” to PA4, “E” to PA5, and “F” to PA6 in password input area 116 . , and PA7 to PA12 show a state in which no characters or symbols are input. In the present embodiment, in the password input area 116, the areas in which the password has already been entered (that is, PA1 to PA6) will be explained as input areas, and the areas in which the password has not yet been entered (that is, PA7 to PA12) will be explained. It may be described as a non-input area.

Here, the underline (bar) display of the portion where the next character or symbol is to be input (that is, the first portion) in the non-input area is displayed differently from the display of the underline (bar) in other portions. It has become. For example, as shown in FIG. 188, the underline (bar) display at the top of the non-input area is displayed in white, and the underline (bar) at the input area and non-input area other than the top is displayed. The display is displayed in black. Note that this is just an example, and the underline (bar) display at the top of the non-input area is lit (or blinking), and the underline (bar) at the input area and non-input area other than the top is displayed. The display can also be turned off (or only turned on instead of blinking). In other words, by differentiating the display mode of the leading portion of the non-input area from the display mode of the input and non-input regions other than the leading portion, the leading portion of the non-input region can be easily recognized. All aspects can be adopted.

Note that the upper part of FIG. 188 shows, for example, the state immediately after the character "F" is input to PA6 of the password input area 116. In this case, the player finally performed the touch operation (or the above operation ) is the area corresponding to "F" in the keyboard display area 117, so the cursor is moved to the area corresponding to "F" in the keyboard display area 117. FIG. That is, in the upper part of FIG. 188, although PA7 of password input area 116 is shown to be the top of the non-input area in the above-described display mode, PA7 of password input area 116 immediately becomes a character or This indicates that the symbol is not ready to be input (that is, it is not in an active state).

However, as will be described later, as long as characters and symbols are sequentially input in the password input area 116 without performing an operation to change the characters and symbols in the input area, characters and symbols are automatically input. may be controlled so that the leading portion of the non-input area is in an active state.

In contrast to the upper part of FIG. 188, the lower part of FIG. 188 shows that PA7 of the password input area 116 is the top of the non-input areas and is in an active state. At this time, in PA7 of the password input area 116, a white underline (bar) is displayed and a white frame line is displayed. It should be noted that this white frame display is the above-described cursor and also indicates that the corresponding portion is in an active state. That is, when a character or symbol can be entered at the beginning of the non-input area, not only is the beginning of the non-input area indicated, but also the character or symbol is displayed in a different display mode. is ready for input. Also in this case, various modes can be adopted for the display mode indicating the state in which characters and symbols can be input.

That is, in this example, while indicating the leading area in the non-input area, the display mode is changed depending on whether or not the character or symbol can be input immediately. As a result, the input state of the password can be displayed in an easy-to-understand manner for the player, and the convenience of password input can be improved.

In this example, in order to enter a state in which characters and symbols can be entered (that is, in an active state) at the beginning of the non-input region of the password input region 116, the non-input region in the password input region 116 , the touch operation may be performed on any one of the regions. Specifically, as shown in FIGS. 187 and 188, PA1 to PA6 in the password input area 116 are input areas, and PA7 to PA12 in the password input area 116 are uninput areas. In order to make PA7, which is the head, into an active state (that is, a valid state), by touching not only PA7 but also any area of PA8 to PA12, PA7 becomes a state in which characters and symbols can be input. It is supposed to be controlled.

Therefore, when the player tries to continue inputting the password in the middle of inputting, the player must deliberately move the cursor to the beginning of the non-input area, or perform a strict touch operation on the beginning of the non-input area. Input can be resumed immediately by touching an uninput area without performing a touch operation.

As a result, it is possible to make it difficult for the player to feel troublesome when inputting the password, and it is possible to improve the convenience of inputting the password.

Next, with reference to FIGS. 189 and 190, transition of the display mode when the player performs an operation to change the characters or symbols in the input area in the password input area 116 will be described.

In this example, when a character or symbol in the input area of the password input area 116 is desired to be changed, a touch operation is performed on the corresponding area of the password input area 116 in which the character or symbol to be changed is input. After being specified, characters and symbols to be input in this corresponding area can be specified by touching the keyboard display area 117 . Specifically, as shown in FIG. 189, when the character “C” entered in PA3 in the password input area 116 is to be changed, if the area corresponding to PA3 in the entered area is touched, a new character is entered in PA3. and symbols can be entered. On the other hand, when the cursor is moved by the above-described operation to change the character, the operation in each direction is required to move the cursor to the corresponding area.

The underline (bar) display and frame line display are basically the same as those shown in FIG. In this case, when PA3) is touched, a white underline (bar) display indicates the changed portion, and a white frame line (cursor) display indicates that characters and symbols can be input. . However, the white underline (bar) display indicating the part to be entered does not move from the part PA7 in the password input area 116 as it only indicates the part to be the beginning of the non-input area, and the part PA3 Only the outline frame (cursor) display may be displayed.

However, when it is desired to change the characters or symbols in the input area of the password input area 116, and the touch operation is performed on an area that does not correspond to the corresponding area of the password input area 116, the cursor does not move. It's like Specifically, for example, as shown in FIG. 190, it corresponds to the space (S1) to the left of PA1 in the password input area 116 and the spaces (S2 to S5 . . . ) between PAs in the input area. When a touch operation is performed on an area, the cursor does not move and none of the input areas becomes active.

The player may not perform a strict touch operation. For example, the player wants to change the characters or symbols input in the input area PA3, and touches the periphery of the area corresponding to PA3 in the input area. In this case, a touch operation may be performed between PA2 and PA3 (S3) or between PA3 and PA4 (S4). At this time, the gaming machine side cannot determine whether the player wants to change the characters and symbols input to PA3 or to change the characters and symbols input to PA2 or PA4. If the determination is made arbitrarily, PA2 or PA4 in the input area may be erroneously activated, which may be a factor of erroneous input. Therefore, when a touch operation is performed on an area (eg, S1 to S5 in FIG. 190) that does not correspond to the corresponding area (eg, PA1 to PA5 in FIG. 190) of the password input area 116, the cursor is moved. It does not move and does not make any area in the input area active.

Among S1 to S5 in the input area, since there is a high possibility that the player wants to change the characters and symbols input in the input area PA1, S1 When a touch operation is performed, the cursor may be moved to PA1 and PA1 may be brought into an active state. That is, if there is no area corresponding to the corresponding area of the password input area 116 between the areas corresponding to the corresponding area of the password input area 116, the cursor is moved to the area corresponding to the corresponding area of the adjacent password input area 116. may be moved.

In addition, among S1 to S5 in the input area, for S5 where the interval between PAs is wider than other areas, further, an area belonging to PA4, an area belonging to PA5, and an area belonging to neither PA4 nor PA5 When the touch operation is performed on the area belonging to PA4, the cursor is moved to PA4, PA4 is made active, and the touch operation is performed on the area belonging to PA5. In this case, the cursor is moved to PA5, PA5 is made active, and when a touch operation is performed on an area that does not belong to PA4 or PA5, the cursor is not moved, and PA4 and PA5 are moved. may be set to be in an active state.

In this way, when the player wants to change the characters or symbols of the password that he or she has entered, he/she can immediately enter the password by simply touching the place where the characters or symbols to be changed are displayed and re-entering the characters or symbols. You can change the content.

As a result, for example, when it is necessary to change the input content, such as when there is an error in the input content of the password, it is possible to devise ways to make it difficult for the player to feel annoyed. Convenience can be improved.

Also, in the input area, if the player performs a touch operation on an area that does not correspond to the area where characters or symbols are input, the cursor does not move. It is possible to prevent an unintentional area from being designated, thereby preventing erroneous input and improving the convenience of password input.

In this example, in the input area of the password input area 116, the area to be operated by the player (for example, PA1 to PA5) and the area not to be operated by the player between the areas (for example, , S1 to S5) are provided, and when a touch operation is performed on an area that is not to be operated by the player, for example, by not moving the cursor, control based on the touch operation can be performed. Although not performed, control based on such rules may be performed when various input operations, selection operations, or decision operations are performed. For example, in the keyboard display area 117, a player touches an area (between characters, etc.) that is not an operation target for the player, and is located between corresponding areas for selecting characters or symbols to be an operation target for the player. When the operation is performed, it is possible to prevent the cursor from moving and the selection of any character or the like.

The same applies to the character customization screen, which will be described later with reference to FIG. 191 . When a touch operation is performed on an area that is not to be operated (between options), it is possible to prevent the player's operation from being reflected.

[13-5. Data accumulation by using the mobile terminal linkage function]
Next, with reference to FIGS. 191 to 193, an example of data accumulation by using the above-described portable terminal cooperation function in the fifth game machine (pachi-slot machine) will be described. FIG. 191 is a diagram showing an example of a character customization screen in the fifth gaming machine (pachi-slot machine), and FIG. 192 is a diagram for explaining various data relating to character customization in the fifth gaming machine (pachi-slot machine). FIG. 193 is a diagram for explaining an overview of data transfer between the fifth gaming machine (pachi-slot machine) and the server 200. In FIG.

As described above, in the fifth gaming machine (pachi-slot machine) of the present embodiment, by using the mobile terminal cooperation function, the player uses his/her mobile terminal to operate the fifth gaming machine (pachi-slot machine). ) to save game information related to the results of the game so far, game information appropriately provided according to the progress of the game, and the results of the player's selection operation It is possible to accumulate various game information (various data) such as information. A method of accumulating various game information (various types of data) in cooperation with the server 300, which will be described later, will be described later with reference to FIG.

First, when the above Unimemo menu items (see FIG. 182) are displayed on the main screen 210a or the sub-screen 220a, for example, the item "customize" is also displayed, and this "customize" menu is selected. Then, a character customization screen as shown in FIG. 191 is displayed.

As shown in FIG. 191, the character customization screen displays character selection buttons (“A” to “D” in the “character” frame in FIG. 191) for selecting a character, and the character can be selected. When pressed, an image showing the selected character is displayed on the left side of the screen.

Further, below the character selection buttons, there are costume selection buttons (“A” to “D” in the frame of “Costume” in FIG. 191) for selecting the displayed costume of the selected character. Displayed below the costume selection buttons are item selection buttons ("A" to "H" in the "Item" frame in FIG. 191) for selecting the displayed property (item) of the selected character. ) is displayed.

In the fifth gaming machine (pachi-slot machine) of the present embodiment, when a character is selected and a costume and an item are selected on the customization screen, the customized character is used for production. there is The selected character type, the selected costume type, and the selected item type can be accumulated as one piece of game information for saving the result of the player's selection operation. Therefore, once the player customizes the character, the player can restore the customized character by simply logging in.

In addition, among the selectable characters, pachislots between different models that use the same or similar motifs and storylines but have different specifications (for example, one model is the above-mentioned pachislot 1a and the other model is In some cases, both common characters commonly used in pachislot 1b described above and specific characters uniquely used in pachislot machines of different models may be included.

In addition, among the costumes that can be selected, there are common costumes (for common characters) that are commonly used in pachislot machines between the different models mentioned above, and pachislot machines between the different machines mentioned above, for customizing the display of common characters. May contain unique costumes (for common characters) that are uniquely used in each. In addition, in order to customize the display of unique characters, there are common costumes (for unique characters) that are commonly used in pachislot machines between different models mentioned above, and unique costumes (for unique characters) that are uniquely used in pachislot machines between different models mentioned above ( for unique characters) may be included.

In addition, among the selectable items, there are common items (for common characters) that are commonly used in pachislot machines of different models described above, and pachislot machines between different models described above, for customizing the display of common characters. May contain unique items (for common characters) that are uniquely used for each. In addition, for customizing the display of unique characters, common items (for unique characters) that are commonly used in pachislot machines between different models mentioned above and unique items (for unique characters) that are uniquely used in pachislot machines between different models mentioned above ( for unique characters) may be included.

In addition, some of the costumes and items that can be selected cannot be selected at first, but can be newly selected when the predetermined unlock conditions can be satisfied according to the progress of the game for each model. It may include what is possible. In this way, the types of costumes and items newly selectable in response to the fulfillment of the release condition can be accumulated as one piece of game information that is appropriately provided according to the progress of the game. Therefore, once the player makes the costume or item selectable, the player can restore the costume or item selectable state simply by logging in. It should be noted that the characters may also include characters that are newly selectable when a predetermined release condition can be established according to the progress of the game for each model.

In addition, various conditions can be defined as conditions for providing various game information as release conditions (conditions for providing game information) according to the progress of the game. For example, the number of times the mobile terminal cooperation function has been used (the number of logins) has reached 1, 3, and 5 times, the cumulative number of games played has reached 1,000, 3,000, and 5,000 times, and a bonus Cumulative number of transitions to game state is 10 times, 30 times, 50 times, Cumulative number of transitions to BB game state is 10 times, 30 times, 50 times, MB game state 10 times, 30 times, and 50 times, and the bonus combination was won independently (for example, any of the winning numbers "1", "9" and "18" Winning), specific performance (for example, special performance) is performed, etc., one provision condition is associated with one piece of game information, and when the provision condition is satisfied, the corresponding game information is accumulated. You can do so.

Next, with reference to FIG. 192, as an example of game information appropriately provided in accordance with the progress of a game, various data relating to customization of a character will be cited, and differences and similarities in the configuration of the various data among a plurality of different models will be described. . Also in FIG. 192, one model is the pachi-slot 1a described above, and the other model is the pachi-slot 1b described above.

As shown in FIG. 192, in pachislot 1a, data corresponding to "character A" and "character B" are data indicating common characters, and data corresponding to "character E" and "character F" are data indicating unique characters. Corresponding data is defined as game information.

In the pachi-slot 1a, as data indicating common costumes (for common characters), "for character A: A" to "for character A: C" and "for character B: A" to "for character B: C". Data corresponding to , as data indicating unique costumes (for common characters), data corresponding to "for character A: E" and "for character B: E", as data indicating unique costumes (for unique characters), " For character E: A" to "for character E: C", "for character E: E", "for character F: A" to "for character F: C", and "for character F: E" Data is defined as game information. For example, the data corresponding to "for character E: A" to "for character E: C" can be used as data indicating common costumes (for unique characters). Moreover, each of the open conditions a to h can be set arbitrarily.

In addition, in the pachislot 1a, data corresponding to "item A" to "item D", data corresponding to "item A" to "item D", data indicating common items (for common characters) and/or common items (for unique characters), unique items (for common characters) And/or data corresponding to "item I" to "item L" are defined as game information as data indicating unique items (for unique characters). It should be noted that each of the open conditions 1 to 8 can be arbitrarily set.

On the other hand, as shown in FIG. 192, in pachislot 1b, data corresponding to "character A" and "character B" are data representing common characters, and data representing unique characters are "character C" and "character D". ” is defined as game information.

In addition, in pachislot 1b, as data indicating common costumes (for common characters), "for character A: A" to "for character A: C" and "for character B: A" to "for character B: C" Data corresponding to , as data indicating unique costumes (for common characters), data corresponding to "for character A: D" and "for character B: D", data indicating unique costumes (for unique characters), " Data corresponding to "for character C: A" to "for character C: D" and "for character D: A" to "for character D: D" are defined as game information. For example, the data corresponding to "for character C: A" to "for character C: C" may be data indicating a common costume (for unique character). It should be noted that each of the open conditions a to h can be set arbitrarily.

In the pachi-slot machine 1b, data corresponding to "item A" to "item D", data indicating common items (for common characters) and/or common items (for unique characters), unique items (for common characters) And/or data corresponding to "item E" to "item H" are defined as game information as data indicating unique items (for unique characters). It should be noted that open conditions 1, 2, 5 to 10 can each be set as desired.

Here, data corresponding to "for character A: A" to "for character A: C", "for character B: A" to "for character B: C", and "item A" to "item D" are , If either one of Pachi-slot 1a and Pachi-slot 1b satisfies the opening condition, even if the other does not satisfy the opening condition, the other Pachi-slot is deemed to have satisfied the opening condition, and the game information is updated. are stored.

In addition, the opening conditions of "for character A: A" to "for character A: C" in pachi-slot 1a and the opening conditions of "for character A: A" to "for character A: C" in pachi-slot 1b, and "for character A: C" in pachi-slot 1a For character B: A" to "for character B: C" opening conditions and for pachislot 1b "for character B: A" to "for character B: C" opening conditions, "item C" and "item for pachislot 1a D" and the opening conditions of "Item C" and "Item D" in Pachi-Slot 1b are different conditions. That is, the common data shown in FIG. 192 can set different opening conditions.
Of course, the individual data shown in FIG. 192 can also set different opening conditions.

In this case, for example, as conditions for unlocking the specific common data, the number of logins is set to "1" for the model described as pachislot 1a, and the number of logins is set to "5" for the model described as pachislot 1b. Of the same type of unlocking conditions, it is possible to set unlocking conditions that specify different degrees of achievement. It is also possible to set different types of release conditions, such as setting the cumulative number of games played to "1000".

Note that the common data and the individual data are not limited to data for customizing characters as described above. For example, the cumulative number of games played (game count) is common data, the number of logins is individual data, the cumulative number of games played (game count), which is common data, is a certain value or more, and individual data If a certain number of logins is equal to or greater than a certain value in each of the model explained as pachi-slot 1a and the model explained as pachi-slot 1b, various effects, such as image effects (displaying images on the liquid crystal display device 11 production by displaying), audio production (production by outputting production sound from speakers 35a and 35b), lamp production (production by lighting the upper lamp 23 and reel lamps, etc.), role production (by role A part of the production such as production) may be performed differently from usual. Specifically, the display mode of the frame display on the display screen of the display devices 210 and 220 (for example, the main screen 210a) may be changed, or the lighting mode of the upper lamp 23 may be changed. In addition to changing the effect mode during execution of such a normal effect, for example, the display mode of the menu screen in the guide menu screen described above may be changed. These are also examples, and all aspects of changing effects in accordance with various types of common data and individual data are applicable to this embodiment.

In this way, in the fifth gaming machine (pachislot machine) capable of exchanging data corresponding to game information corresponding to the game status of each player with the server 300 described later, the server 300 described later can accumulate the data. The game information includes, for example, unique information (for example, individual data shown in FIG. 192) that is unique to each model of the model described as pachi-slot 1a or the model described as pachi-slot 1b, and the information described as pachi-slot 1a. Common information (for example, common data shown in FIG. 192) that is common information between the model and the model described as the pachi-slot 1b can be included.

As a result, for example, when these models are installed at the game arcade at the same time, the player can change the model for playing the game while enjoying the accumulation of the game information, which makes the game itself boring. It is possible to further improve interest in the accumulated game information. In addition, for example, if these models are installed at different times in amusement arcades, the game information accumulated in the model installed first will not be wasted, and will continue to be used in the models installed later. Since the game information can be accumulated by the game information, the interest in the accumulated game information can be further enhanced, and the brand power of the game machine having such relevance can be enhanced.

In addition, in the fifth gaming machine (pachi-slot machine) of the present embodiment, the common information includes a character used in the performance performed in the model described as pachi-slot 1a and a character used in the performance performed in the model described as pachi-slot 1b. Character-related information related to the commonly used character can be included between the characters to be used, and the character-related information can be used to change the display mode of the character. As a result, it is possible to change the contents of the presentation depending on the outcome of the game across a plurality of models, so that the interest in the accumulated game information can be further enhanced.

In addition, in the fifth gaming machine (pachi-slot machine) of the present embodiment, the conditions for accumulating the specific information of the common information in the server 300 described later are the model described as the pachi-slot 1a and the model described as the pachi-slot 1b. It is possible to set different conditions between As a result, it is possible not only to standardize the accumulated game information, but also to change the accumulated conditions, thereby further enhancing interest in the accumulated game information.

In FIG. 192, as an example of common data and individual data, data related to character customization is described as an example, but common data and individual data are not limited to this. For example, if the release condition is related to the cumulative number of times the game has been played, the game information is used as common data, and if the release condition is related to the cumulative number of times the game is shifted to the bonus game state, the game information is used as individual data. You can also That is, all game information that can be shared between one model of gaming machine and another model of gaming machine can be applied as common data.

Next, with reference to FIG. 193, transfer of data between the fifth gaming machine (pachi-slot machine) and server 300 will be described. Although illustration is omitted, the server 300 includes, for example, a WEB server that controls communication with a mobile terminal of a player, a player management server that manages player information, and data corresponding to game information for each model. It consists of a data management server, etc.

First, when the player wants to restore the game information saved at the end of the previous game (that is, when he/she wants to continue playing the game from the continuation of the previous game with respect to the accumulated game information), the player opens the browser, application, etc. of his/her mobile terminal. to access the server 300 (player access).

At this time, the server 300 authenticates the player by means of the identification information obtained at the time of access, issues a password for restoring the game information, and the password is displayed on the display screen of the player's mobile terminal. Data to be displayed is sent to the player's mobile terminal. The password is an example of restoration information for restoring the accumulated game information in the fifth gaming machine (pachi-slot machine). In other words, if the information can be input or read on the fifth gaming machine (pachi-slot machine) side, it is possible to send other information as the restoration information.

The player inputs the password sent from the server 300 and displayed on his/her own mobile terminal in the password display image (password input area 116) described above (with password input). As a result, in the fifth gaming machine (pachi-slot machine), the player's login is completed, and the game information is restored to the data at the time of the previous termination according to the data indicated by the input password.

On the other hand, if the player is playing for the first time on that model (including other models for which common data is set), or if the player wishes to start accumulating game information for the first time, the password is not input (no password is input), and a new login is performed based on the player's touch operation on the above Unimemo menu item "Record" or the like.
It should be noted that if no operation is performed, the user is not logged in and the game information is not updated.

After the game information is restored and logged in based on the input of the password, or after a new login, when the game is started (game start), the game information is appropriately changed according to the result of the game. (including common data, individual data, other game result data, etc.) are updated and stored. It should be noted that the game information updated here may include not only specific information that can be restored by entering a password, but also general information that simply indicates the result of the game.

After that, when the game is over (game over), the player is logged out based on the player's touch operation such as the item "record and end" of the Unimemo menu. In the main display device 210 or the sub display device 220, two devices for storing game information (that is, for accumulating game information recorded on the fifth gaming machine (pachislot machine) side in the server 300) are provided. A dimension code is displayed.

The player reads the two-dimensional code displayed on the main display device 210 or the sub-display device 220 with his mobile terminal, and based on the data contained in the read two-dimensional code, the browser of his mobile terminal or the An application or the like is used to access the server 300 (player access based on the two-dimensional code). Note that what is displayed on the main display device 210 or the sub display device 220 may be, for example, a URL or a password. That is, any information that allows access to the server 300 may be used.

At this time, the server 300 appropriately stores game information (common data, individual data, and other game result data) based on data indicating game information stored on the fifth gaming machine (pachislot machine) side acquired when accessed. etc.) are updated and accumulated. Note that the game information accumulated here may be only specific information that can be restored by the transmitted password.

When the game information to be updated and accumulated includes common data, the server 300 also updates and accumulates the game information of other models whose game information can be updated by the common data.

An end button for ending the display of the two-dimensional code is displayed on the screen on which the two-dimensional code is displayed. When the end button is selected, a confirmation message "Cannot be displayed again, but are you sure you want to end?" is displayed near the two-dimensional code or the end button. As a result, it is possible to prevent the display of the two-dimensional code from ending due to an erroneous operation. The confirmation that the two-dimensional code cannot be redisplayed is not limited to text, and may be output, for example, by voice, or both voice and text may be output.

In this embodiment, data is transferred between the fifth gaming machine (pachi-slot machine) and the server 300 by intermediating the mobile terminal of the player between the fifth gaming machine (pachi-slot machine) and the server 300. However, the configuration that enables the transfer of data between the fifth game machine (pachi-slot machine) and the server 300 is not limited to this. For example, when the fifth gaming machine (pachi-slot machine) is capable of direct data communication with the server 300, the data relating to the game information is directly transferred without the intermediary of the mobile terminal of the player. It may be configured as Further, for example, a fifth gaming machine (pachi-slot machine) cannot communicate data with the server 300, but another gaming device (for example, a gaming display device capable of displaying various information related to the game, or By making it possible to transfer data corresponding to game media owned by a player to and from a fifth gaming machine (pachi-slot machine), the fifth gaming machine (pachi-slot machine) can input physical game media and If data communication is possible with a game media management device capable of electromagnetically managing game media without paying out, the fifth game device can be used as an intermediary. Data may be transferred between the gaming machine (pachi-slot machine) and the server 300 . In short, the form that enables data transfer between the fifth gaming machine (pachi-slot machine) and the server 300 includes not only direct data transfer but also indirect data transfer (i.e., other device All forms of passing data are applicable.

That is, as a gaming system including a gaming machine (e.g., fifth gaming machine (pachislot machine)) and a server device (e.g., server 300), the gaming machine (e.g., fifth gaming machine (pachislot machine)) and It can be a gaming system configured with a server device (for example, server 300), or a game machine (for example, a fifth gaming machine (pachislot machine)), a server device (for example, server 300), and players It can be a gaming system configured with a mobile terminal, or it can be configured with a gaming machine (for example, a fifth gaming machine (pachi-slot machine)), a server device (for example, server 300), and other gaming devices. It can also be considered as a game system. That is, in this embodiment, the invention as a game system can also be configured.

Note that this embodiment employs OFF edge execution in which the sub CPU 201 detects an input when the operator's finger leaves the touch input unit. However, as the fifth game machine, it is possible to employ ON edge execution in which the sub CPU 201 detects an input when the operator's finger touches the touch input unit.

[13-6. Other Configurations of the Fifth Gaming Machine]
(accumulation of staging environment)
In the fifth game machine (pachi-slot machine), the player can set the production environment. As the production environment, for example, the volume output from the speakers 35a and 35b, the amount of light emitted from the lamps such as the upper lamp 23 (light quantity), the type of language to be displayed on the display devices 210 and 220 (for example, Japanese Japanese, English, Korean), format of the language to be displayed on the display devices 210 and 220 (for example, Mincho, Gothic), and the like. The setting information of the effect environment is included in the game information accumulated in the server 300 when Unimemo is logged out.

For example, when a plurality of categorized volume levels are set, setting information for each categorized volume level is accumulated as game information. Then, when Unimemo is logged in to the fifth gaming machine (pachislot machine) next time, the password for acquiring the game information containing the accumulated setting information for the volume for each category is publish. As a result, when logging in to Unimemo, the volume settings for each category are reflected when the game was played last time. As a result, the next time Unimemo is logged in, there is no need to set the volume by category again to a desired value, and the volume by category can be easily set to the desired volume. Convenience can be enhanced with respect to the setting of the performance environment when starting the game. That is, by reading the two-dimensional code, setting information of the production environment is stored in the server 300, and by issuing a password when playing the next game, the setting information of the production environment can be reproduced on the gaming machine where the game is played. becomes. As a result, it is possible to easily set the effect environment that the player likes, and it is possible to enhance the convenience of the player with respect to the setting of the effect environment.

As described above, the game information accumulated in the server 300 includes the details of effects that can be set by the player. The contents of the production include, for example, selection of a character to be displayed on the display devices 210 and 220, selection of the displayed costume of the selected character, selection of the displayed item of the selected character, Examples include so-called character custom, voice selection for performing push-order navigation, and the like. In addition, the contents of the production include production frequency customization, which is the frequency at which a specific production is performed, and benefits that are advantageous to the player (bonus on pachislot machines, AT wins, additional games on ATs, jackpots on pachinko machines, etc.) ) can also be cited as reliability custom, which is the reliability of the performance expected to be given. Hereinafter, the contents of such effects are referred to as "custom effects". Setting the contents of such an effect can be said to be "setting of the contents of the effect".

The effect custom may be settable not only in a state of being logged in to Unimemo (login state) but also in a state of not being logged in to Unimemo (non-login state). As a result, the player can enjoy the performance with a favorite character or costume without performing a login operation. However, setting information for custom effects such as favorite characters and costumes is not stored in the server 300 . Note that the effect environment can be set regardless of whether the player is logged in or not logged in, as described in the volume setting by the player.

(Performance custom and production environment setting by mobile terminal)
The setting of the production custom and the production environment accumulated in the server 300 can be confirmed and set from the application of the portable terminal. As a result, it is possible to set a desired effect customization and effect environment in advance using the portable terminal. When logging in to Unimemo in the fifth game machine (pachislot machine), a password is issued for acquiring game information including information on the effect customization and effect environment set by the application of the portable terminal. Then, when a password is entered to log in to Unimemo, a game can be played on a gaming machine in which the effect customization and effect environment set by the application are reflected.

(Initialization of production custom and production environment)
The gaming machine according to the present embodiment displays a demonstration screen (standby screen) when settlement processing for settlement of game values (for example, medals) is executed. note that. The display of the demonstration screen (standby screen) corresponds to the "demonstration effect" according to the present invention. As a result, the standby screen is displayed immediately after the settlement process is performed, so that the player who is looking for a table in the store can easily understand whether the table is vacant or not. As a result, the operation can be promoted, and convenience for the player can be enhanced in setting the performance environment. In addition, when the standby screen is displayed after the execution of the settlement process, the BGM is not output from the speaker, or the volume of the BGM output from the speaker is suppressed (for example, the volume is lower than the initial setting). . As a result, the environment of the entire hall can be made quiet. A sound corresponding to some kind of operation such as button operation is output.
In the fifth gaming machine (pachislot machine), when the value of the credit counter is 0 (zero) and the demonstration screen (standby screen) is displayed on the main display device 210, the effect custom and effect Restore the environment to the initial settings (default settings). When the value of the credit counter is 0 (zero), there is a high possibility that the game has ended and the balance has been settled. Therefore, the production custom and production environment are immediately returned to the initial settings (default settings). As a result, even if the previous player has set the sound volume to an extremely high volume, it is possible to prevent the players playing after that from feeling uncomfortable when hearing the high sound volume. That is, when the settlement process is executed, the effect customization and the effect environment are returned to the initial settings, so that the next player can comfortably play the game.
If the value of the credit counter is not 0 (zero), the standby screen is displayed when the period during which the start switch 7S is not turned on reaches a predetermined period. Also, the settlement process can be executed when the start switch 7S is not turned ON. Therefore, when the settlement process is executed and the standby screen is displayed, the start switch 7S is not turned ON.
In addition, in the fifth game machine (pachi-slot machine), the effect environment after power failure recovery is returned to the initial setting (default setting). In addition, if there is no game operation (bet, lever on, stop operation, medal insertion, payment button press, etc.) or operation of the production button / touch panel for a certain period of time (for example, 3 minutes), the standby screen will be displayed. It may be displayed. This timer starts timing at the end of the game (at the time when the stop button is turned off for the final stop operation, when the reels are stopped, at the end of the payout, or at the end of the freeze at the end of one game). Also, if any operation is performed during time measurement, the time value of the timer is initialized and time measurement is restarted. For example, when an operation controlled by the sub-control circuit is performed, the time value of the timer is not initialized, and when an operation controlled by the main control circuit is performed, the time value of the timer is initialized. good too. It should be noted that timing may be restarted only when the demo shift condition is satisfied. For example, if the specifications do not shift to the standby screen after a bet is made, the timer may not start timing when a bet operation is performed and one or more medals are betted.

On the other hand, the fifth gaming machine (pachislot machine) that is logged in to Unimemo (in a logged-in state) is set so that the production custom and production environment do not return to the initial settings. That is, while logged in to Unimemo, even if the value of the credit counter is 0 (zero) and the demonstration screen (standby screen) is displayed on the main display device 210, the set production custom and the staging environment is maintained. As a result, it is possible to prevent the performance custom and the performance environment from returning to the initial setting at unintended timing, and reduce situations where the performance custom and the performance environment need to be redone. It would be inconvenient if, while logged in to Unimemo, the user leaves the seat for a short period of time to go to the bathroom or take a smoking break, etc., and the performance environment such as the volume returns to the initial settings. When the player is logged in to Unimemo, it is often the case that the player intends to continue playing the game. Therefore, by maintaining the setting of the production environment while logging in to Unimemo, it is possible to save the trouble of setting the production environment to the desired one again. In addition, in the fifth game machine (pachi-slot machine), when Unimemo logs out or power is cut off, the effect customization and the effect environment are returned to the initial settings. Note that in the fifth gaming machine (pachislot machine) that is logged in to Unimemo (in a logged-in state), when the settings are changed, the effect customization and the effect environment are returned to the initial settings (default settings).

In addition, in the fifth gaming machine (pachi-slot machine) in which Unimemo is not logged in (non-login state), when the demonstration screen (standby screen) is displayed on the main display device 210, the effect customization and the effect environment are displayed. may be returned to the initial settings (default settings). That is, even if the value of the credit counter is not 0 (zero), when the demonstration screen (standby screen) is displayed on the main display device 210, the production custom and production environment are initialized (default setting). You can return it. In this case, even if a demonstration screen (standby screen) is displayed on the main display device 210 while logged in to Unimemo, the production custom and production environment are not returned to the initial settings.

In the gaming machine according to the present invention, the value of the credit counter indicating the number of game values accumulated in credits and the value of the bet number counter indicating the number of game values already betted are 0 during login to Unimemo. (zero) and the demonstration screen (standby screen) is displayed on the main display device 210, the production custom and production environment may be returned to the initial settings. In this case, even if the user quits the game without logging out of Unimemo, it is possible to increase the chances of returning the production customization and production environment to the initial settings, and the game can be played with the production customization and production environment set by others. can be suppressed from starting

(ON/OFF of volume setting by player)
As described above, the volume adjustment range is set in the hall side volume mode setting. In the fifth game machine (pachi-slot machine), in addition to setting the volume adjustment range, it is possible for the player to set ON/OFF of the volume setting. When the volume setting by the player is ON, it is possible for the player to set the above-described multiple category-specific volume levels and the like. On the other hand, when the volume setting by the player is OFF, the player cannot set the above-described volume levels for each category. In this case, even if a screen that allows the player to control the volume level is displayed, the color of the gauge corresponding to the volume level will be displayed in a different color (e.g. gray) than usual, making it impossible to operate. represents Also, by not displaying the gauge corresponding to the volume level, it may be indicated that the volume setting operation is impossible.
In addition, when the volume setting by the player is ON, a display suggesting/announcing that the volume can be adjusted, such as "You can adjust the volume with the volume adjustment key" or "You can adjust the volume with the touch panel." It is desirable to go and make it easier for the player to notice the volume control feature. The following variations are conceivable for the timing of these displays.
Timing 1: Predetermined timing during progress of the game For example, during the display of a normal effect in which a highly important effect such as a winning/losing notification effect is not performed.
Timing 2: Waiting for a game For example, the period from the end of one game to the betting of the next game or the operation of the start lever can be mentioned. In this case, it may be displayed immediately after the end of one game, or since it would be troublesome if this kind of explanation display were to appear frequently, the player's operation may be delayed for a predetermined period of time, such as about five seconds, after the end of one game. may be displayed when is not performed.
Timing 3: During execution of pseudo-game For example, during the production of stopping the reel fluctuation by the reel action using the acceleration before the constant speed rotation with the stop button, or during the temporary stop of the reel in the pseudo-game.
Timing 4: While the demo screen is being displayed For example, if the power saving mode is set while the demo screen is not being displayed, the standby screen (an image with low power consumption such as a black background image) is displayed without the demo video being displayed. It is desirable that the indication that the volume can be adjusted is displayed at least one of the four timings described above. These timings are merely examples, and the gaming machine according to the present embodiment may display that the volume can be adjusted at timings other than these timings.
Even at the four timings as described above, when the volume setting is invalid, the display suggesting/notifying that the volume adjustment is possible is not performed. As a result, it is possible to prevent suggesting/announcing that the volume can be adjusted when the volume cannot be set. That is, the display suggesting/informing that the volume can be adjusted is displayed when the volume setting is valid.
A fifth game machine (pachi-slot machine) may be configured so that the volume setting operation can be performed at any timing except during an error. In this case, at any one of the timing 1, the timing 2, the timing 3, and the timing 4, it is possible to perform a display suggesting/announcing that the volume can be adjusted.
As a fifth gaming machine (pachislot machine), when the reels are rotating (fluctuating in the case of pachinko), the volume setting operation may be disabled. In this case, the sound volume setting is validated when a game operation is awaited after all the reels have stopped or after a predetermined time has elapsed since the end of the game. In the case of the timing 1, if the reel is rotating, the display suggesting/announcing that the volume can be adjusted is not displayed. On the other hand, if the reel is not rotating at the timing 1, a display suggesting/announcing that the volume can be adjusted can be displayed. Further, in the case of timing 2, since the reels are not rotating, it is possible to perform a display suggesting/announcing that the sound volume can be adjusted. Further, in the case of timing 3, since the reels are rotating, the display suggesting/notifying that the volume adjustment is possible is not performed. Further, at timing 4, since the reels are not rotating, it is possible to perform a display suggesting/notifying that the sound volume can be adjusted.
As a fifth game machine (pachi-slot machine), the operation of setting the volume may be enabled in the state of waiting for an operation in the operation effect of pressing the effect operation means such as the effect buttons 10a and 10b.
In the case of the timing 1, the timing 2, the timing 3, or the timing 4, a display that suggests/informs that the volume can be adjusted if the user is waiting for an operation of a highly important effect such as a winning/losing notification effect. do not On the other hand, if the timing 1, the timing 2, the timing 3, or the timing 4 is not waiting for an operation of high importance such as a winning/losing notification effect, it is suggested/notified that the volume can be adjusted. can be displayed.
As a fifth game machine (pachi-slot machine), even if the game machine is waiting for an operation in the operation presentation, the volume setting operation may be disabled when the reels are rotating. In this case, after all the reels have stopped or after a predetermined time has passed after all the reels have stopped, the volume setting operation is validated. In the case of the above timing 1, if the state is waiting for an operation in the operation presentation and the reels are rotating, the display suggesting/announcing that the volume adjustment is possible is not performed. On the other hand, when it is the timing 1, it is possible to perform a display suggesting/announcing that the sound volume can be adjusted if the reels are not rotating while waiting for an operation in the operation presentation. Further, in the case of the timing 2 or the timing 4, since the reels are not rotating, it is possible to perform a display suggesting/notifying that the volume can be adjusted while waiting for an operation in the operation effect. can. Further, in the case of timing 3, since the reels are rotating, the display suggesting/notifying that the volume can be adjusted is not displayed even in the state of waiting for an operation in the operation presentation.
As a fifth game machine (pachi-slot machine), during a simulated game, which is one of the effects using reels, the volume setting operation may be enabled even while the reels are rotating. In the case of timing 1, it is possible to perform a display suggesting/notifying that the volume can be adjusted even during a simulated game, which is one of the effects using the reels. In the case of timing 3, since it is the timing at which a pseudo-game, which is one of the effects using the reels, is performed, it is possible to perform a display suggesting/notifying that the volume can be adjusted. Timing 2 or timing 4 is a timing at which a pseudo-game, which is one of the effects using the reels, is not performed.
As a fifth gaming machine (pachi-slot machine), the volume setting operation may be disabled during a pseudo-game, which is one of the effects using reels. In the case of the above timing 1, it is possible to perform a display suggesting/notifying that the sound volume can be adjusted unless a pseudo-game, which is one of the effects using the reels, is being performed. In the case of the timing 3, since it is the timing at which a pseudo-game, which is one of the effects using the reels, is performed, the display suggesting/notifying that the volume can be adjusted is not performed. Timing 2 or timing 4 is a timing at which a pseudo-game, which is one of the effects using the reels, is not performed.
The display suggesting/notifying that the amount adjustment is possible may be performed on either the main screen 210a or the sub-screen 220a, or may be performed on both the main screen 210a and the sub-screen 220a.

Further, in the fifth gaming machine (pachi-slot machine), it is possible to set whether or not the timing at which the player sets the volume setting to ON is when the player logs in to Unimemo. That is, in the fifth gaming machine (pachislot machine), the volume setting by the player is set to ON regardless of whether or not the user logs in to YunMemo, or the volume setting by the player is set to ON only while logging in to Unimemo. You can choose either If the volume setting by the player is set to ON only while logged in to Unimemo, the volume setting cannot be performed by the player without logging in, and the initial setting of the volume is maintained.

Although the volume setting has been described here as an example, the ON/OFF of the light amount setting may be set by the player. That is, it may be possible for the player to set ON/OFF of the effect environment setting. Also, the ON/OFF of the light amount setting by the player and the ON/OFF of the volume setting by the player may be set individually, or may be collectively set as effect environment setting.

(Setting status aggregation at logout)
In the fifth gaming machine (pachi-slot machine), a two-dimensional code is displayed for accumulating game information recorded on the fifth gaming machine side in the server 300 when logging out from Unimemo. When the player accesses based on the two-dimensional code, the server 300 appropriately retrieves the game information using the data indicating the game information stored on the fifth gaming machine (pachi-slot machine) acquired at the time of access. Update and accumulate.

The game information obtained when the server 300 is accessed via the two-dimensional code includes information regarding the setting status. The information about the setting status includes, for example, the setting value of the fifth gaming machine (pachi-slot machine) when the game is played (for example, setting 1 to setting 6 in 6 stages), so-called " You can select the success rate of "eye-pushing", the selection rate of characters in custom effects (for example, character A 50%, character B 30%, character C 15%, character D 5%, etc.), and the type of effect (effect type) for notifying the grant of benefits. The selection rate of the production type when a bonus is installed can be mentioned.

(Timing when player's volume setting operation is effective)
A fifth game machine (pachi-slot machine) may be configured so that the volume setting operation can be performed at any timing except during an error. Any timing other than during an error includes during display of a demonstration screen (standby screen), during progress of a game, and during standby for a game.
Further, when the reels are rotating (fluctuating in the case of pachinko), the volume setting operation may be disabled. In this case, the sound volume setting is validated when a game operation is awaited after all the reels have stopped or after a predetermined time has elapsed since the end of the game.
In addition, in the state of waiting for an operation in the operation effect of pressing the effect operation means such as the effect buttons 10a and 10b, the volume setting operation may be enabled.
Further, even in the state of waiting for an operation in the operation effect, when the reels are rotating, the operation of setting the sound volume may be invalidated. In this case, after all the reels have stopped or after a predetermined time has passed after all the reels have stopped, the volume setting operation is validated.
Further, during a pseudo game, which is one of the effects using the reels, the volume setting operation may be enabled even while the reels are rotating.
Further, during a pseudo-game, which is one of the effects using the reels, the volume setting operation may be disabled.

(Settlement while logged in)
In the fifth game machine (pachislot machine), when you press the checkout button 9 (see FIG. 1) while logging in to Unimemo to pay for the accumulated medals, a two-dimensional code saying "Be careful not to forget to take Unimemo!" A warning notification is performed to prevent forgetting to read the This makes it possible to remember to log out of Unimemo when quitting the game. When you stop playing, you need to pay for the accumulated medals, transfer the medals to the box, take out the membership card from the sandwich, take out your baggage, etc. It is easy to forget to log out of Unimemo (read the two-dimensional code). Therefore, it is effective to provide an alert notification to prevent forgetting to read the two-dimensional code. Note that the payment of stored medals includes the payout of stored medals to the medal receiving tray 12 (see FIG. 1) and the transfer of medal information in the case of a medalless gaming machine.

(Sound effect when paying for accumulated medals)
When the stored medals are to be settled, sound effects are output from the speakers 35a and 35b. The sound effect when the stored medals are settled is output at a predetermined volume (for example, a volume higher than the median volume in the volume adjustment range), not at the volume level set by the volume setting. This makes it easier for the store clerk of the amusement arcade to recognize that the accumulated medals are being settled. As a result, it is possible to prevent a fraudulent act of paying for the accumulated medals and taking away the medals without permission from the gaming machine when the player is away from the seat.

Also, the effect sound when the stored medals are settled may be output at the volume level set by the volume setting. As a result, when the player lowers the sound volume level in the sound volume setting, it is possible to prevent a loud sound from being output even when the accumulated medals are settled. As a result, it is possible to prevent the player from feeling uncomfortable due to the sudden output of a loud sound when the accumulated medals are settled.

Also, at the time of payout of medals including settlement of stored medals, a lighting effect is performed in which the LEDs provided on the medal receiving tray 12 emit light. This light emission effect is output at a predetermined light amount (for example, a light amount greater than the median light amount in the light amount adjustment range), not at the light amount level determined by the light amount setting. This makes it easy to understand that medals (game value) have been awarded. Note that the payout of medals includes not only the actual payout of medals to the medal tray 12, but also the accumulation of medals when winning a small winning combination.

The light emission effect performed at the time of payout of medals including settlement of accumulated medals may be output at the light amount level according to the light amount setting. If the amount of light is large only in the light emission effect that is performed when the medals are paid out, there is a risk that the effect of other light emission effects will be reduced. Therefore, by outputting the light emission effect that is performed when the medals are paid out at the light amount level according to the light amount setting, it is possible to prevent the effect of other light emission effects from being reduced.

(Light intensity setting during lights-out effect)
In the fifth gaming machine (pachi-slot machine), there is an extinguishing effect in which the lamps for which the light intensity is set (for example, the upper lamp 23 and the reel lamps) are extinguished, and a low luminance effect in which the lamp for which the light intensity is to be set emits light at low luminance. Perform brightness production. A fifth game machine (pachi-slot machine) prohibits a player from setting the amount of light during a light-off effect or a low-luminance effect. As a result, it is possible to prevent a situation in which the lighting effect or the low-luminance effect is not noticed by setting the light amount. In addition, it is possible to prevent the player from being unable to grasp the time during which the lights-out effect or the low-luminance effect is being performed.
In addition, the lights-out effect and low-brightness effect, for example, if they occur, benefits (such as transitions to jackpots, variable probability, time-saving states, etc. in pachinko game machines, winning of predetermined winning roles in reel-type game machines, and AT-related (benefits)) are raised or fixed. It should be noted that the light-off effect and low-luminance effect can be generated during execution of other effects such as an image effect by a display device and a sound output effect by a speaker, and can suggest the level of expectation.

(Composition of customization screen)
The fifth game machine (pachi-slot machine) was configured to display a character customization screen (see FIG. 191) on the main display device 210 . Then, selection buttons such as a character selection button, a costume selection button, an item selection button, and a character representing the selection result are displayed on the customization screen. A fifth game machine (pachi-slot machine) has a sub-display device 220 . Therefore, each selection button may be displayed on the sub-display device 220 and a character representing the selection result may be displayed on the main display device 210 . As a result, the character representing the selection result can be displayed in a large size, and the player can easily confirm the selection result. Since the sub-display device 220 that displays each selection button is provided with a touch input section, a character, costume, or item can be selected by touching each selection button with a finger.

In addition, in the gaming machine according to the present invention, each selection button may be displayed on the main display device 210 and a character representing the selection result may be displayed on the sub display device 220 . For example, when a character is displayed on the sub-display device 220 during a game, by displaying the character representing the selection result on the sub-display device 220, the selected character can be confirmed in the same size as during the effect. can be done. Note that a touch input unit may be provided in the main display device 210 that displays each selection button. In this case, a character, costume, or item can be selected by touching each selection button displayed on the main display device 210 with a finger.

(Display of level related to login)
In the fifth gaming machine (pachislot machine), the progress of the game while logging in to Unimemo (the number of games played, the winning of small wins and bonuses, the winning of AT, the achievement of a predetermined mission, etc.) achievement), the Unimemo level rises. In the Unimemo login state, the Unimemo level is displayed on the sub-display device 220 . In addition, reaching a predetermined level of the Uni-memo level is included in the above-described release condition predetermined according to the progress of the game. When the Unimemo level reaches the upper limit, the item "Level Reincarnation" becomes selectable on the Unimemo menu screen. When "level reincarnation" is selected, the uni-memo level returns to the initial level (for example, "level 1"), and "first reincarnation" is displayed next to the level display on the sub display device 220. FIG. This makes it possible to raise the Uni-memo level again.
"First reincarnation" is a display indicating that the Uni-memo level has reached the upper limit once. As the number of times the Unimemo level reaches the upper limit increases, the number of reincarnations increases, such as "2nd reincarnation", "3rd reincarnation", and so on.

(Keep volume setting after logout)
In the fifth gaming machine (pachislot machine), when Unimemo is logged out, the value of the credit counter indicating the number of game values accumulated in the credit and the value of the bet number counter indicating the number of game values already betted are 0. When the number of sheets is 0 (zero) and the demonstration screen (standby screen) is displayed on the main display device 210, the effect customization and the effect environment are returned to the initial settings (default settings). However, the gaming machine according to the present invention may maintain the effect customization and the effect environment even after Unimemo is logged out. Alternatively, only the performance environment may be maintained.

Here, a Unimemo logout operation will be described.
There are the following three Unimemo logout operations in the fifth game machine (pachislot machine).

The first logout operation is to select the item "End Unimemo" to display the two-dimensional code and terminate the display. The item “End Unimemo” can be selected from the guide menu displayed on the sub display device 220 . Strictly speaking, the timing of completion of logout by this logout operation may be accomplished by selecting "end display of two-dimensional code" by operating a production key or the like after displaying the two-dimensional code, and ending the display. This is when the option "yes" is selected in response to the display of the confirmation message for confirming whether or not. As a result, processing for ending the display of the two-dimensional code is performed, and a logout state is entered. Also, if the next game is started by inserting medals or operating the start lever while the two-dimensional code is being displayed, the display of the two-dimensional code will end (or the display of the two-dimensional code will end when the medal is inserted). ), but in this case, it is desirable that logout processing is not performed. This is because the intention of the player is to be respected since the player is actually intending to continue the game.
The second logout operation is to newly log in to Unimemo while logged in to Unimemo. To log in to Unimemo for the first time, select the item "Enter Password" and enter the password, or select the item "Quick Start" and select Quick Start. The items “password input” and “quick start” can be selected from the guide menu displayed on the sub-display device 220 . Here, "quick start" means a login method that does not require password input. This item is for players who do not need to accumulate game data accumulated from previous games or accumulate Unimemo levels, or who simply find password entry troublesome. Even with "Quick Start", the game data from the login is recorded on the game machine and can be read with the two-dimensional code for confirmation and the two-dimensional code at the end, so the game data of this game (number of games completed, This is convenient for a player who wants to know the number of bonuses, the number of ATs, the odds of a small winning combination, etc.) but finds it troublesome to enter a password. If quick start is selected, it is possible to log in to Unimemo without reflecting game information such as effect customization and effect environment accumulated in the server 300 . If you select "Quick Start" or "Enter Password" while logging in to Unimemo, you will be prompted with the message "You are currently logged in, but would you like to log in again? Unsaved data will be lost." Then, two selection buttons “Yes” and “No” are displayed on the sub-display device 220 . Touching the "Yes" button here enables quick start or password input. On the other hand, when the "No" button is touched, the display on the sub-display device 220 returns to the video display for presentation.
The third logout operation is to select the item "end login state" while logging in to Unimemo. The item “end login state” can be selected from the guide menu displayed on the sub-display device 220 . It should be noted that if you select "end the login state", it may be possible to complete the logout immediately, if you select "end the login state", and if you select "end the current game data when you log out" Do you want to logout?" and ask the player to select "Yes" or "No", and logout is completed when "Yes" is selected. It can be a thing. By performing such logout confirmation, it is possible to suppress logout due to an erroneous operation.

(recovery from power failure during login)
In the fifth game machine (pachi-slot machine), the login state of Unimemo is not erased when power is cut off. Therefore, if the user is in the Unimemo login state before the power failure, the Unimemo login state is restored when the power is restored. Note that, as described above, after the power is restored, the performance environment is returned to the initial setting (default setting).

Images indicating volume levels as shown in FIGS. 177 and 178 may be displayed on a main screen such as the liquid crystal display area 210a shown in FIG. 180, or may be displayed on a sub screen such as the liquid crystal display area 220a shown in FIG. may be displayed in In addition, when the volume adjustment menu is opened, the effect display that is currently being executed may be temporarily interrupted and switched to a screen dedicated to volume adjustment, or the effect screen that is currently being executed may be superimposed on the image layer on the front side. It can be a thing. When it is displayed on the front layer, it may be displayed large in the center of the screen to make it easy to see the volume, or it may be displayed small in the edge of the screen to ensure the visibility of the effect screen.

The gaming machine according to the present embodiment may continuously output the currently occurring BGM when the volume adjustment menu is opened, or may output the BGM for the volume adjustment menu. good. In the case of the specification of outputting the BGM for the adjustment menu, the player can easily recognize the volume of the BGM even when he/she wants to adjust the volume in a state where the BGM is not generated (for example, a so-called normal game). Further, the gaming machine according to the present embodiment may output a sample sound when the volume level is changed by the overall volume meter 231 or the category volume meters 232 to 234 . When the overall sound volume is adjusted, it is difficult for the player to understand if "BGM", "SE" and "VOICE" are output simultaneously, so it is desirable to output "SE" or "VOICE" as a representative example. When adjusting the volume of "SE" in the volume by category, generate a predetermined SE (either a special sound effect or a sound effect of another production) and adjust the volume of "VOICE" should generate a predetermined voice. For example, if the volume level after adjustment is 1, "Volume is 1", and if the volume level is 2, "Volume is 2". easier for people to understand. In addition, in the gaming machine according to the present embodiment, it is assumed that the volume adjustment is finalized by performing an operation to complete the volume adjustment, such as touching the decision icon after adjustment, operating a predetermined effect button, volume adjustment button, or the like. good. In this case, when the volume adjustment confirmation operation is performed, a display indicating that the volume adjustment is completed, a sound effect, or a voice saying "volume adjustment is completed" may be generated.

In the gaming machine according to the present embodiment, the player does not perform a predetermined operation (an operation related to the progress of the game, or an operation not related to the progress of the game such as adjusting the volume or logging in to Unimemo) for a predetermined time (for example, 30 seconds). ) has elapsed, a demonstration screen (standby screen) is displayed on the main display device 210 . Then, when the standby screen is displayed, the sound is turned off or muted. However, in the gaming machine according to the present embodiment, a predetermined time (for example, , 30 seconds) has elapsed, a volume reduction function may be provided to automatically reduce the volume of the currently occurring BGM. In this case, the sound volume is lowered while the effect of the image being executed remains unchanged. For example, if the BGM continues to be output at the same volume when the player leaves the seat while BGM is being played, such as during an AT or during a bonus, it can be annoying to surrounding players. By providing a function that automatically lowers the volume of BGM, the volume automatically decreases when a game is not in progress. can be made easier. The volume after the decrease may be decreased at a constant rate such as 1/2 or 1/4 of the volume immediately before the decrease, or may be a predetermined volume level during decrease. As the volume level at the time of decrease, for example, it may be the same volume as volume level 1 which is the minimum volume that can be set by adjustment by the player, a predetermined volume higher than volume level 1, or a predetermined volume lower than volume level 1. A mute with a volume value of 0 may be applied to make the volume or silence. Further, when a bet operation, a start lever operation, or the like is performed while the volume is lowered and a predetermined operation for resuming the game is detected, it is desirable to restore the volume to the level before the volume was lowered. In addition, the game machine according to the present embodiment switches to the standby screen (demonstration screen) when a longer time (eg, 3 minutes) has passed than the time (eg, 30 seconds) at which the volume reduction by the volume reduction function starts. You may do so. Then, when the standby screen is displayed, the volume of the non-playing table is gradually lowered by muting or muting the sound, or by making the sound even smaller than during the volume reduction. It may be made to

The gaming machine according to the present embodiment displays a demonstration screen (standby screen) on the main display device 210 after the power is turned on. Specifically, when the power is turned on, first, a screen notifying that the power is turned on is displayed, such as "powering up" and "NOWLOADING", and after the power is turned on, the standby screen is displayed. becomes. It should be noted that the gaming machine according to the present embodiment may not display a notification that the power is being turned on. When the standby screen is displayed after the power is turned on, BGM is not sounded (no sound). When the standby screen is displayed after the power is turned on, the BGM may be output at a low volume (for example, a volume lower than the default volume). In this case, the BGM sound may be used during the game, or may be provided in advance for the standby screen. Further, the gaming machine according to the present embodiment may display a normal screen that is displayed during game standby without displaying the standby screen after the power is turned on. In this case, the BGM, SE, VOICE, etc. may not be sounded (silent), or the same BGM, etc. as during the game standby may be sounded.
In addition, in the gaming machine according to the present embodiment, when an operation related to the progress of the game (for example, operation of the start lever 7) is performed in a state where the standby screen is displayed after the power is turned on, the standby screen is displayed (demonstration effect ) to the normal screen display (game effect). When the display of the standby screen shifts to the display of the normal screen, the setting of the performance environment such as the volume may be returned to the initial state. As a result, it is possible to prevent the players who are playing at the time of opening the store from having a sense of incongruity with respect to the production environment. If the performance environment at the time of closing is inherited when the store opens, the performance environment (for example, volume) will be different for each game machine immediately after the store opens. As a result, the player may feel uncomfortable. Therefore, when the power is turned on, it is possible to reduce the player's sense of incompatibility by setting the presentation environment to the initial state.
A sub-control circuit that controls the performance environment may not be provided with data backup means. In this case, the setting of the performance environment disappears when the power is turned off. As a result, the performance environment returns to the initial state after the power is turned on.
A sub-control circuit that controls the performance environment may be provided with data backup means. In this case, the setting data of the rendering environment is discarded when the power is turned off. Alternatively, the setting data of the output environment is maintained when the power is turned off, but the setting data of the rendering environment is initialized when the power is turned on. As a result, the performance environment returns to the initial state after the power is turned on.

In addition, the gaming machine according to the present embodiment can perform volume adjustment and light intensity adjustment when the demonstration screen (standby screen) is displayed. In this case, the volume adjustment screen and the light amount adjustment screen may be displayed superimposed on the standby screen. Then, when the volume adjustment and the light amount adjustment are completed, the volume adjustment screen and the light amount adjustment screen are turned off so that only the standby screen is displayed. Further, in the gaming machine according to the present embodiment, when an operation for volume adjustment or light amount adjustment is performed while the standby screen is displayed, the standby screen is turned off and the volume adjustment screen or the light amount adjustment screen is displayed. can be In this case, when volume adjustment and light intensity adjustment are completed, the volume adjustment screen and light intensity adjustment screen are turned off, and the standby screen is displayed.
Further, the mode of the lamps when the light amount is adjusted while the standby screen is displayed can be the mode during the standby screen, the normal mode same as when the game is played, or the mode dedicated to the light amount adjustment. Modes of these lamps may be made selectable, for example, on the light amount adjustment screen. When adjusting the amount of light, if the mode of the lamps is not changed in the mode of the standby screen, the current amount of light and the amount of light after adjustment are easily compared, so that the player can easily adjust the amount of light to a desired amount. When adjusting the amount of light, if the mode of the lamps is changed to the normal mode, the amount of light when the game is played can be confirmed. As a result, when returning to the normal game, it is possible to prevent the player from feeling uncomfortable about the amount of light. In the case of adjusting the light amount, when the mode of the lamps is set to the mode dedicated to the light amount adjustment, the change in the light amount can be made conspicuous, and the difference in the light amount can be easily recognized by the player.

Further, in the gaming machine according to the present embodiment, if an error occurs while the volume adjustment screen or the light amount adjustment screen is being displayed, the error notification screen is superimposed on the volume adjustment screen or the light amount adjustment screen and displayed. You may do so. In this case, when the error is resolved, the error notification screen is turned off and the volume adjustment screen, the light intensity adjustment screen, or the normal screen is displayed. Also, if an error occurs while the volume adjustment screen or the light amount adjustment screen is being displayed, the volume adjustment screen or the light amount adjustment screen may be turned off and the error notification screen may be displayed. In this case, when the error is eliminated, the error notification screen is turned off and the standby screen or normal screen is displayed.

The game machine according to the present embodiment has a physical switch for adjusting the volume inside the housing (a slide switch that can be set to small, medium, large, etc., and a volume switch that is operated by turning the volume 1 to 10, etc.). may In this case, the set volume may be reset and the volume setting by the physical switch may be set. Further, even if the volume is set by a physical switch, the set volume may be reflected as much as possible. For example, in a game machine with volume levels 1 to 7, when the maximum volume is set to volume level 5 and the volume level is set to "medium" and the volume adjustment range is limited to the range of volume levels 1 to 5, the volume before operating the physical switch If the level is 4, the volume level 4 is maintained, but if the volume level was 6 before operating the physical switch, the volume level may be changed to 5.

[13-7. Note]
2. Description of the Related Art Conventionally, game machines have been known in which a guide menu screen is displayed on a display device, and the volume and amount of light can be set to desired levels by operating input units such as left and right keys. 2008-295551). According to the gaming machine as disclosed in Japanese Patent Application Laid-Open No. 2008-295551, there is an advantage that the player can set the performance environment such as sound volume and amount of light as desired.

By the way, in a gaming machine capable of setting an effect environment as described in Japanese Patent Application Laid-Open No. 2008-295551, it is desired to enhance convenience for the player in setting the effect environment.
For example, even if a player finds and sets his or her own preferred production environment (for example, volume or amount of light), in order to reproduce the same production environment in subsequent games, setting information for the production environment (such as volume value and light intensity value) must be remembered by the player. Also, there is a problem that it is troublesome to memorize the setting information of the production environment and to set the production environment each time a game is played (started).

SUMMARY OF THE INVENTION The present invention has been made in view of such a point, and an object of the present invention is to improve the convenience of the player regarding the setting of the performance environment.

In order to achieve the above object, according to the gaming machine according to the present embodiment, it is possible to provide a gaming machine having the following configuration.

production means (for example, speakers 35a, 35b, upper lamp 23, main display device 210, sub-display device 220, etc.) for performing game production;
Production control means (for example, sub-control circuit 200) that controls the production means,
A game machine comprising effect environment setting means (for example, a sub CPU 201 for setting sound volume, light amount, etc.) capable of setting the effect environment (for example, volume, light amount, etc.) in the effect means according to an operation by a player. hand,
A gaming machine characterized in that, when settlement processing for settlement of game values (for example, medals) is executed, said effect control means shifts the effect performed by said effect means to a demonstration effect.

According to the gaming machine of the present invention having the above configuration, the waiting screen is displayed immediately after the settlement process is performed, so that the player who is looking for a machine in the store can easily understand whether the machine is empty or not. . As a result, the operation is promoted, and convenience for the player can be enhanced in setting the performance environment.

The gaming machine as described above, wherein the effect environment set by the effect environment setting means is in an initial state when the settlement process is executed.
According to such a gaming machine, even if the previous player has set the extreme production environment (for example, a large volume), the player who plays the game after that makes the extreme production environment uncomfortable. You can make it so you don't feel it.

The gaming machine described above is characterized in that, while the demonstration effect is being executed, the BGM is not output, or the BGM is in a silent state in which the volume of the BGM is suppressed.
According to such a gaming machine, the environment of the entire hall can be made quiet.

When an operation related to the progress of the game (for example, operation of the start lever 7) is not performed for a predetermined period (for example, 3 minutes), it is possible to shift from the game effect to the demonstration effect,
When an operation related to the progress of the game is not performed for a specific period (for example, 30 seconds or 1 minute) shorter than the predetermined period, the sound output volume is lower than the volume set by the production environment setting means. The above-mentioned game machine, characterized in that it is possible to set the volume to be reduced.
According to such a gaming machine, it is possible to suppress the sound volume when it is expected that the player will temporarily leave the hall, so that the environment of the entire hall can be made quiet.

When an operation related to the progress of the game is performed in the volume reduction state, the volume reduction state ends, and a state is entered in which sound is output at the volume set by the production environment setting. game machine.
According to such a game machine, even if the volume is temporarily decreased, the volume is immediately restored to the original volume (the volume set by the player) by performing a game operation. Therefore, when the game is restarted after leaving the seat for a short period of time, the sound volume set by the player is maintained, so that convenience for the player can be enhanced in setting the performance environment.

The game machine described above is characterized in that the effect means can execute a demonstration effect after the power is turned on, and the game effect is shifted from the demo effect to the game effect when an operation relating to progress of the game is performed.
According to such a game machine, a demonstration effect is executed at the opening of the store (for example, a video introducing the characteristic image of the machine, attractive game characteristics, characters, etc. is displayed). The game machine can be appealed to the player who has played the game. Furthermore, since the BGM sound is not output during the demonstration production, the inside of the hall can be made silent.

In a situation where the performance environment can be set by the performance environment setting means, it is possible to display that the performance environment can be set, and the performance environment can be set even in the volume reduction state. The gaming machine described above is characterized by being capable of displaying a message to the effect that the
According to such a gaming machine, it is possible to make it easier for the player to recognize that the performance environment can be set.

The game machine described above is characterized in that after the power is turned on, the setting of the performance environment is in an initial state.
According to such a gaming machine, it is possible to prevent the player from feeling uncomfortable about the performance environment when the store opens. If the presentation environment at the time of opening takes over the presentation environment at the time of closing, the presentation environment (for example, volume) will be different for each game machine immediately after opening. As a result, the player may feel uncomfortable. Therefore, when the power is turned on, it is possible to reduce the player's sense of incompatibility by setting the presentation environment to the initial state.

Equipped with administrator environment setting means (for example, a physical switch for volume adjustment provided in the housing) that cannot be operated by the player,
When the performance environment is set by the environment setting means for administrator in a state where the performance environment is set by the environment setting means for administrator, the performance environment set by the environment setting means for administrator is changed. The gaming machine described above is characterized in that the setting is updated.
According to such a game machine, when the player wants to ignore the performance environment set by the player and uniformly adjust the performance environment in the hall, there is no need to worry about the performance environment set for each game machine. . As a result, it is possible to enhance the convenience of adjusting the performance environment by the hall side.

At the time of a predetermined operation by the player, the effect control means causes the effect means to enter a two-dimensional code at the end that can be read by the mobile terminal (for example, a two-dimensional code for storing the game information recorded on the gaming machine side in the server 300). dimension code) can be displayed,
The two-dimensional code at the end includes information on the setting of the production environment,
By performing a predetermined login operation (for example, entering a password) when starting the next game, it is possible to reproduce the setting of the effect environment at the end of the previous game. game machine.
According to such a gaming machine, by performing a predetermined login operation, it is possible to set the effect environment at the end of the previous game, and it is possible to improve the convenience of setting the effect environment at the time of starting the game. .

1... Pachi-slot machine 3L, 3C, 3R... Reel 8L, 8C, 8R... Stop button 23... Upper lamp 35a, 35b... Speaker 71... Main control board 72... Sub control board 100... Main control circuit 101 Main CPU 200 Sub control circuit 201 Sub CPU 210 Main display device 220 Sub display device

Claims (1)

light emitting means;
a plurality of light emission drive means for driving the light emission means;
a control means for driving the plurality of light emission drive means to control light emission operations of the light emission means;
The light emitting means has a plurality of multicolor light emitting means and a plurality of segment light emitting means,
The multicolor light emitting means is composed of light emitting elements capable of emitting color light, the segment light emitting means is composed of a plurality of segment light emitting elements,
The control means is
light emission data generation means for generating light emission data for controlling the light emission drive means;
data storage means for storing the light emission data generated by the light emission data generation means;
The data storage means are
a first storage area storing first light emission data for driving and controlling the plurality of multicolor light emitting means;
a second storage area for storing selection information for selecting one segment light emitting means from among the plurality of segment light emitting means;
a third storage area for storing second light emission data for driving and controlling one selected segment light emitting means;
a fourth storage area for storing all of the plurality of second light emission data for respectively driving and controlling the plurality of segment light emitting means;
When the control means sets the second light emission data for driving and controlling the selected one segment light emission means in the third storage area, the control means sets the corresponding segment light emission means stored in the fourth storage area. A game machine characterized by reading out the second light emission data of and setting it in the third storage area.

Images