JP7313324B2 - game machine - Google Patents

Description

TECHNICAL FIELD The present invention relates to a game machine capable of changing settings related to effects.

2. Description of the Related Art Conventionally, there is known a game machine capable of changing settings related to effects (see Patent Literature 1).
In this gaming machine, it is possible to change the setting change information stored in the storage unit for each of the low-probability game state and the high-probability game state in accordance with the setting change operation. The effect during the game is controlled based on the setting change information stored in the storage unit.

JP 2018-110627 A

However, in the conventional game machine, it is unclear whether or not the change of the setting related to the effect has been confirmed, which may make the player feel uncomfortable.
An object of the present invention is to prevent the player from feeling uncomfortable.

上記目的を達成するために、第一の発明に係る遊技機は、上部に意匠部が形成された前枠と、遊技領域が形成された遊技盤と、前記遊技領域の上部に配置され、外周面及び内周面を有する誘導通路と、演出に関する設定の変更が可能となる期間中に設定画像を表示し、前記演出に関する設定の変更が確定した場合に特定画像を表示する表示手段と、を備え、前記設定画像の表示中に第１条件が成立した場合、当該設定画像の表示が終了され、前記特定画像の表示中に前記第１条件が成立した場合、当該特定画像の表示が終了されず、前記遊技盤の盤面に対して垂直方向に延びる線のうち、前記外周面の頂上を通る線を第１基準線とし、前記第１基準線に対する鉛直線が交わり得る部分のうち、前記意匠部の下面における最も後側の部分を第１意匠部とし、前記第１基準線に対する鉛直線が交わり得る部分のうち、前記意匠部の下面における最も下側の部分を第２意匠部とすると、前記第１意匠部は、前記第１基準線よりも下方に位置するとともに、前記第１基準線からの距離が遊技球の直径以下となっており、前記第２意匠部は、前記第１基準線よりも下方に位置するとともに、前記第１基準線からの距離が遊技球の直径以上となっており、前記第１意匠部と前記第２意匠部とを結ぶ仮想直線は、前記誘導通路側が高くなるように傾斜しており、前記第２意匠部は、前記第１意匠部と水平方向に離間して配置されており、前記第１意匠部と前記第２意匠部との間に形成される空間を介して、正面側から前記誘導通路を視認可能となっていることを特徴とする。
In the gaming machine according to the first aspect of the invention, the specific image is displayed in response to confirmation of the change of the setting regarding the effect. As a result, it is possible to inform the player that the change of the setting regarding the effect has been confirmed based on the display of the specific image.
In particular, in the gaming machine according to the first aspect, the display of the setting image is terminated when the first condition is met, but the display of the specific image is not terminated when the first condition is met. As a result, it becomes possible for the player to more reliably recognize that the change of the setting regarding the effect has been confirmed.
As described above, in the gaming machine according to the first aspect of the invention, it is possible to clearly notify that the change of the setting related to the effect has been confirmed, and it is possible to prevent the player from feeling uncomfortable.
Here, the setting related to the effect corresponds to the effect custom setting described later. A setting image corresponds to a second custom interface image IF2, which will be described later. The specific image corresponds to a custom change message image cm, which will be described later. An effect control board 300, which will be described later, corresponds to the display means. The first condition corresponds to the case where the variation of the special symbol to be described later is started (when one of the subcommands of the symbol type designation command, the variation mode designation command, and the variation pattern designation command is received).

According to the present invention, it is possible to prevent the player from feeling uncomfortable.

1 is a perspective view showing the overall configuration of a pachinko machine; FIG. It is a diagram showing the front of the game board, and schematically showing a part particularly necessary for explanation. It is a block diagram which shows the structure of the control system of a pachinko machine. 3 is a block diagram showing configurations of a firing condition detection circuit and a firing control circuit; FIG. It is a block diagram which shows the structure of a production|presentation control board. 3 is an address map of a memory area used by the CPU 210. FIG. 4 is a flowchart showing CPU initialization processing; 4 is a flowchart showing main loop processing; 7 is a flow chart showing saving processing at power-off. 4 is a flowchart showing timer interrupt processing; 4 is a flowchart showing dynamic port output processing; 4 is a flowchart showing performance display device output processing. 8 is a flowchart showing setting-related processing; 4 is a flowchart showing switch management processing; It is a flow chart which shows normal figure starting ball detection processing. It is a flow chart showing a special figure 1 starting ball detection process. It is a flow chart showing a special figure 2 starting ball detection process. It is a flow chart showing a special symbol random number acquisition process. It is a flow chart showing a special game management process. It is a flow chart showing a special figure variation waiting process. It is a flow chart showing processing during special figure fluctuation. It is a flowchart which shows processing during a special figure stop. It is a flow chart which shows a special prize opening pre-opening process. 10 is a flowchart showing a special electric service open/close switching process; It is a flow chart showing a special winning opening opening control process. It is a flow chart showing a special winning opening closing effective process. It is a flow chart showing a special winning opening opening end wait process. It is a flow chart showing normal game management processing. It is a flowchart which shows normal figure fluctuation waiting processing. It is a flow chart which shows processing during normal figure fluctuation. It is a flow chart which shows processing during normal figure stop. It is a flow chart showing normal electric accessary product opening pre-processing. 10 is a flowchart showing normal electric open/close switching processing; It is a flow chart showing normal electric accessory opening control processing. It is a flow chart showing normal electric accessary product closing effective processing. It is a flowchart showing normal electric accessary product open end wait processing. 4 is a flowchart showing performance display device control processing. 4 is a flowchart showing sub CPU initialization processing; 8 is a flowchart showing initial transfer processing; 4 is a flowchart showing sub timer interrupt processing; 4 is a flowchart showing command analysis processing; FIG. 11 is a flowchart showing pending command reception processing; FIG. 9 is a flowchart showing prefetch command reception processing; 9 is a flow chart showing variation command reception processing. 9 is a flowchart showing stop command reception processing; 9 is a flowchart showing opening command reception processing; 4 is a flowchart showing Vsync interrupt processing; FIG. 11 is a flowchart showing command construction task processing; FIG. 4 is a flowchart showing sound interrupt processing; 4 is a flowchart showing lamp interrupt processing; It is a flow chart which shows movable body interruption processing. 3 is a block diagram showing the configuration of a sound circuit; FIG. FIG. 4 is a diagram showing types of frequency correction parameters; FIG. 10 is a diagram showing settings of a channel router; FIG. 4 is a diagram for explaining a ducking function; FIG. FIG. 10 is a diagram showing the contents of command lists corresponding to sound effects A and B; FIG. 10 is a diagram showing the first opening/closing member 80 arranged at the closed position; FIG. 10 is a diagram showing the first opening/closing member 80 arranged at the minimum open position; FIG. 4 is a diagram showing the first opening/closing member 80 arranged at the maximum open position; FIG. 10 is a diagram showing the second opening/closing member 90 arranged at the closed position; FIG. 10 is a diagram showing the second opening/closing member 90 arranged at the minimum open position; FIG. 10 is a diagram showing the second opening/closing member 90 arranged at the maximum open position; FIG. 12 is an enlarged view showing the firing handle unit; FIG. 10 is a perspective view showing the firing handle unit with the face cover removed; It is a figure which shows the positional relationship of an operation ring and a front frame unit. It is a figure which shows the positional relationship of an operation ring and an inner frame unit. FIG. 5 is a diagram showing an example of setting an operation torque according to the first embodiment; FIG. FIG. 11 is a diagram showing an example of setting an operation torque according to Example 2; It is an exploded perspective view of a game board. It is a figure which shows the structure of an outer rail. FIG. 4 is a diagram showing the arrangement of guide holes gh in the outer rail; It is a cross-sectional view of the rail base. FIG. 2 is a cross-sectional view taken along line AA shown in FIG. 1; Figure 74 is an enlarged view of Figure 73; 9 is a flowchart showing material replacement offset setting processing; It is a figure which shows the production|presentation custom classification. FIG. 4 is a diagram showing an example of a first custom interface image IF1; FIG. FIG. 10 is a diagram showing display transitions during the first custom state; FIG. 10 is a diagram showing display transitions when the first custom state ends. FIG. 10 is a diagram showing an example of a second custom interface image IF2; FIG. FIG. 10 is a diagram showing display transition during the second custom state according to the first example; FIG. 11 is a diagram showing display transition during the second custom state according to the second example; FIG. 10 is a diagram showing an example of a custom change message image cm; FIG. 10 is a diagram showing display transitions when the second custom state ends. FIG. 12 is a diagram showing transition of display of the custom change message image cm at the end of the second custom state. FIG. 86 is a diagram showing display transitions at the end of the fourth custom state. FIG. 12 is a diagram showing transition of display of the custom change message image cm at the end of the fourth custom state.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In this embodiment, the gaming machine according to the present invention is applied to a pachinko machine 1. FIG.

(Overall Configuration of Pachinko Machine 1)
First, the overall configuration of the pachinko machine 1 will be described.
FIG. 1 is a perspective view showing the overall configuration of a pachinko machine.
The pachinko machine 1 includes an outer frame unit 2, a body frame unit (not shown), and a game board unit 10. - 特許庁
The outer frame unit 2 includes a rectangular frame (outer frame). The outer frame unit 2 (outer frame) is fixed to the island facilities of the game arcade.
The body frame unit includes an inner frame unit 3 (inner frame) and a front frame unit 4 (front frame). The body frame unit (body frame) is attached to the outer frame unit 2 via a hinge mechanism. The body frame unit is arranged on the front side of the outer frame unit 2 . This allows the body frame unit to open and close the front side of the outer frame unit 2 .

The inner frame unit 3 includes a rectangular frame (inner frame). The inner frame unit 3 is attached to the outer frame unit 2 via a hinge mechanism. The inner frame unit 3 is arranged on the front side of the outer frame unit 2 . A game board unit 10 is attached to the inner frame unit 3. - 特許庁This allows the inner frame unit 3 to open and close the front side of the outer frame unit 2 .
The front frame unit 4 includes a rectangular frame (front frame). The front frame unit 4 is attached to the outer frame unit 2 via a hinge mechanism. The front frame unit 4 is arranged on the front side of the inner frame unit 3 . Thereby, the front frame unit 4 can open and close the front side of the inner frame unit 3 (in particular, the front side of the game board unit 10 attached to the inner frame unit 3).
Further, the front frame unit 4 includes a pair of transparent plates g1 and g2. The pair of transparent plates g1 and g2 are arranged substantially in the center of the front frame unit 4 (front frame) when viewed from the front side. A pair of transparent plates g1 and g2 are arranged in parallel along the depth direction. Each of the transparent plates g1 and g2 is made of a transparent material such as resin or glass and formed into a flat plate shape.
Further, the front frame unit 4 includes a decoration unit DU, a saucer unit SU, and a firing handle unit 6. The decoration unit DU, the saucer unit SU and the firing handle unit 6 are attached to the front of the front frame unit 4 (front frame).
In particular, the decoration unit DU and the saucer unit SU are detachably attached to the front frame unit 4 .

(Configuration of decoration unit DU)
Next, the configuration of the decoration unit DU will be described.
The decoration unit DU is arranged so as to surround the transparent plates g1 and g2. The decoration unit DU includes a design portion (decorative portion) 40, a speaker 22 (see FIG. 3), and a frame rank 20 (see FIG. 3).
The design portion 40 is arranged around the transparent plates g1 and g2. The design portion 40 is made of a resin material and has a shape that bulges (protrudes) toward the front side. At each upper corner of the design portion 40, a sound elimination portion 4c is provided. Each sound removal part 4c is provided with a plurality of sound removal holes through which the sound output by the speaker 22 is passed.
The speaker 22 is arranged inside each sound removing portion 4c. The frame lamp 20 is arranged inside the design portion 40 . The frame lamp 20 includes a plurality of light emitting elements (LEDs) driven by dynamic lighting control.

(Configuration of saucer unit SU)
Next, the configuration of the receiving tray unit SU will be described.
FIG. 57 is a diagram showing the first opening/closing member 80 arranged in the closed position. FIG. 58 is a diagram showing the first opening/closing member 80 arranged at the minimum open position. FIG. 59 is a diagram showing the first opening/closing member 80 arranged at the maximum open position. FIG. 60 shows the second opening/closing member 90 in the closed position. FIG. 61 is a diagram showing the second opening/closing member 90 arranged at the minimum open position. FIG. 62 is a diagram showing the second opening/closing member 90 arranged at the maximum open position.
The saucer unit SU is arranged below the transparent plates g1 and g2.
The receiving tray unit SU includes a receiving tray capable of storing game balls (rental balls/prize balls) paid out by a game ball payout device 440, which will be described later. In this embodiment, the tray includes two trays (upper tray 8 and lower tray 9).
Here, when the number of game balls stored in the upper tray 8 has not reached a predetermined number (when the upper tray 8 is not full), the game balls paid out by the game ball dispensing device 440 flow into the upper tray 8, and when the number of game balls stored in the upper tray 8 has reached a predetermined number (when the upper tray 8 is full), the game balls paid out by the game ball dispensing device 440 flow into the lower tray 9. do.

The upper receiving plate 8 is formed in a dish shape with an open upper surface. The bottom surface of the upper receiving plate 8 extends along the left-right direction. The bottom surface of the upper receiving plate 8 is inclined so that the left side is higher and the right side is lower when viewed from the front side. As a result, the game balls that have flowed into the upper tray 8 flow down the bottom surface of the upper tray 8 from left to right. In the following description, the left side of the upper receiving tray 8 is defined as the 'upstream side' of the path along which the game balls flow, and the right side of the upper receiving tray 8 is defined as the 'downstream side' of the path along which the game balls flow. That is, the game ball that has flowed into the upper receiving tray 8 from a first payout hole 8a, which will be described later, flows down the bottom surface of the upper receiving tray 8 from the upstream side toward the downstream side.
A first discharge hole 8a and a first discharge hole 8b are provided in the wall surface of the upper tray 8 on the back side.
The first payout hole 8a is provided at the upstream end of the upper tray 8 (the upstream end of the path along which the game ball flows down). The game balls paid out by the game ball payout device 440 flow into the upper receiving tray 8 from the first payout hole 8a.
The first discharge hole 8b is provided at the downstream end of the upper tray 8 (the downstream end of the path along which the game ball flows). The game balls stored in the upper tray 8 can be discharged out of the upper tray 8 through the first discharge holes 8b. Specifically, the first discharge hole 8b is connected to a second discharge hole 9a, which will be described later, via a guideway (not shown) provided on the back side of the upper tray 8. As shown in FIG. As a result, the game ball discharged from the first discharge hole 8b passes through the guide path and flows into the lower tray 9 from the second discharge hole 9a. Thereby, it is possible to discharge the game ball from the upper tray 8 to the lower tray 9 through the first discharge hole 8b.
In particular, the first discharge hole 8b is configured to have dimensions that allow game balls to pass through (discharge) one by one. In other words, the first discharge hole 8b is configured with dimensions that make it impossible to pass (discharge) two or more game balls at the same time. In this embodiment, the inner diameter of the first discharge hole 8b is 14 [mm].

As shown in FIGS. 57 to 59, a first opening/closing member 80 capable of opening and closing the first discharge hole 8b is provided on the back side of the upper tray 8. As shown in FIGS. Here, FIGS. 57 to 59 show the state of the upper receiving tray 8 viewed from the rear side (that is, the state of the first discharge hole 8b viewed from the rear side).
The first opening/closing member 80 is an opening/closing member that is opened and closed non-electrically (manually) without using an actuator. The first opening/closing member 80 includes a body portion 81 , an opening/closing piece portion 82 and a connection portion 83 .
The body portion 81 is formed in a plate shape extending in the left-right direction. The body portion 81 is provided with two guide holes 81a arranged in the left-right direction. Each guide hole 81a is a through hole penetrating along the depth direction. Each guide hole 81a is provided to have a predetermined length along the left-right direction. In addition, mechanical ends 8c corresponding to the respective guide holes 81a are provided on the rear surface of the upper receiving plate 8. As shown in FIG. Each mechanical end 8c is formed in a cylindrical shape and is provided so as to protrude from the rear surface of the upper receiving plate 8 toward the rear surface side. A mechanical end 8c corresponding to the guide hole 81a is inserted into each guide hole 81a.
The opening/closing piece 82 is formed in a bar shape extending in the left-right direction. The opening/closing piece portion 82 is provided so as to protrude rightward from the right end of the main body portion 81 .
The connecting portion 83 is provided so as to protrude leftward from the left end of the body portion 81 . The connecting portion 83 is provided with a connecting hole 83a. The connecting hole 83a is a through hole penetrating along the depth direction. The connecting hole 83a is provided to have a predetermined length along the vertical direction. An output shaft 88d, which will be described later, is inserted into the connecting hole 83a.

The first opening/closing member 80 is arranged on the left side of the first discharge hole 8b when viewed from the rear side. The first opening/closing member 80 can be displaced in the left-right direction within a range from the closed position (see FIG. 57) to the maximum open position (see FIG. 59).
When the first opening/closing member 80 is arranged at the closed position, the first discharge hole 8b is closed by the opening/closing piece 82, and the game ball cannot pass through the first discharge hole 8b.
When the first opening/closing member 80 is displaced from the closed position toward the left (maximum open position side), the closing of the first discharge hole 8b by the opening/closing piece 82 is gradually released, and the first discharge hole 8b is gradually opened. At this time, when the first opening/closing member 80 is arranged at the minimum open position (see FIG. 58), the opening width of the first discharge hole 8b becomes substantially the same as the diameter of the game ball, and the game ball can pass through the first discharge hole 8b. Then, when the first opening/closing member 80 is arranged at the maximum open position, the entire first discharge hole 8b is opened.
That is, when the first opening/closing member 80 is arranged on the right side (closed position side) of the minimum open position as viewed from the rear side, it becomes impossible for the game ball to pass through the first discharge hole 8b. On the other hand, when the first opening/closing member 80 is arranged on the left side of the minimum open position (maximum open position side) as viewed from the back side, it becomes possible for the game ball to pass through the first discharge hole 8b. As a result, the first opening/closing member 80 is arranged at the minimum open position, so that the minimum opening width that enables passage (discharging) of game balls is ensured as the opening width of the first discharge hole 8b.

A first ball release button 85 is provided on the side of the upper tray 8 . The first ball eject button 85 includes an operation portion 85a and a pushing piece portion 85b.
The operation portion 85a is formed in a substantially rectangular parallelepiped shape. The pushing piece 85b is formed in a bar shape. The pushing piece portion 85b is fixed to the bottom surface of the operation portion 85a. At this time, the pushing piece portion 85b is provided so as to extend downward from the bottom surface of the operating portion 85a.
The first ball eject button 85 is arranged such that the operating portion 85a protrudes upward from the upper surface of the tray unit SU. The first ball ejection button 85 can be operated by the player. Specifically, the first ball eject button 85 is provided so as to be displaceable along the vertical direction. The player can displace the first ball extraction button 85 in the upward direction by pushing the operation portion 85a downward. In particular, the player can displace the lower end portion of the push-in piece 85b downward by pushing the operation portion 85a downward.
The first ball eject button 85 can be vertically displaced (performs a pushing operation) within a range from the initial position (see FIG. 57) to the lowest position (see FIG. 59).

The first ball release button 85 is connected to the first opening/closing member 80 via a bellcrank (direction changing mechanism) 88 . As a result, the vertical displacement of the first ball eject button 85 can be converted into the horizontal displacement of the first opening/closing member 80 .
The bellcrank 88 includes an input side crank arm 88a, an output side crank arm 88b, and a rotating shaft 88c. Each crank arm 88a, 88b is formed like a rod. The bell crank 88 is configured by connecting an input side crank arm 88a and an output side crank arm 88b in a substantially "<" shape (boomerang shape). The input side crank arm 88a and the output side crank arm 88b are connected at a predetermined angle (eg, 90°). Further, in the bellcrank 88, a rotary shaft 88c is provided at the connecting portion between the input side crank arm 88a and the output side crank arm 88b.
In particular, in the bellcrank 88, the length of the output side crank arm 88b is longer than the length of the input side crank arm 88a. This makes it possible to increase the ratio of the amount of displacement (movement) of the first opening/closing member 80 to the amount of operation of the first ball extraction button 85 .

The rotating shaft 88c is arranged to extend along the depth direction. The bellcrank 88 is configured to be rotatable about a rotating shaft 88c.
The input-side crank arm 88a is arranged to extend substantially in the left-right direction. As a result, the tip of the input side clamp arm 88a is displaced in the vertical direction as the bell clamp 88 rotates.
The output side crank arm 88b is arranged to extend substantially along the vertical direction. As a result, the position of the tip of the output side clamp arm 88b is displaced in the left-right direction as the bell clamp 88 rotates. An output shaft 88d is provided at the tip of the output side crank arm 88b. The output shaft 88d is arranged to extend along the depth direction.

The lower end of the pushing piece 85b is arranged so as to contact the upper surface of the tip of the input-side clamp arm 88a. An output shaft 88d provided at the tip of the output-side crank arm 88b is inserted into a connecting hole 83a provided at the left end of the first opening/closing member 80. As shown in FIG. Furthermore, the first opening/closing member 80 is biased toward the right side (closed position side) as viewed from the rear side by the coil spring sp.
As a result, when the operation portion 85a of the first ball removal button 85 is not operated, the first opening/closing member 80 is arranged at the closed position and the first ball removal button 85 is arranged at the initial position. Therefore, the game balls cannot pass through the first discharge hole 8b, and the game balls stored in the upper tray 8 are not discharged.
Specifically, when the operation portion 85a of the first ball extracting button 85 is not operated, the coil spring sp biases the first opening/closing member 80 toward the right side (closed position side) as viewed from the rear side, and the left inner surface of each guide hole 81a contacts the mechanical end 8c. As a result, the displacement (displacement to the right) of the first opening/closing member 80 is restricted (prevented) by the mechanical ends 8c, and the position of the first opening/closing member 80 is maintained at the closed position. In addition, as the first opening/closing member 80 is disengaged toward the right side (closed position side) as viewed from the rear side, the tip of the output side crank arm 88b is pulled rightward, the bell crank 88 rotates counterclockwise, and the tip of the input side crank arm 88a pushes the pushing piece 85b upward. As a result, the first ball release button 85 is arranged at the initial position.

When the operation part 85a is pushed downward from the state where the first ball removal button 85 is arranged at the initial position, the first opening/closing member 80 is displaced from the closed position toward the left side (maximum open position side) as viewed from the rear side. At this time, the larger the amount of operation (the amount of pushing) of the operating portion 85a, the larger the amount of displacement of the first opening/closing member 80, and as a result, the larger the amount of opening (opening width) of the first discharge hole 8b.
Specifically, when the operation portion 85a is pushed downward from the state where the first ball eject button 85 is arranged at the initial position, the lower end of the pushing piece portion 85b pushes down the tip portion of the input side crank arm 88a. As a result, the bellcrank 88 rotates clockwise when viewed from the rear side, the tip of the output-side crank arm 88b moves leftward, and the output shaft 88d provided at the tip of the output-side crank arm 88b pulls the first opening/closing member 80 leftward (toward the maximum open position). As a result, the first opening/closing member 80 is displaced from the closed position toward the left side (toward the maximum open position), and the closure of the first discharge hole 8b by the opening/closing piece 82 is released.
When the first opening/closing member 80 is displaced to the minimum open position by pushing the operation part 85a, the game balls can pass through the first discharge hole 8b, and the game balls stored in the upper tray 8 are discharged from the first discharge hole 8b. Here, in the following description, the position of the first ball extraction button 85 when the first opening/closing member 80 is arranged at the minimum open position is referred to as "specific position". That is, when the first ball ejection button 85 is arranged at a specific position by pushing the operation portion 85a, the first opening/closing member 80 is arranged at the minimum open position, and the game balls can pass through the first discharge hole 8b, and the game balls stored in the upper tray 8 are discharged from the first discharge hole 8b.
As a result, when the first ball ejection button 85 is arranged above the specific position (initial position side), it becomes impossible for the game ball to pass through the first discharge hole 8b. On the other hand, when the first ball ejection button 85 is arranged below the specific position (lowermost position side), it becomes possible for the game ball to pass through the first discharge hole 8b. As a result, the first ball ejection button 85 is arranged (pushed in) at a specific position, so that the minimum opening width that allows the passage (ejection) of the game ball is secured as the opening width of the first discharge hole 8b.

Furthermore, when the first ball release button 85 is pushed to the lowest position, the first opening/closing member 80 is arranged at the maximum open position. That is, when the first ball release button 85 is pushed to the lowest position, the inner surface on the right side of each guide hole 81a comes into contact with the mechanical end 8c as viewed from the rear side. As a result, the displacement (leftward displacement) of the first opening/closing member 80 is restricted (prevented) by each mechanical end 8c, the displacement (leftward displacement) of the first opening/closing member 80 is controlled to the maximum closed position, and accordingly the displacement (downward displacement) of the first ball extraction button 85 is limited to the lowest position.
Then, when the pushing operation part 85a is stopped from the state where the first ball extracting button 85 is arranged at the lowest position, the first opening/closing member 80 is returned to the closed position and the first ball extracting button 85 is returned to the initial position due to the depressing force of the coil spring sp.
As described above, the player can discharge the game balls stored in the upper receiving tray 8 to the lower receiving tray 9 through the first discharge hole 8b by pressing the first ball ejection button 85 (operation portion 85a).

The lower receiving plate 9 is formed in a dish shape with an open upper surface. The bottom surface of the lower receiving plate 9 extends along the left-right direction. The bottom surface of the lower receiving plate 9 is inclined so that the left side is higher and the right side is lower when viewed from the front side. As a result, the game balls flowed into the lower receiving tray 9 flow down the bottom surface of the lower receiving tray 9 from left to right. In the following description, when viewed from the front side, the left side of the lower receiving tray 9 is defined as the 'upstream side' of the path along which the game ball flows, and the right side of the lower receiving tray 9 is defined as the 'downstream side' of the path along which the game ball flows. That is, the game ball that has flowed into the lower receiving tray 9 from a second payout hole 9a described later flows down the bottom surface of the lower receiving tray 9 from the upstream side toward the downstream side.
A wall surface on the back side of the lower tray 9 is provided with a second dispensing hole 9a. Further, the bottom surface of the lower receiving plate 9 is provided with a second discharge hole 9b.
The second payout hole 9a is provided at the upstream end of the lower tray 9 (the upstream end of the path along which the game ball flows down). The game balls paid out by the game ball payout device 440 (when the upper receiving tray 8 is full) and the game balls discharged from the first discharging hole 8b flow into the lower receiving tray 9 from the second paying-out hole 9a.
The second discharge hole 9b is provided at the downstream end of the lower tray 9 (the downstream end of the path along which the game ball flows). The game balls stored in the lower receiving tray 9 can be discharged out of the lower receiving tray 9 through the second discharge holes 9b. In this embodiment, the game balls stored in the lower tray 9 can be discharged from the second discharge hole 9b to the outside of the pachinko machine 1 (specifically, the dollar box placed below the lower tray 9). The game balls stored in the lower receiving tray 9 may be discharged from the second discharge hole 9b to the inside of the pachinko machine 1 (for example, a counting device for counting game balls).
In particular, the dimensions of the second discharge holes 9b are larger than the dimensions of the first discharge holes 8b. As a result, the second discharge hole 9b allows more game balls to pass through at the same time than the first discharge hole 8b. In other words, the number of game balls that can pass through the second discharge hole 9b at the same time is greater than the number of game balls that can pass through the first discharge hole 8b at the same time. Specifically, the second discharge hole 9b is configured to have dimensions that allow two or more (in this embodiment, five) game balls to pass through (discharge) at the same time. In this embodiment, the inner diameter of the second discharge hole 9b is 25 [mm].

As shown in FIGS. 60 to 62, the bottom surface of the lower tray 9 is provided with a second opening/closing member 90 capable of opening and closing the second discharge hole 9b. Here, FIGS. 60 to 62 show the state of the lower receiving tray 9 viewed from below (bottom side) (that is, the state of the second discharge hole 8b viewed from below (bottom side)).
The second opening/closing member 90 is an opening/closing member that is opened and closed non-electrically (manually) without using an actuator. The second opening/closing member 90 includes a disk-shaped opening/closing plate portion 91 . The second opening/closing member 90 can be displaced in the left-right direction within a range from the closed position (see FIG. 60) to the maximum open position (see FIG. 62).
When the second opening/closing member 90 is arranged at the closed position, the second discharge hole 9b is entirely closed by the opening/closing plate portion 91, making it impossible for the game ball to pass through the second discharge hole 9b.
When the second opening/closing member 90 is displaced from the closed position toward the maximum open position, the closing of the second discharge hole 9b by the opening/closing plate portion 91 is gradually released, and the second discharge hole 9b is gradually opened. At this time, when the second opening/closing member 90 is arranged at the minimum open position (see FIG. 61), the opening width of the second discharge hole 9b becomes substantially the same as the diameter of the game ball, and the game ball can pass through the second discharge hole 9b. In particular, when the second opening/closing member 90 is arranged at the minimum open position, it becomes possible to pass (discharge) game balls one by one from the second discharge hole 9b. Then, when the second opening/closing member 90 is arranged at the maximum open position, the entire second discharge hole 9b is opened. In particular, when the second opening/closing member 90 is arranged at the maximum open position, it becomes possible to simultaneously pass (discharge) two or more game balls (five balls in this embodiment) from the second discharge hole 9b.
In other words, when the second opening/closing member 90 is arranged closer to the closed position than the minimum open position, it becomes impossible for the game ball to pass through the second discharge hole 9b. On the other hand, when the second opening/closing member 90 is arranged from the minimum open position to the maximum open position, it becomes possible for the game ball to pass through the second discharge hole 9b. As a result, the second opening/closing member 90 is arranged at the minimum open position, so that the minimum opening width that enables passage (discharging) of game balls is secured as the opening width of the second discharge hole 9b.

A second ball release button 95 is provided on the front surface of the lower tray 9 . The second ball eject button 95 includes an operating portion 95a formed in a strip shape.
The second ball eject button 95 is arranged such that the operation portion 95a protrudes from the front surface of the lower tray 9 toward the front side. The second ball ejection button 95 can be operated by the player. Specifically, the second ball eject button 95 is provided so as to be displaceable along the depth direction. The player can displace the second ball extraction button 95 along the depth direction by pushing the operation portion 95a toward the depth side.
The second ball eject button 95 can be displaced (performed a pushing operation) along the depth direction within a range from the initial position (see FIG. 60) to the lowest position (see FIG. 62).

The second ball release button 95 is connected to the second opening/closing member 90 via a direction changing mechanism (not shown). As a result, the displacement of the second ball eject button 95 along the depth direction can be converted into the displacement of the second opening/closing member 90 along the left-right direction.
The second opening/closing member 90 is biased toward the right side (closed position side) as viewed from below by biasing means (not shown) such as a coil spring. As a result, when the operating portion 95a of the second ball removal button 95 is not operated, the second opening/closing member 90 is arranged at the closed position and the second ball removal button 95 is arranged at the initial position. Therefore, the game balls cannot pass through the second discharge hole 9b, and the game balls stored in the lower receiving tray 9 are not discharged.
When the operation part 95a is pushed inward from the state where the second ball extraction button 95 is arranged at the initial position, the second opening/closing member 90 is displaced from the closed position toward the left side (maximum open position side) when viewed from below. At this time, as the operation amount (push amount) of the operation portion 95a increases, the displacement amount of the second opening/closing member 90 increases, and as a result, the opening amount (open width) of the second discharge hole 9b increases.
When the second opening/closing member 90 is displaced to the minimum open position by pushing the operation part 95a, the game balls can pass through the second discharge hole 9b, and the game balls stored in the lower tray 9 are discharged from the second discharge hole 9b. Here, in the following description, the position of the second ball extraction button 95 when the second opening/closing member 90 is arranged at the minimum open position is referred to as "specific position". That is, when the second ball ejection button 95 is arranged at a specific position by pushing the operation part 95a, the second opening/closing member 90 is arranged at the minimum open position, the game balls can pass through the second discharge hole 9b, and the game balls stored in the lower receiving tray 9 are discharged from the second discharge hole 9b.
As a result, when the second ball extraction button 95 is arranged on the front side (initial position side) of the specific position, it becomes impossible for the game ball to pass through the second discharge hole 9b. On the other hand, when the second ball ejection button 95 is arranged on the back side (lowest position side) from the specific position, it becomes possible for the game ball to pass through the second discharge hole 9b. As a result, the second ball ejection button 95 is arranged (pushed in) at a specific position, so that the minimum opening width that allows the passage (ejection) of the game ball is secured as the opening width of the second discharge hole 9b.
Furthermore, when the second ball release button 95 is pushed to the lowest position, the second opening/closing member 90 is arranged at the maximum open position. As a result, the entire second discharge hole 9b is opened, and two or more game balls (five balls in this embodiment) can be discharged from the second discharge hole 9b at the same time.
When the push-in of the operation part 95a is stopped from the state where the second ball extracting button 95 is arranged at the lowest position, the second opening/closing member 90 is returned to the closed position and the second ball extracting button 95 is returned to the initial position due to the depressing force of the depressing means.
As described above, the player can discharge the game balls stored in the lower receiving tray 9 to the outside of the pachinko machine 1 (specifically, the dollar box placed below the lower receiving tray 9) through the second discharge hole 9b by pushing the second ball ejection button 95 (operation portion 95a).

In particular, in this embodiment, the dimensions of the second discharge holes 9b are larger than the dimensions of the first discharge holes 8b. That is, the second discharge hole 9b is capable of allowing more game balls to pass through (discharge) at the same time than the first discharge hole 8b. Thus, when an abnormal state (hereinafter referred to as a ``full-tank error'') occurs in which the trays (upper tray 8 and lower tray 9) are full of game balls and the game balls put out by the game ball putting-out device 440 cannot be sent to the tray, the full-fill error can be quickly canceled.
Further, in the present embodiment, the first ball ejection button 85 can be put into a state in which the game ball can pass through the first discharge hole 8b (a state in which the game ball can be discharged from the first discharge hole 8b) by an operation amount equal to or less than (less than) the diameter of the game ball (about 11 [mm]).
Specifically, the first ball ejection button 85 can be put into a state in which the game ball can pass through the first ejection hole 8b (a state in which the game ball can be ejected from the first ejection hole 8b) with an operation amount of 4 [mm].
That is, the operation amount for displacing the first ball eject button 85 from the initial position to the specific position is 4 [mm]. In other words, the first ball ejection button 85 can be arranged at a specific position by pushing it 4 [mm] from the initial position.
As a result, the game ball can be discharged from the upper receiving tray 8 with a small amount of operation.
In addition, in the present embodiment, the second ball eject button 95 can be put in a state in which the game ball can pass through the second ejection hole 9b (a state in which the game ball can be ejected from the second ejection hole 9b) by an operation amount equal to or less than (less than) the diameter of the game ball.
In particular, the second ball ejection button 95 can be put into a state in which the game ball can pass through the second ejection hole 9b (a state in which the game ball can be ejected from the second ejection hole 9b) with an operation amount smaller than the operation amount of the first ball ejection button 85 required to enable the game ball to be ejected from the first ejection hole 8b. In other words, the operation amount (minimum operation amount) of the second ball ejection button 95 required to allow the game ball to pass through the second ejection hole 9b (the state in which the game ball can be ejected from the second ejection hole 9b) is smaller than the operation amount (minimum operation amount) of the first ball ejection button 85 required to bring the game ball into the state in which the game ball can pass through the first ejection hole 8b (the state in which the game ball can be ejected from the first ejection hole 8b).
Specifically, the second ball ejection button 95 can be put into a state in which the game ball can pass through the second ejection hole 9b (a state in which the game ball can be ejected from the second ejection hole 9b) with an operation amount of 3 [mm].
That is, the operation amount for displacing the second ball eject button 95 from the initial position to the specific position is 3 [mm]. In other words, the second ball ejection button 95 can be arranged at a specific position by pushing it 3 [mm] from the initial position. In particular, "the operation amount for displacing the second ball eject button 95 from the initial position to the specific position"<"the operation amount for displacing the first ball eject button 85 from the initial position to the specific position".
As a result, the game ball can be ejected from the lower receiving tray 9 with a small amount of operation. In particular, when the player is required to quickly remove the ball from the receiving tray, such as when a full tank error occurs, it is possible to prompt the player to operate the second ball removal button 95 that enables efficient ball removal.

In addition, in the present embodiment, the second ball ejection button 95 can be put into a state in which the game ball can pass through the second ejection hole 9b (a state in which the game ball can be ejected from the second ejection hole 9b) with an operation load smaller than the operation load of the first ball ejection button 85 that is required to enable the game ball to be ejected from the first ejection hole 8b. In other words, the operation load (minimum operation load) of the second ball ejection button 95 required to allow the game ball to pass through the second ejection hole 9b (the state to allow the game ball to be ejected from the second ejection hole 9b) is smaller than the operation load (minimum operation load) of the first ball ejection button 85 required to allow the game ball to pass through the first ejection hole 8b (the state to allow the game ball to be ejected from the first ejection hole 8b).
Specifically, with an operation load of 4 [N], the first ball ejection button 85 can be put into a state in which the game ball can pass through the first ejection hole 8b (a state in which the game ball can be ejected from the first ejection hole 8b).
That is, the operation load required to displace the first ball eject button 85 from the initial position to the specific position is 4 [N]. In other words, the first ball eject button 85 arranged at the initial position can be arranged at a specific position by pushing it with a force of 4 [N].
On the other hand, for the second ball ejection button 95, an operation load of 2[N] enables a state in which the game ball can pass through the second ejection hole 9b (a state in which the game ball can be ejected from the second ejection hole 9b).
That is, the operation load required to displace the second ball eject button 95 from the initial position to the specific position is 2 [N]. In other words, the second ball eject button 95 arranged at the initial position can be arranged at a specific position by pushing it with a force of 2 [N]. In particular, "the operation load required to displace the second ball eject button 95 from the initial position to the specific position"<"the operation load required to displace the first ball eject button 85 from the initial position to the specific position".
As a result, the ball can be removed from the second ball removal button 95 with an operation load smaller than that of the first ball removal button 85 . Therefore, when the player is required to quickly remove the ball from the receiving tray, such as when a full tank error occurs, it is possible to prompt the player to operate the second ball removal button 95 that enables efficient ball removal.

Further, in this embodiment, the maximum operation amount of the second ball removal button 95 is larger than the maximum operation amount of the first ball removal button 85 . That is, the operation amount of the second ball ejection button 95 required to open the second ejection hole 9b to the upper limit (maximum) is greater than the operation amount of the first ball ejection button 85 required to open the first ejection hole 8b to the upper limit (maximum).
That is, the operation amount (maximum operation amount) for displacing the first ball extraction button 85 from the initial position to the lowest position is equal to or less than (less than) the diameter of the game ball. Specifically, the operation amount (maximum operation amount) for displacing the first ball eject button 85 from the initial position to the lowest position is 6 [mm]. In other words, the first ball eject button 85 can be placed at the lowest position by pushing it 6 [mm] from the initial position.
On the other hand, the operation amount (maximum operation amount) for displacing the second ball extraction button 95 from the initial position to the lowest position is equal to or larger than the diameter of the game ball (excess). Specifically, the operation amount (maximum operation amount) for displacing the second ball eject button 95 from the initial position to the lowest position is 14.5 [mm]. In other words, the second ball eject button 95 can be placed at the lowest position by pushing it 14.5 [mm] from the initial position. In particular, "the operation amount (maximum operation amount) for displacing the second ball eject button 95 from the initial position to the lowest position">"the operation amount (maximum operation amount) for displacing the first ball eject button 85 from the initial position to the lowest position".
As a result, of the two ball ejection buttons (first ball ejection button 85 and second ball ejection button 95), the ball ejection button (second ball ejection button 95) having a larger maximum operation amount becomes a ball ejection button with high ejection efficiency of game balls. Therefore, the player can intuitively select the ball removal by the second ball removal button 95 when a quick ball removal from the receiving tray is required, such as when a full tank error occurs.

In addition, the tray unit SU includes various operating means that can be operated by the player.
In this embodiment, various operation means include a production button 5b, a rotary selector 5c, a light amount adjustment button (not shown), a volume adjustment button (not shown), a cross key button (not shown), and the like.
The effect button 5b includes an operation section that can be pressed by the player, and a button switch 25 (see FIG. 3) that detects the pressing operation of the operation section. The button switch 25 outputs a detection signal to the effect control board 300 (see FIG. 3) each time the operation unit is pressed.
The rotary selector 5c (so-called "jog dial") includes an operating section that can be rotated by the player, and a dial switch 26 (see FIG. 3) that detects the rotating operation of the operating section. The dial switch 26 outputs a detection signal to the effect control board 300 each time the operating portion is rotated by a predetermined angle (for example, 60[°]).

The light amount adjustment button includes two operation sections (first operation section and second operation section) that can be pressed by the player, and a light amount adjustment switch 27 (see FIG. 3) that detects the pressing operation of each operation section. The light amount adjustment switch 27 outputs a first detection signal to the performance control board 300 every time the first operation part is pressed down, and outputs a second detection signal to the performance control board 300 every time the second operation part is pressed down.
The volume adjustment button includes two operation units (first operation unit and second operation unit) that can be pressed by the player, and a volume adjustment switch 28 (see FIG. 3) that detects the pressing operation of each operation unit. The sound volume adjustment switch 28 outputs a first detection signal to the performance control board 300 every time the first operation part is pressed down, and outputs a second detection signal to the performance control board 300 every time the second operation part is pressed down.
The cross key button includes four operation units (up key button, down key button, left key button, and right key button) that can be pressed by the player, and a cross key switch 29 (see FIG. 3) that detects the pressing operation of each operation unit. The cross key switch 29 outputs a first detection signal to the performance control board 300 each time the up key button is pressed, outputs a second detection signal to the performance control board 300 each time the down key button is pressed, outputs a third detection signal to the performance control board 300 each time the left key button is pressed, and outputs a fourth detection signal to the performance control board 300 each time the right key button is pressed.

Further, a lending operation section 7 is arranged on the upper surface of the receiving tray unit SU. The rental operation unit 7 has a ball rental button 7a, a return button 7b, and a frequency display device 7c.
Here, the pachinko machine 1 is communicably connected to a CR unit 700 capable of reading and updating information recorded on the prepaid card. Then, when a prepaid card (not shown) is inserted into the CR unit 700, the remaining credits of the valuable medium recorded on the prepaid card inserted in the CR unit 700 are displayed on the count display device 7c.
Further, when the ball lending button 7a is operated while the prepaid card is inserted in the CR unit 700, a predetermined number of game balls are paid out to the upper receiving tray 8.例文帳に追加At this time, the remaining frequency of the valuable medium recorded in the prepaid card is updated according to the number of game balls paid out, and the updated remaining frequency of the valuable medium is displayed on the frequency display device 7c.
Furthermore, when the return button 7b is operated while the prepaid card with the remaining credits of the valuable medium is inserted in the CR unit 700, the prepaid card is returned from the CR unit 700. FIG.
Here, the prepaid cart includes, for example, a magnetic storage medium, a storage IC built-in medium, and the like.

(Execution of production according to the type of decoration unit DU/receptacle unit SU)
Next, the execution of the effect according to the type of the decoration unit DU/receptacle unit SU attached to the main body of the game machine will be described.
In this embodiment, of the configuration of the pachinko machine 1, the gaming machine body (outer frame unit 2, body frame unit (inner frame unit 3 and front frame unit 4), etc.) is commonly used for a plurality of different models.
On the other hand, among the configurations of the pachinko machine 1, the game board unit 10, the decoration unit DU, the tray unit SU, etc., which are mounted on the main body of the game machine, are individually prepared for a plurality of models (different models). That is, the game board unit 10, decoration unit DU, tray unit SU and the like are used exclusively for each model.
For example, when "model A", "model B", "model C" and "model D" are manufactured as the models (types) of the pachinko machine 1, "model A", "model B", "model C" and "model D" can be used in common for the gaming machine main body.
On the other hand, the game board unit 10, decoration unit DU, receiving tray unit SU, etc. are prepared for "model A", "model B", "model C" and "model D".
That is, as the game board unit 10, a "game board unit A" corresponding to the "model A", a "game board unit B" corresponding to the "model B", a "game board unit C" corresponding to the "model C", and a "game board unit D" corresponding to the "model D" are prepared.
As decoration units DU, a ``decoration unit A'' corresponding to ``model A'', a ``decoration unit B'' corresponding to ``model B'', a ``decoration unit C'' corresponding to ``model C'', and a ``decoration unit D'' corresponding to ``model D'' are prepared.
Further, as the receiving tray unit SU, a ' receiving tray unit A' corresponding to the 'model A', a 'receiving tray unit B' corresponding to the 'model B', a 'receiving tray unit C' corresponding to the 'model C', and a 'receiving tray unit D' corresponding to the 'model D' are prepared.
In the pachinko machine 1 corresponding to the 'model A', a 'game board unit A', a 'decoration unit A' and a 'receptacle unit A' are mounted on a game machine main body common to 'model A', 'model B', 'model C' and 'model D'.
On the other hand, in the pachinko machine 1 corresponding to the ``model B'', a ``game board unit B'', a ``decoration unit B'' and a ``receiving tray unit B'' are mounted on the game machine body common to the ``model A'', the ``model B'', the ``model C'' and the ``model D''.
On the other hand, in the pachinko machine 1 corresponding to the ``model C'', a ``game board unit C'', a ``decoration unit C'' and a ``receiving tray unit C'' are attached to the game machine body common to the ``model A'', ``model B'', ``model C'' and ``model D''.
On the other hand, in the pachinko machine 1 corresponding to the ``model D'', the ``game board unit D'', the ``decoration unit D'' and the ``receiving tray unit D'' are mounted on the game machine body common to the ``model A'', the ``model B'', the ``model C'' and the ``model D''.
It should be noted that at least one type of game board unit 10 may be configured to be commonly used for a plurality of models. Also, at least one type of decoration unit DU may be used in common for a plurality of models. Also, at least one type of receiving tray unit SU may be configured to be commonly used for a plurality of models.
For example, in a pachinko machine 1 corresponding to ``model E'', ``model E'' is set in addition to the above-mentioned models, and ``model A'', ``model B'', ``model C'' and ``model D'' may be configured to have a ``game board unit A'' common to ``model A'', a ``decoration unit B'' common to ``model B'', and a ``receiving tray unit C'' common to ``model C''.

In particular, the pachinko machine 1 includes detection means for detecting the type of the decoration unit DU attached to the main body of the game machine (specifically, the front frame unit 4) and detection means for detecting the type of the receiving tray unit SU attached to the main body of the game machine (specifically, the front frame unit 4).
Then, according to the type of the decoration unit DU detected by the detection means, the mode of the predetermined effect is changed. That is, as the mode of the predetermined effect, a mode corresponding to the type of the decoration unit DU detected by the detection means is set.
In addition, according to the type of the receiving tray unit SU detected by the detecting means, the mode of the predetermined effect is changed. That is, as the mode of the predetermined effect, a mode corresponding to the type of the receiving tray unit SU detected by the detection means is set.
In this embodiment, the mode of the "specific super reach variable effect" (specifically, the mode of the "specific advanced reach effect image") changes according to the type of the decoration unit DU detected by the detection means. That is, a mode corresponding to the type of the decoration unit DU detected by the detection means is set as the mode of the "specific super reach variable effect" (specifically, the mode of the "specific extended reach effect image").
Further, the form of the "button notice effect" (specifically, the form of the "button notice effect image") changes according to the type of the receiving tray unit SU detected by the detecting means. That is, a mode corresponding to the type of the receiving tray unit SU detected by the detecting means is set as the mode of the "button notice effect" (specifically, the mode of the "button notice effect image").

Specifically, the front frame unit 4 includes a decoration unit detection switch 35 and a tray unit detection switch 36 .
The decoration unit detection switch 35 includes four switch circuit portions sa, sb, sc, and sd. The switch circuit portions sa, sb, sc, and sd of each system are configured including contact portions. Then, the switch circuit units sa, sb, sc, and sd of each system output detection signals to the production control board 300 when the contact units are in the ON state (conducting state) (the detection signals input to the production control board 300 from the switch circuit units sa, sb, sc, and sd are set to high level). On the other hand, the switch circuit units sa, sb, sc, and sd of each system stop outputting the detection signal to the production control board 300 when the contact portion is in the OFF state (non-conducting state) (the detection signal input to the production control board 300 from the switch circuit units sa, sb, sc, and sd is set to low level).
The decoration unit DU is configured including a conductive piece. When the decoration unit DU is attached to the front frame unit 4, the conductive pieces can switch the contact portions of the switch circuit portions sa, sb, sc, and sd between ON and OFF states.
In particular, "decoration unit A", "decoration unit B", "decoration unit C", and "decoration unit D" differ in the configuration of the conducting piece (in this embodiment, the position where the conducting piece is provided). Thus, when the decoration unit DU is attached to the front frame unit 4, the pattern (combination) in which the contact parts of the four switch circuit parts sa, sb, sc, and sd are turned on or off is different for each type of the decoration unit DU.

Specifically, when the decoration unit DU is not attached to the front frame unit 4, the contact portions of all the switch circuit portions sa, sb, sc, and sd are turned off (non-conducting state).
In the "decorative unit A", a conductive piece is provided at a position corresponding to the switch circuit sa among the four switch circuit units sa, sb, sc, and sd. As a result, when the "decorative unit A" is attached to the front frame unit 4, the contact portions of the switch circuit portion sa of the four switch circuit portions sa, sb, sc, and sd are turned on (conducting state), and the contact portions of the other switch circuit portions sb, sc, and sd are turned off (non-conducting state).
On the other hand, in the "decorative unit B", among the four switch circuit portions sa, sb, sc, and sd, a conductive piece portion is provided at a position corresponding to the switch circuit portion sb. As a result, when the "decorative unit B" is attached to the front frame unit 4, the contact portion of the switch circuit portion sb among the four switch circuit portions sa, sb, sc, and sd is turned on (conducting state), and the contact portions of the other switch circuit portions sa, sc, and sd are turned off (non-conducting state).
On the other hand, in the "decorative unit C", among the four switch circuit portions sa, sb, sc, and sd, a conductive piece portion is provided at a position corresponding to the switch circuit portion sc. As a result, when the "decorative unit C" is attached to the front frame unit 4, the contact portion of the switch circuit portion sc among the four switch circuit portions sa, sb, sc, and sd is turned on (conducting state), and the contact portions of the other switch circuit portions sa, sb, and sd are turned off (non-conducting state).
On the other hand, in the "decorative unit D", among the four switch circuit portions sa, sb, sc, and sd, a conductive piece portion is provided at a position corresponding to the switch circuit portion sd. As a result, when the "decorative unit D" is attached to the front frame unit 4, the contact portions of the switch circuit portion sd of the four switch circuit portions sa, sb, sc, and sd are turned on (conducting state), and the contact portions of the other switch circuit portions sa, sb, and sc are turned off (non-conducting state).
It should be noted that the "decoration unit E" may be provided, and in the "decoration unit E", of the four switch circuit portions sa, sb, sc, and sd, conductive pieces may be provided at positions corresponding to the switch circuit portions sa and sb. As a result, when the "decorative unit E" is attached to the front frame unit 4, the contact portions of the switch circuit portions sa and sb of the four switch circuit portions sa, sb, sc, and sd are turned on (conducting state), and the contact portions of the other switch circuit portions sc and sd are turned off (non-conducting state).

The effect control board 300 is provided with input ports (not shown) corresponding to the switch circuit units sa, sb, sc, and sd of each system, and a reception storage area corresponding to each input port.
The detection signals output from the switch circuit units sa, sb, sc and sd are input to the input ports corresponding to the switch circuit units sa, sb, sc and sd. 1-bit data indicating the input state of the detection signal to the input port corresponding to the reception storage area is set in each reception storage area. That is, each reception storage area is set to "1" when the detection signal is input to the input port corresponding to the reception storage area (the input detection signal is high level), and is set to "0" when the detection signal is not input to the input port corresponding to the reception storage area (the input detection signal is low level).
In this embodiment, as input ports, an input port pa corresponding to the switch circuit portion sa, an input port pb corresponding to the switch circuit portion sb, an input port pc corresponding to the switch circuit portion sc, and an input port pd corresponding to the switch circuit portion sd are provided.
As reception storage areas, a reception storage area ma corresponding to the input port pa (switch circuit section sa), a reception storage area mb corresponding to the input port pb (switch circuit section sb), a reception storage area mc corresponding to the input port pc (switch circuit section sc), and a reception storage area md corresponding to the input port pd (switch circuit section sd) are provided.
When the contact portion of the switch circuit portion sa is in the off state (non-conducting state) (when the detection signal is at low level), "0" is set in the reception storage area ma, and when the contact portion of the switch circuit portion sa is in the on state (conducting state) (when the detection signal is at high level), "1" is set in the reception storage area ma.
When the contact portion of the switch circuit portion sb is in the off state (non-conducting state) (when the detection signal is at low level), "0" is set in the reception storage area mb, and when the contact portion of the switch circuit portion sb is in the on state (conducting state) (when the detection signal is at high level), "1" is set in the reception storage area mb.
Further, when the contact portion of the switch circuit portion sc is in the off state (non-conducting state) (when the detection signal is at low level), "0" is set in the reception storage area mc, and when the contact portion of the switch circuit portion sc is in the on state (conducting state) (when the detection signal is at high level), "1" is set in the reception storage area mc.
When the contact portion of the switch circuit portion sd is in the off state (non-conducting state) (when the detection signal is at low level), "0" is set in the reception storage area md, and when the contact portion of the switch circuit portion sd is in the on state (conducting state) (when the detection signal is at high level), "1" is set in the reception storage area md.

Thereby, the CPU 310 of the performance control board 300 can determine (determine/identify) whether or not the decoration unit DU is attached to the front frame unit 4 and the type of the decoration unit DU attached to the front frame unit 4 based on the 4-bit data stored in the four reception storage areas ma, mb, mc, and md.
That is, when "0" is stored in all the reception storage areas ma, mb, mc, and md, it is determined that the decoration unit DU is not attached to the front frame unit 4 (the attachment of the decoration unit DU to the front frame unit 4 is incomplete).
On the other hand, when "1" is set in the reception storage area ma and "0" is set in the other reception storage areas mb, mc and md among the four reception storage areas ma, mb, mc and md, it is determined that the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit A".
On the other hand, when "1" is set in the reception storage area mb among the four reception storage areas ma, mb, mc and md and "0" is set in the other reception storage areas ma, mc and md, it is determined that the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit B".
On the other hand, when "1" is set in the reception storage area mc among the four reception storage areas ma, mb, mc, md and "0" is set in the other reception storage areas ma, mb, md, it is determined that the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit C".
On the other hand, when "1" is set in the reception storage area md among the four reception storage areas ma, mb, mc, md and "0" is set in the other reception storage areas ma, mb, mc, it is determined that the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit D".
When the above-mentioned "decorative unit E" is provided, among the four receiving storage areas ma, mb, mc, and md, "1" is set in the receiving storage areas ma, mb, and when "0" is set in the other receiving storage areas mc, md, it is determined that the type of the decoration unit DU attached to the front frame unit 4 is the "decorating unit E".

The DRAM 304 of the effect control board 300 is provided with a first material replacement offset storage area. A first material replacement offset value (one of "0" to "3") is stored (set) in the first material replacement offset storage area.
In the material replacement offset setting process (step S28-2) executed when the power is turned on, the CPU 310 of the effect control board 300 acquires 4-bit data (hereinafter referred to as "first model determination bit data") stored in the four reception storage areas ma, mb, mc, and md, determines the type of the decoration unit DU attached to the front frame unit 4 based on the acquired first model determination bit data, and determines the first material corresponding to the determined type of the decoration unit DU. A replacement offset value is stored in a first material replacement offset storage area.
At this time, when it is determined that the type of the decoration unit DU attached to the front frame unit 4 is "decorative unit A", "0" is stored in the first material replacement offset storage area, "1" is stored in the first material replacement offset storage area when it is determined that the type of the decoration unit DU attached to the front frame unit 4 is "decorative unit B", and when it is determined that the type of the decoration unit DU attached to the front frame unit 4 is "decorative unit C", the first material replacement offset. "2" is stored in the storage area, and "3" is stored in the first material replacement offset storage area when it is determined that the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit D".

The CGROM 303 stores, as image data (compressed image data) of the "specific developed reach effect image", "specific developed reach effect image data A" corresponding to the "decoration unit A", "specific developed reach effect image data B" corresponding to the "decoration unit B", "specific developed reach effect image data C" corresponding to the "decoration unit C", and "specific developed reach effect image data D" corresponding to the "decoration unit D".
Here, "decorative unit A", "decorative unit B", "decorative unit C" and "decorative unit D" differ in the shape (appearance, configuration, type) of the speaker 22 . The image data of the ``specific developed reach effect image'' corresponding to each type of decoration unit DU includes display of an image simulating the shape of the speaker 22 provided in the type of decoration unit DU.
That is, the "specific developed reach effect image data A" includes display of an image simulating the speaker 22 provided in the "decoration unit A". Further, the "specific advanced reach effect image data B" includes display of an image simulating the speaker 22 provided in the "decoration unit B". Further, the "specific developed reach effect image data C" includes display of an image simulating the speaker 22 provided in the "decoration unit C". Further, the "specific developed reach effect image data D" includes display of an image simulating the speaker 22 provided in the "decoration unit D".
It should be noted that the shape (appearance) of the movable body unit may be different in "decoration unit A", "decoration unit B", "decoration unit C", and "decoration unit D". Then, "specific developed reach effect image data A" includes display of an image simulating the movable body unit provided in "decorative unit A", "specific developed reach effect image data B" includes display of an image simulating the movable body unit provided in "decorative unit B", "specific developed reach effect image data C" includes display of an image simulating the movable body unit provided in "decorative unit C", and "specific developed reach effect image data D" includes: A configuration including display of an image simulating the movable body unit provided in the “decorative unit D” may be employed.

The CPU 310 of the effect control board 300 acquires the first material replacement offset value stored in the first material replacement offset storage area when executing the "specific super reach variable effect". Then, image data corresponding to the acquired first material replacement offset value is set as the image data of the "specific advanced reach effect image".
At this time, when "0" is stored in the first material replacement offset storage area, "specific development reach effect image data A" is set, when "1" is stored in the first material replacement offset storage area, "specific development reach effect image data B" is set, when "2" is stored in the first material replacement offset storage area, "specific development reach effect image data C" is set, and when "3" is stored in the first material replacement offset storage area, " Specific developed reach effect image data D” is set.
As a result, a mode corresponding to the type of the decoration unit DU detected by the detection means is set as the mode of the "specific super reach variable effect" (specifically, the mode of the "specific advanced reach effect image").
That is, when the type of the decoration unit DU attached to the front frame unit 4 is the "decoration unit A", an image based on the "specific development reach performance image data A" is displayed as the "specific development reach performance image".
On the other hand, when the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit B", an image based on "specific development reach performance image data B" is displayed as the "specific development reach performance image".
On the other hand, when the type of the decoration unit DU attached to the front frame unit 4 is ``decoration unit C'', an image based on ``specific development reach performance image data C'' is displayed as the ``specific development reach performance image''.
On the other hand, when the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit D", an image based on "specific development reach performance image data D" is displayed as the "specific development reach performance image".

As described above, in the pachinko machine 1, the aspect of the ``specified super reach variable performance'' (specifically, the aspect of the ``specified extended reach performance image'') is automatically changed according to the type of the decoration unit DU attached to the front frame unit 4.例文帳に追加
Accordingly, it is not necessary to replace the image data stored in the CGROM 303 according to the type of the decoration unit DU attached to the front frame unit 4, and it is not necessary to change the control contents.
Therefore, it is possible to reduce the number of man-hours during manufacturing, and to suppress the occurrence of defects due to human error.

Similarly, the tray unit detection switch 36 includes four switch circuit sections se, sf, sg, and sh. The switch circuit sections se, sf, sg, and sh of each system are configured including contact sections. Then, the switch circuit units se, sf, sg, and sh of each system output detection signals to the production control board 300 when the contact units are in an ON state (conducting state) (the detection signals input to the production control board 300 from the switch circuit units se, sf, sg, and sh are set to a high level). On the other hand, the switch circuit units se, sf, sg, sh of each system stop outputting the detection signal to the production control board 300 when the contact part is in the OFF state (non-conducting state) (the detection signal input to the production control board 300 from the switch circuit units se, sf, sg, sh is set to low level).
The receiving plate unit SU is configured including a conductive piece. When the receiving plate unit SU is attached to the front frame unit 4, the conductive pieces can switch the contact portions of the switch circuit portions se, sf, sg, and sh between ON and OFF states.
In particular, the configuration of the conducting piece (in this embodiment, the position where the conducting piece is provided) is different between "Pasket unit A", "Pasket unit B", "Pasket unit C" and "Pasket unit D". Thus, when the tray unit SU is attached to the front frame unit 4, the pattern (combination) in which the contact parts of the four switch circuit parts se, sf, sg, and sh are turned on or off is different for each type of the tray unit SU.

Specifically, when the tray unit SU is not attached to the front frame unit 4, the contact portions of all the switch circuit portions se, sf, sg, and sh are turned off (non-conducting state).
In the "receptacle unit A", a conductive piece is provided at a position corresponding to the switch circuit se among the four switch circuit units se, sf, sg, and sh. As a result, when the "receptacle unit A" is attached to the front frame unit 4, of the four switch circuit units se, sf, sg, and sh, the contact portion of the switch circuit portion se is turned on (conducting state), and the contact portions of the other switch circuit portions sf, sg, and sh are turned off (non-conducting state).
On the other hand, in the "receptacle unit B", among the four switch circuit units se, sf, sg, and sh, a conductive piece is provided at a position corresponding to the switch circuit unit sf. As a result, when the "receptacle unit B" is attached to the front frame unit 4, of the four switch circuit units se, sf, sg, and sh, the contact portion of the switch circuit portion sf is turned on (conducting state), and the contact portions of the other switch circuit portions se, sg, and sh are turned off (non-conducting state).
On the other hand, in the "receptacle unit C", among the four switch circuit units se, sf, sg, and sh, a conductive piece is provided at a position corresponding to the switch circuit unit sg. As a result, when the "receptacle unit C" is attached to the front frame unit 4, of the four switch circuit units se, sf, sg, and sh, the contact portion of the switch circuit portion sg is turned on (conducting state), and the contact portions of the other switch circuit portions se, sf, and sh are turned off (non-conducting state).
On the other hand, in the "receptacle unit D", among the four switch circuit units se, sf, sg, and sh, a conductive piece is provided at a position corresponding to the switch circuit unit sh. As a result, when the "receptacle unit D" is attached to the front frame unit 4, of the four switch circuit units se, sf, sg, and sh, the contact portion of the switch circuit portion sh is turned on (conducting state), and the contact portions of the other switch circuit portions se, sf, and sg are turned off (non-conducting state).
It is also possible to provide a "receptacle unit E" in which conductive pieces are provided at positions corresponding to the switch circuit units se, sf among the four switch circuit units se, sf, sg, and sh. As a result, when the "receptacle unit E" is attached to the front frame unit 4, of the four switch circuit units se, sf, sg, and sg, the contact portions of the switch circuit portions se and sf are turned on (conducting state), and the contact portions of the other switch circuit portions sg and sh are turned off (non-conducting state).

The effect control board 300 is provided with input ports (not shown) corresponding to the switch circuit units se, sf, sg, and sh of each system, and a reception storage area corresponding to each input port.
The detection signals output from the switch circuit units se, sf, sg, and sh are input to the input ports corresponding to the switch circuit units se, sf, sg, and sh. 1-bit data indicating the input state of the detection signal to the input port corresponding to the reception storage area is set in each reception storage area. That is, each reception storage area is set to "1" when the detection signal is input to the input port corresponding to the reception storage area (the input detection signal is high level), and is set to "0" when the detection signal is not input to the input port corresponding to the reception storage area (the input detection signal is low level).
In this embodiment, as input ports, an input port pe corresponding to the switch circuit section se, an input port pf corresponding to the switch circuit section sf, an input port pg corresponding to the switch circuit section sg, and an input port ph corresponding to the switch circuit section sh are provided.
As reception storage areas, a reception storage area me corresponding to the input port pe (switch circuit section se), a reception storage area mf corresponding to the input port pf (switch circuit section sf), a reception storage area mg corresponding to the input port pg (switch circuit section sg), and a reception storage area mh corresponding to the input port ph (switch circuit section sh) are provided.
When the contact portion of the switch circuit section se is in the off state (non-conducting state) (when the detection signal is at low level), "0" is set in the reception storage area me.
When the contact portion of the switch circuit portion sf is in the off state (non-conducting state) (when the detection signal is at low level), "0" is set in the reception storage area mf, and when the contact portion of the switch circuit portion sf is in the on state (conducting state) (when the detection signal is at high level), "1" is set in the reception storage area mf.
When the contact portion of the switch circuit portion sg is in the off state (non-conducting state) (when the detection signal is at low level), "0" is set in the reception storage area mg.
When the contact portion of the switch circuit sh is in the off state (non-conducting state) (when the detection signal is at low level), "0" is set in the reception storage area mh, and when the contact portion of the switch circuit sh is in the on state (conducting state) (when the detection signal is at high level), "1" is set in the reception storage area mh.

Thereby, the CPU 310 of the performance control board 300 can determine (discriminate/identify) whether or not the saucer unit SU is attached to the front frame unit 4 and the type of the saucer unit SU attached to the front frame unit 4 based on the 4-bit data stored in the four reception storage areas me, mf, mg, and mh.
That is, when "0" is stored in all the reception storage areas me, mf, mg, and mh, it is determined that the receiving tray unit SU is not attached to the front frame unit 4 (that the receiving tray unit SU is incompletely attached to the front frame unit 4).
On the other hand, when "1" is set in the reception storage area me and "0" is set in the other reception storage areas mf, mg, and mh among the four reception storage areas me, mf, mg, and mh, it is determined that the type of the saucer unit SU attached to the front frame unit 4 is "saucer unit A."
On the other hand, when "1" is set in the reception storage area mf among the four reception storage areas me, mf, mg, mh and "0" is set in the other reception storage areas me, mg, mh, it is determined that the type of the saucer unit SU attached to the front frame unit 4 is the "saucer unit B".
On the other hand, when "1" is set in the reception storage area mg among the four reception storage areas me, mf, mg, and mh, and "0" is set in the other reception storage areas me, mf, and mh, it is determined that the type of the saucer unit SU attached to the front frame unit 4 is the "saucer unit C."
On the other hand, when "1" is set in the reception storage area mh among the four reception storage areas me, mf, mg, mh, and "0" is set in the other reception storage areas me, mf, mg, it is determined that the type of the saucer unit SU attached to the front frame unit 4 is "saucer unit D".
When the above-described "saucer unit E" is provided, if "1" is set in the reception storage areas me, mf out of the four reception storage areas me, mf, mg, mh, and "0" is set in the other reception storage areas mg, mh, it is determined that the type of the saucer unit SU attached to the front frame unit 4 is the "saucer unit E".

The DRAM 304 of the effect control board 300 is provided with a second material replacement offset storage area. A second material replacement offset value (one of "0" to "3") is stored (set) in the second material replacement offset storage area.
The CPU 310 of the effect control board 300 acquires the 4-bit data (hereinafter referred to as "second model determination bit data") stored in the four reception storage areas me, mf, mg, and mh in the material replacement offset setting process (step S28-2) executed when the power is turned on, determines the type of the saucer unit SU attached to the front frame unit 4 based on the acquired second model determination bit data, and determines the second type corresponding to the determined saucer unit SU type. A material replacement offset value is stored in a second material replacement offset storage area.
At this time, if it is determined that the type of the saucer unit SU attached to the front frame unit 4 is "saucer unit A", "0" is stored in the second material replacement offset storage area, and if it is determined that the type of the saucer unit SU attached to the front frame unit 4 is "saucer unit B", "1" is stored in the second material replacement offset storage area, and if it is determined that the type of the saucer unit SU attached to the front frame unit 4 is "saucer unit C", "2" is stored in the second material replacement offset storage area, and "3" is stored in the second material replacement offset storage area when it is determined that the type of the tray unit SU attached to the front frame unit 4 is "the tray unit D".

Further, the CGROM 303 stores, as image data (compressed image data) of the ``button notice effect image'', ``button notice effect image data A'' corresponding to the ``receiver unit A'', ``button notice effect image data B'' corresponding to the ``receiver unit B'', ``button notice effect image data C'' corresponding to the ``receiver unit C'', and ``button notice effect image data D'' corresponding to the ``receiver unit D''.
Here, the shape (appearance, configuration, type) of the operation means that can be operated by the player differs between the "receiving tray unit A", the "receiving tray unit B", the "receiving tray unit C" and the "receiving tray unit D". The image data of the ``button notice effect image'' corresponding to each type of receiver unit SU includes display of an image simulating the shape of the operating means provided in the corresponding type of receiver unit SU.
That is, the "button notice effect image data A" includes a display of an image simulating the operating means (for example, the effect button 5b) provided in the "receptacle unit A". Further, the "button notice effect image data B" includes a display of an image simulating an operation means (for example, an operation lever) provided in the "receptacle unit B". Also, the "button notice effect image data C" includes display of an image simulating an operation means (for example, a trigger of an object resembling a gun) provided in the "receptacle unit C". Further, the "button notice effect image data D" includes display of an image simulating an operation means (for example, an object that can be pushed) provided in the "receptacle unit D".

The CPU 310 of the effect control board 300 acquires the second material replacement offset value stored in the second material replacement offset storage area when executing the "button advance notice effect". Then, image data corresponding to the acquired second material replacement offset value is set as the image data of the "button preview effect image".
At this time, when "0" is stored in the second material replacement offset storage area, "button notice effect image data A" is set, when "1" is stored in the second material replacement offset storage area, "button notice effect image data B" is set, when "2" is stored in the second material replacement offset storage area, "button notice effect image data C" is set, and when "3" is stored in the second material replacement offset storage area, "button notice effect image data D" is set. ” is set.
As a result, a mode corresponding to the type of the receiving tray unit SU detected by the detection means is set as the mode of the "button notice effect" (specifically, the mode of the "button notice effect image").
That is, when the type of the receiving tray unit SU attached to the front frame unit 4 is 'the receiving tray unit A', an image based on the 'button advance notice performance image data A' is displayed as the 'button advance notice performance image'.
On the other hand, when the type of the receiving tray unit SU attached to the front frame unit 4 is 'the receiving tray unit B', an image based on the 'button advance notice performance image data B' is displayed as the 'button advance notice performance image'.
On the other hand, when the type of the receiving tray unit SU attached to the front frame unit 4 is 'the receiving tray unit C', an image based on the 'button advance notice performance image data C' is displayed as the 'button notice performance image'.
On the other hand, when the type of the receiving tray unit SU attached to the front frame unit 4 is 'the receiving tray unit D', an image based on the 'button advance notice performance image data D' is displayed as the 'button advance notice performance image'.

As described above, in the pachinko machine 1, the aspect of the ``button notice effect'' (specifically, the aspect of the ``button notice effect image'') is automatically changed according to the type of the tray unit SU attached to the front frame unit 4.例文帳に追加
Accordingly, it is not necessary to replace the image data stored in the CGROM 303 according to the type of the receiving tray unit SU attached to the front frame unit 4, and it is not necessary to change the control contents.
Therefore, it is possible to reduce the number of man-hours during manufacturing, and to suppress the occurrence of defects due to human error.

(Configuration of firing handle unit 6)
Next, the configuration of the firing handle unit 6 will be described.
FIG. 63 is an enlarged view showing the firing handle unit; FIG. 64 is a perspective view showing the firing handle unit with the face cover removed;
Here, FIG. 63(a) shows a state in which an operation ring 72, which will be described later, is arranged at the initial position, and FIG. 63(b) shows a state in which the operation ring 72 is arranged at the maximum position.
A shooting handle unit 6 is provided on the body frame. Specifically, the shooting handle unit 6 is provided so as to protrude from the front of the front frame unit 4 (front frame) toward the front side. The firing handle unit 6 is arranged on the side of the saucer unit SU.
As shown in FIGS. 63 and 64, the firing handle unit 6 includes a handle base 71, an operating ring 72, a coil spring 73, a face cover 74, and a firing stop button 77.

The handle base 71 has a substantially cylindrical shape and is fixed to the front surface of the front frame unit 4 (front frame). The handle base 71 is provided with a rotary shaft 71a and three guide shafts 71b. The rotating shaft 71a is provided along the central axis of the handle base 71 which is formed in a substantially cylindrical shape. The three guide shafts 71b are provided around the rotating shaft 71a.
The operation ring 72 is rotatably attached to the handle base 71 . The operation ring 72 includes a ring portion 72a and a plurality of (three in this embodiment) finger hook portions fa, fb, and fc provided on the outer peripheral surface of the ring portion 72a.
The ring portion 72a is formed in a substantially cylindrical shape (substantially annular/substantially ring-like) having an open top surface and a bottom surface.
The finger hooks fa, fb, and fc are provided so as to protrude outward from the outer peripheral surface of the ring portion 72a. The three finger hooks fa, fb, and fc are provided at predetermined intervals along the circumferential direction of the ring portion 72a. The three finger hooks fa, fb, and fc have different sizes. In particular, the three finger hook portions fa, fb, and fc have different amounts of protrusion from the outer peripheral surface of the ring portion 72a (hereinafter simply referred to as "protrusion amounts"). That is, the amount of protrusion is the dimension (height) from the outer peripheral surface of the ring portion 72a to the vertex (vertex in the radial direction) of each of the finger hook portions fa, fb, and fc.

In the present embodiment, of the three finger hook portions fa, fb, and fc arranged in the left-right direction when the operation ring 72 is located at the initial position, the finger hook portion fa on the left side has the largest protrusion amount, the finger hook portion fc on the right side has the smallest protrusion amount, and the finger hook portion fb provided in the middle has a protrusion amount smaller than that of the finger hook portion fa and larger than that of the finger hook portion fc.
In other words, of the three finger hook portions fa, fb, and fc arranged in the vertical direction when the operation ring 72 is located at the maximum position, the finger hook portion fa provided on the upper side has the largest protrusion amount, the finger hook portion fc provided on the lower side has the smallest protrusion amount, and the finger hook portion fb provided in the middle has a protrusion amount smaller than that of the finger hook portion fa and larger than that of the finger hook portion fc.
That is, the projection amount of each finger hooking portion fa, fb, and fc is, in descending order, finger hooking portion fa, finger hooking portion fb, and finger hooking portion fc (large protrusion amount→small protrusion amount).

A bearing hole (not shown) and a pair of guide holes 72b are provided in the bottom surface of the ring portion 72a. The bearing hole is provided along the central axis of the substantially cylindrical ring portion 72a. Each guide hole 72b is an elongated through hole curved along the circumferential direction. The pair of guide holes 72b are arranged 180° out of phase around the bearing hole.
The coil spring 73 has one end locked to a receiving portion (not shown) of the handle base 71 and the other end locked to a receiving portion (not shown) of the operation ring 72 . A coil spring 73 biases the operation ring 72 toward the initial position.
The face cover 74 is formed in a substantially hemispherical shape. The face cover 74 is attached to the tip of each guide shaft 71b by screwing. As a result, the operation ring 72 is rotatably held between the handle base 71 and the face cover 74 . The face cover 74 covers (conceals) the open top surface of the ring portion 72a.
A firing stop button 77 is provided on the outer peripheral surface of the handle base 71 . The shooting stop button 77 can be pressed by the player.

The operation ring 72 is attached to the handle base 71 with the rotary shaft 71a inserted through the bearing hole and the guide shaft 71b inserted through the guide hole 72b. As a result, the operation ring 72 is rotatable with respect to the handle base 71 around the rotary shaft 71a. At this time, the rotation range of the operation ring 72 is restricted by the guide shaft 71b inserted through the guide hole 72b.
That is, as described above, the operating ring 72 is always biased counterclockwise when viewed from the front side by the elastic force of the coil spring 73 . Therefore, when the operation ring 72 is not rotated, one end surface of each guide hole 72b contacts the guide shaft 71b. As a result, the counterclockwise rotation of the operating ring 72 is restricted, and the operating ring 72 is placed (stationary) at the initial position.
On the other hand, the operation ring 72 can be rotated clockwise when viewed from the front side by being rotated against the bias (elastic force) of the coil spring 73 . Then, when the amount of clockwise rotation of the operation ring 72 reaches a predetermined amount, the other end surface of each guide hole 72b comes into contact with the guide shaft 71b. As a result, the clockwise rotation of the operating ring 72 is restricted, and the operating ring 72 is placed at the maximum position (stationary).
On the other hand, when the rotating operation of the operating ring 72 is finished (stopped), the operating ring 72 is returned to the initial position by the biasing (elastic force) of the coil spring 73 .
As described above, the operation ring 72 can be rotated by the player. At this time, the player can easily rotate the operation ring 72 by putting his/her fingers on the finger hooks fa, fb, and fc.
In particular, the operation ring 72 can be rotated (displaced/operated) within a range from the initial position (see FIG. 63(a)) to the maximum position (see FIG. 63(b)).
As will be described later, in the game area 30, a left path (left hitting area) formed on the left side of the main image display device 31 and a right path (right hitting area) formed on the right side of the main image display device 31 are configured as paths along which game balls flow down.
A game ball shot by the game ball shooting device 430 in response to the rotating operation of the operation ring 72 passes through a shooting passage (not shown) and flows into the game area 30 . At this time, when the momentum of the shot game ball is weak, the game ball that has passed through the shooting passage flows into the left path. On the other hand, when the momentum of the launched game ball is strong, the game ball that has passed through the launch passage passes through a guide passage (not shown) and flows into the right path.

The firing handle unit 6 includes a firing volume 411 (see FIG. 3), a touch sensor 412 (see FIG. 3), and a firing stop switch 413 (see FIG. 3).
The firing volume 411 is configured with a variable resistor. The firing volume 411 detects the amount of rotational manipulation of the manipulation ring 72 (the angle by which the manipulation ring 72 is rotationally manipulated). Specifically, the firing volume 411 includes a rotary shaft (not shown) and a resistor (not shown) whose resistance value changes according to the amount of rotation (rotation angle) of the rotary shaft. The rotation axis of the firing volume 411 is coaxially fixed to the bearing hole of the operation ring 72 . As a result, the rotary shaft of the firing volume 411 is rotated according to the rotational operation of the operation ring 72 , and the resistance value of the firing volume 411 changes according to the rotational operation amount of the operation ring 72 .
The firing volume 411 is electrically connected to the operation detection section 421 (see FIG. 4). The operation detection unit 421 detects the rotation operation (rotation operation amount) of the operation ring 72 based on the change in the resistance value (voltage value) of the ejection volume 411 .

The touch sensor 412 detects contact (holding) of the operation ring 72 by the player based on changes in capacitance. Then, the touch sensor 412 outputs a touch signal to the firing enable condition detection unit 422 (see FIG. 4) when the player's contact with the operation ring 72 is detected (sets the touch signal to a high level). On the other hand, the touch sensor 412 stops outputting the touch signal to the firing enable condition detection unit 422 (makes the touch signal low level) when the player's contact with the operation ring 72 is not detected.
The firing stop switch 413 detects pressing operation of the firing stop button 77 . Then, the firing stop switch 413 outputs a firing stop signal to the firing enable condition detection unit 422 when the pressing operation of the firing stop button 77 is not detected (making the firing stop signal high level). On the other hand, the firing stop switch 413 stops outputting the firing stop signal to the firing enable condition detection unit 422 (making the firing stop signal low level) when the pressing operation of the firing stop button 77 is detected.

(Positional relationship between operation ring 72 and body frame)
Next, the positional relationship between the operation ring 72 and the body frame will be described.
FIG. 65 is a diagram showing the positional relationship between the operation ring and the front frame unit. FIG. 66 is a diagram showing the positional relationship between the operation ring and the inner frame unit.
In this embodiment, when the operation ring 72 is placed at the initial position, the finger hooks fa, fb, and fc (top portions) do not protrude below the lower edge of the body frame. That is, as shown in FIG. 65, when the operation ring 72 is placed at the initial position, the finger hooks fa, fb, and fc (top portions) do not protrude below the lower edge of the front frame unit 4 (front frame). Further, as shown in FIG. 66, when the operation ring 72 is placed at the initial position, the finger hooks fa, fb, and fc (top portions) do not protrude below the lower edge of the inner frame unit 3 (inner frame).
Further, in this embodiment, when the operation ring 72 is placed at the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude below the lower edge of the body frame. That is, when the operation ring 72 is located at the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude below the lower edge of the front frame unit 4 (front frame). Further, when the operation ring 72 is placed at the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude below the lower edge of the inner frame unit 3 (inner frame).
As a result, even when the body frame is placed on the floor or the like, the finger hooks fa, fb, and fc do not come into contact with the floor or the like, and damage to the firing handle unit 6 (operation ring 72) can be prevented.
In particular, in this embodiment, even when the operation ring 72 is arranged (rotated) at any position within the range from the initial position to the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude below the lower edge of the body frame. That is, even when the operation ring 72 is arranged (rotated) at any position within the range from the initial position to the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude below the lower edge of the front frame unit 4 (front frame). Further, even when the operation ring 72 is arranged (rotated) at any position within the range from the initial position to the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude below the lower edge of the inner frame unit 3 (inner frame).
This makes it possible to more reliably prevent damage to the firing handle unit 6 (operation ring 72).

Further, in this embodiment, when the operation ring 72 is placed at the initial position, the finger hooks fa, fb, and fc (top portions) do not protrude rightward beyond the right edge of the body frame. That is, as shown in FIG. 65, when the operation ring 72 is placed at the initial position, the finger hooks fa, fb, and fc (top portions) do not protrude rightward beyond the right edge of the front frame unit 4 (front frame). Further, as shown in FIG. 66, when the operation ring 72 is placed at the initial position, the finger hooks fa, fb, and fc (top portions) do not protrude rightward beyond the right edge of the inner frame unit 3 (inner frame).
Further, in this embodiment, when the operation ring 72 is placed at the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude rightward beyond the right edge of the body frame. That is, when the operation ring 72 is located at the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude rightward beyond the right edge of the front frame unit 4 (front frame). Further, when the operation ring 72 is arranged at the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude rightward beyond the right edge of the inner frame unit 3 (inner frame).
As a result, even if the body frame is accidentally collided with a wall or the like, the finger hooks fa, fb, and fc do not come into contact with the wall or the like, and damage to the shooting handle unit 6 (operation ring 72) can be prevented.
In particular, in this embodiment, even when the operation ring 72 is arranged (rotated) at any position within the range from the initial position to the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude rightward beyond the right edge of the body frame. That is, even when the operation ring 72 is arranged (rotated) at any position within the range from the initial position to the maximum position, the finger hooks fa, fb, and fc (top portions) do not protrude to the right from the right edge of the front frame unit 4 (front frame). In addition, even when the operation ring 72 is arranged (rotated) at any position within the range from the initial position to the maximum position, each of the finger hooks fa, fb, and fc (top) does not protrude rightward from the right edge of the inner frame unit 3 (inner frame).
This makes it possible to more reliably prevent damage to the firing handle unit 6 (operation ring 72).

Furthermore, in the present embodiment, the finger hooking portion fa, which has the largest protrusion amount among the three finger hooking portions fa, fb, and fc, is configured so as not to be located at the lowest point in the rotational orbit of the finger hooking portion fa when the operation ring 72 is arranged at the maximum position.
Here, the "rotational trajectory of the finger hook fa" is the trajectory drawn by the finger hook fa as the operation ring 72 rotates within the range from the initial position to the maximum position.
In this embodiment, when the operation ring 72 is arranged at the initial position, the finger hooking portion fa is arranged at the lowest point in the rotation orbit of the finger hooking portion fa. Further, when the operation ring 72 is arranged at the maximum position, the finger hooking portion fa is arranged at a position higher than the lowest point of the rotational orbit of the finger hooking portion fa.
This makes it easier for the player to put his/her finger on the finger-holding portion fa, and as a result, the operation ring 72 can be easily rotated.

Specifically, as shown in FIGS. 65 and 66, the dimension (distance) D1 from the rotation center (rotational axis 71a) of the operation ring 72 to the apex of the finger hook portion fa is set to 53.4 [mm]. Also, the dimension (distance) D2 from the rotation center (rotation shaft 71a) of the operation ring 72 to the top of the finger hook portion fb is set to 45.6 [mm]. Also, the dimension (distance) D3 from the rotation center (rotation shaft 71a) of the operation ring 72 to the top of the finger hook portion fc is set to 39.3 [mm]. Also, the dimension (distance) E from the center of rotation (rotating shaft 71a) of the operation ring 72 to the edge (end in the radial direction) of the ring portion 72a is set to 34.6 [mm].
In particular, the dimension (distance) F from the rotation center (rotating shaft 71a) of the operation ring 72 to the lower edge of the front frame unit 4 (front frame) is set to 40.0 [mm]. Also, the dimension (distance) G from the rotation center (rotating shaft 71a) of the operation ring 72 to the right edge of the front frame unit 4 (front frame) is set to 49.1 [mm].
As a result, dimension D3<dimension F<dimension G, and when the operation ring 72 rotates within the range from the initial position to the maximum position, the apex of the finger hooking part fc does not protrude outward from the edge of the front frame unit 4 (front frame). Also, the dimension D2<the dimension G, and when the operation ring 72 rotates within the range from the initial position to the maximum position, the apex of the finger hook portion fb does not protrude outward from the edge of the front frame unit 4 (front frame).
Furthermore, the dimension (distance) H from the rotation center (rotation shaft 71a) of the operation ring 72 to the lower edge of the inner frame unit 3 (inner frame) is set to 45.0 [mm]. Also, the dimension (distance) I from the rotation center (rotating shaft 71a) of the operation ring 72 to the right edge of the inner frame unit 3 (inner frame) is set to 51.1 [mm].
As a result, dimension D3<dimension H<dimension I, and when the operation ring 72 rotates within the range from the initial position to the maximum position, the apex of the finger hook fc does not protrude outward from the edge of the inner frame unit 3 (inner frame). Also, the dimension D2<the dimension I, and when the operation ring 72 rotates within the range from the initial position to the maximum position, the apex of the finger hook portion fb does not protrude outward from the edge of the inner frame unit 3 (inner frame).

(Operation torque of operation ring 72)
Next, the operating torque of the operating ring 72 will be described.
FIG. 67 is a diagram illustrating an example of setting the operation torque according to the first embodiment; FIG. 68 is a diagram showing a setting example of operation torque according to the second embodiment.
In the following description, the operation torque required to start rotating the operation ring 72 from the initial position is referred to as "first operation torque". That is, the first operation torque is the operation torque required for starting the movement of the operation ring 72 arranged at the initial position. Therefore, when the operation torque (the operation torque toward the maximum position side) acting on the operation ring 72 arranged at the initial position reaches the first operation torque, the operation ring 72 starts rotating toward the maximum position side.
Further, the operation torque required to rotate the operation ring 72 from the initial position to the left-handed reference position is referred to as "second operation torque". That is, the second operation torque is the operation torque required to displace the operation ring 72 arranged at the initial position to the left-handed reference position. Therefore, when the second operation torque (the operation torque toward the maximum position) acts on the operation ring 72 arranged at the initial position, the operation ring 72 rotates from the initial position to the left-handed reference position.
Here, the "left-handed reference position" is the position of the operation ring 72 that allows the game ball to be shot to the left-hand path, which will be described later. In particular, the left-handed reference position is the position of the operation ring 72 that makes it possible to stably shoot the game ball to the left-hand path. In this embodiment, the center (center) position (angle) of the range (angle) of the operation ring 72 from which the game ball is to be shot with respect to the left path is defined as the left-handed reference position.

Further, the operation torque required to rotate the operation ring 72 from the initial position to the maximum position is referred to as "third operation torque". That is, the third operation torque is the operation torque required to displace the operation ring 72 arranged at the initial position to the maximum position. Therefore, when the third operation torque (the operation torque toward the maximum position side) acts on the operation ring 72 arranged at the initial position, the operation ring 72 rotates from the initial position to the maximum position.
In this embodiment, the maximum rotation position and the right-handed reference position match. The "right-handed reference position" is the position of the operation ring 72 that allows the game ball to be shot to the right-hand path, which will be described later. In particular, the right-handed reference position is the position of the operation ring 72 at which the game ball can be stably shot to the right path.
Note that the maximum rotation position and the right-handed reference position may not match each other. That is, as the right-handed reference position, the position (angle) of the center (center) of the range (angle) of the operation ring 72 from which the game ball is shot with respect to the right path may be defined.

In this embodiment, the second operation torque is larger than the first operation torque. Also, the third operation torque is larger than the second operation torque. In particular, the third operation torque is less than or equal to twice the second operation torque.
As a result, the difference between the second operation torque and the third operation torque is reduced, and the operation torque when the operation ring 72 is rotated from the left-handed reference position to the maximum position (right-handed reference position) does not suddenly increase with respect to the operation torque when the operation ring 72 is rotated from the initial position to the left-handed reference position. Therefore, the player's fatigue due to the operation of the operation ring 72 is suppressed, and the burden on the player can be reduced.
Further, in the present embodiment, the second operation torque is twice or less than the first operation torque.
As a result, the difference between the first operation torque and the second operation torque becomes small, and the operation torque when the operation ring 72 is rotated from the initial position to the left-handed reference position does not suddenly increase with respect to the operation torque required for starting the movement of the operation ring 72 from the initial position. Therefore, the player's fatigue due to the operation of the operation ring 72 is suppressed, and the burden on the player can be reduced.

As shown in FIG. 67, in Example 1, the first operation torque is 6.8 [N.mm], the second operation torque is 13.6 [N.mm], and the third operation torque is 23.8 [N.mm].
Further, as shown in FIG. 68, in Example 2, the first operation torque is 27.2 [N.mm], the second operation torque is 54.4 [N.mm], and the third operation torque is 95.2 [N.mm].
On the other hand, in the comparative example, the first operation torque=31.0 [N.mm], the second operation torque=69.0 [N.mm], and the third operation torque=152.0 [N.mm].
As a result, in the first and second embodiments, compared with the comparative example, the operation torque curve (the curve indicating the relationship between the operation torque and the position) can be flattened, and when the operation ring 72 is rotated from the initial position to the maximum position, the operation torque does not suddenly increase, and the burden on the player can be reduced.
In particular, in the first embodiment, as compared with the second embodiment, when the operation ring 72 is rotated from the initial position to the maximum position, the amount of change in the operation torque is small, so it is possible to further reduce the burden on the player.

(Rotation angle of operation ring 72)
Next, the rotation angle of the operation ring 72 will be explained.
In the following description, the operation angle (rotational angle) of the operation ring 72 from the initial position to the left-handed reference position is referred to as a "first operation angle". That is, when the operation ring 72 arranged at the initial position is rotated by the first operation angle (rotated toward the maximum position side), the operation ring 72 is arranged at the left-handed reference position.
Further, the operation angle (rotational angle) from the initial position to the maximum position of the operation ring 72 is defined as a "second operation angle". That is, when the operation ring 72 arranged at the initial position is rotated by the second operation angle (rotation operation toward the maximum position side), the operation ring 72 is arranged at the maximum position.
In this embodiment, the first operation angle is within the range of 45° to 60°, and the second operation angle is within the range of 100° to 120°. In particular, the first operating angle is less than half the second operating angle.
This makes it possible for the player to easily shoot the game ball to the right path.

(Configuration of game board unit 10)
Next, the configuration of the game board unit 10 will be described.
FIG. 2 is a diagram showing the front of the game board unit, and schematically showing a part particularly necessary for explanation. FIG. 69 is an exploded perspective view of the game board. FIG. 70 is a diagram showing the configuration of the outer rail. FIG. 71 is a diagram showing the arrangement of guide holes gh in the outer rail. FIG. 72 is a cross-sectional view of the rail base.
2, the display of the rail base 13 and the like is omitted. 70(a) shows the outer rail 14 as seen from the side, and FIG. 70(b) shows the outer rail 14 as seen from the front. Also, FIG. 71 shows the state of the outer rail 14 attached to the game board 11 viewed from the front side. Also, in FIG. 72, the game ball is indicated by the code "B".
The game board unit 10 is supported by the inner frame unit 3. Specifically, the game board unit 10 is attached to the inner side of the inner frame of the inner frame unit 3 . Thereby, the game board unit 10 is arranged on the back side of the front frame unit 4 . A player can visually recognize a game board 11 (a game area 30), which will be described later, through the transparent plates g1 and g2. In this embodiment, a game area 30, which will be described later, is formed between the back surface of the transparent plate g2 arranged on the back side of the pair of transparent plates g1 and g2 and the front surface of the game board 11. FIG.
As shown in FIG. 2, the game board unit 10 includes a set board (not shown), a game board 11 attached to the set board, and various effect devices (main image display device 31, sub-image display device 32, movable body unit, etc.) attached to the set board.
The set plate is formed in a box shape with an open front side. An opening formed by a through hole is provided in a substantially central portion of the back plate of the set plate.

The game board 11 is attached to the front side of the set board.
As shown in FIG. 69, the game board 11 is made of resin and formed in a flat plate shape. An opening (not shown in FIG. 69) consisting of a through hole is provided at substantially the center of the game board 11 . The player can visually recognize the display screen 31a of the main image display device 31 through the opening provided in the game board 11 and the opening provided in the set board.
An inner rail 12, a rail base 13, and an outer rail 14 are attached to the front of the game board 11. - 特許庁A game area 30 is defined by the inner rail 12, the outer rail 14, and the like.
The inner rail 12 is made of resin or the like. The inner rail 12 is configured in an arc shape when viewed from the front side. The outer peripheral surface of the inner rail 12 constitutes an inner guide surface 12a that guides the game ball. A return ball prevention piece 12b is provided at the tip of the inner rail 12. As shown in FIG. The return ball preventing piece 12b prevents the game ball shot from the shooting path r1 to the game area 30 from returning to the shooting path r1.

The rail base 13 is made of resin or the like. As shown in FIG. 69, the rail base 13 is provided with a guide surface 13b that supports the outer rail 14. As shown in FIG. The guide surface 13b extends in an arc shape when viewed from the front side.
At least a part of the guide surface 13b in the longitudinal direction is inclined toward the rear side (the front side of the game board 11). In this embodiment, substantially the entire length of the guide surface 13b is inclined toward the rear side. As a result, at least part of the outer guide surface 14c of the outer rail 14 supported by the guide surface 13b (substantially the entire length in this embodiment) in the longitudinal direction can be inclined toward the rear side (the front side of the game board 11). This makes it difficult for the game ball shot by the game ball shooting device 430 to flow toward the front side (the side of the transparent plate g2), making it possible to suppress contact with the transparent plate g2.
A plurality of protrusions (bosses) pr are provided on the guide surface 13b. Each protruding portion pr is formed as a substantially elliptical protruding portion, and is provided so as to protrude from the guide surface 13b. Each projecting portion pr is fitted into a guide hole gh provided in the outer rail 14 to position the outer rail 14 with respect to the rail base 13 (game board 11).
A proximal end support portion (not shown) that supports the proximal bent portion 14 a provided on the outer rail 14 is provided at the proximal end portion (starting end portion) of the rail base 13 . The proximal support portion is configured as a recess into which the proximal bent portion 14a can be inserted. Further, at the tip (terminating end) of the rail base 13, a tip side support portion (not shown) that supports the tip side bending portion 14b provided on the outer rail 14 is provided. The tip-side support portion is configured as a recess into which the tip-side bent portion 14b can be inserted.
Also, the rail base 13 is provided with a covering portion 13a that covers (supports) the side surface (the side surface on the front side) of the outer rail 14 when viewed from the front side.

The outer rail 14 is made of metal. As shown in FIGS. 69 and 70, the outer rail 14 is formed in a flat plate shape and extends in an arc shape when viewed from the front side.
A base end portion (starting end portion) of the outer rail 14 is provided with a base end bent portion 14a. The proximal bent portion 14a is formed by bending the proximal portion of the outer rail 14 into a substantially L shape. A distal end portion (end portion) of the outer rail 14 is provided with a distal end side bent portion 14b. The distal end bent portion 14b is formed by bending the distal end portion of the outer rail 14 into a substantially U shape.
A guide surface 13b of the rail base 13 supports the outer peripheral surface of the outer rail 14 formed in an arc shape. The inner peripheral surface of the outer rail 14 formed in an arc shape constitutes an outer guide surface 14c that guides the game ball.
A plurality of guide holes gh are provided in the outer rail 14 (outer guide surface 14c). Each guide hole gh is a through hole penetrating the outer rail 14 in the thickness direction. Each guide hole gh is a substantially elliptical through hole into which the protrusion pr can be fitted.
The outer rail 14 (outer guide surface 14c) is provided with guide holes gh at positions corresponding to the protrusions pr provided on the guide surface 13b when the outer rail 14 is supported (attached) to the guide surface 13b. As a result, the guide holes gh and the projections pr guide (define) the mounting position of the outer rail 14 with respect to the rail base 13 (guide surface 13b), and further guide (define) the mounting position of the outer rail 14 with respect to the game board 11 .

Next, the arrangement of the guide holes gh in the outer rail 14 (outer guide surface 14c) will be described.
Here, the arrangement of the plurality of guide holes gh in the outer rail 14 and the arrangement of the plurality of protrusions pr in the guide surface 13b correspond to each other.
Therefore, the arrangement condition of the plurality of guide holes gh in the outer rail 14 and the arrangement condition of the plurality of protrusions pr in the guide surface 13b are the same.
Therefore, the arrangement condition of the plurality of guide holes gh in the outer rail 14 will be described below, and the explanation of the arrangement condition of the plurality of protrusions pr in the guide surface 13b will be omitted.
The outer rail 14 is attached to the front of the game board 11 via the rail base 13 . The outer rail 14 (outer guide surface 14c) extends in an arc shape when viewed from the front side while attached to the game board 11 .
As shown in FIG. 71, in the following description, when the outer rail 14 attached to the game board 11 is viewed from the front side, the uppermost part (upper vertex) of the outer rail 14 is defined as "upper vertex P1", and the leftmost part (left vertex) of the outer rail 14 is defined as "left vertex P2".
The range from the base end (starting end) to the left vertex P2 of the outer rail 14 is defined as "first range H1", the range from the left vertex P2 to the upper vertex P1 of the outer rail 14 is defined as "second range H2", and the range from the upper vertex P1 to the tip (end) of the outer rail 14 is defined as "third range H3".
Also, the range from the left vertex P2 of the outer rail 14 to the tip (terminus) is referred to as a "fourth range". That is, the fourth range=second range H2+third range H3.
A range from the base end (starting end) of the outer rail 14 to the upper vertex P1 is defined as a "fifth range". That is, the fifth range=first range H1+second range H2.
Further, the range from the base end (starting end) to the intermediate portion of the outer rail 14 is referred to as "sixth range", and the range from the intermediate portion to the tip (terminating end) of the outer rail 14 is referred to as "seventh range". Here, the “intermediate portion” is the middle (central) portion of the outer rail 14 in the longitudinal direction.

In this embodiment, the number of guide holes gh provided is greater in the first range H1 than in the second range H2, and the number of guide holes gh provided is greater in the second range H2 than in the third range H3.
Further, in the present embodiment, the number of guide holes gh provided in the first range H1 is greater than or equal to the number of guide holes gh provided in the second range H2, and the number of guide holes gh provided in the second range H2 is greater than or equal to the number of guide holes gh provided in the third range H3.
Further, in the present embodiment, the number of guide holes gh provided in the first range H1 is greater than or equal to the number of guide holes gh provided in the third range H3, and the number of guide holes gh provided in the second range H2 is greater than or equal to the number of guide holes gh provided in the third range H3.
Further, in the present embodiment, the number of guide holes gh provided in the first range H1 is greater than or equal to the number of guide holes gh provided in the second range H2, and the number of guide holes gh provided in the first range H1 is greater than or equal to the number of guide holes gh provided in the third range H3.
Further, in the present embodiment, the number of guide holes gh provided in the first range H1 is larger than that in the fourth range.
Further, in the present embodiment, the number of guide holes gh provided in the fifth range is larger than that in the third range H3.
Further, in the present embodiment, the number of guide holes gh provided in the sixth range is larger than that in the seventh range.

Specifically, three guide holes gh are provided along the longitudinal direction in the first range H1. On the other hand, two guide holes gh are provided in the second range H2 along the longitudinal direction. On the other hand, no guide hole gh is provided in the third range H3.
Thus, the fourth range is provided with two guide holes gh along the longitudinal direction. In addition, five guide holes gh are provided along the longitudinal direction in the fifth range. In addition, four guide holes gh are provided in the sixth range along the longitudinal direction. In addition, one guide hole gh is provided along the longitudinal direction in the seventh range.
That is, in the outer rail 14, the portion on the base end side (game ball launching device 430 side) receives a larger impact from the collision of the game ball launched by the game ball launching device 430 than the portion on the tip end side (terminating end side), and the impact on the launching direction of the game ball launched by the game ball launching device 430 becomes larger.
As a result, in the outer rail 14, the base end side (game ball launching device 430 side) is required to have higher mounting strength and more accurate arrangement than the tip side (end end side).
Therefore, in the present embodiment, by increasing the number of guide holes gh provided in the proximal side (game ball launching device 430 side) portion of the outer rail 14, it is possible to prevent positional deviation and vibration in the proximal side portion. In addition, it is possible to stabilize the trajectory of the game ball and execute the game as designed. In particular, it is possible to prevent damage and vibration of the outer rail 14 due to the collision of the shot game ball. As a result, it is possible to prevent the shot game ball from shaking due to the damage or vibration, and it is possible to send the shot game ball to the board surface of the game board 11 stably. As a result, irregular movements of the game ball are reduced, and the game can be stably executed.
On the other hand, by reducing the number of guide holes gh provided in the tip side (terminating end side) portion of the outer rail 14, it becomes possible to facilitate processing of the outer rail 14 and attachment to the rail base 13.
As described above, it is possible to achieve both prevention of displacement and vibration of the outer rail 14 and facilitation of processing of the outer rail 14 and attachment to the game board 11 .

In particular, in this embodiment, the guide holes gh are not formed at the upper vertex P1 and the left vertex P2 of the outer rail 14 .
That is, when an impact is applied to the upper and lower side surfaces or the left and right side surfaces of the game board 11, the impact is strongly transmitted to the upper vertex P1 or the left vertex P2 of the outer rails . As a result, if the guide holes gh are formed in the upper vertex P1 and the left vertex P2 of the outer rail 14, the strength of the upper vertex P1 and the left vertex P2 is reduced due to the formation of the guide holes gh, and the outer rail 14 may be damaged when the impact is transmitted. Therefore, by forming the guide hole gh while avoiding the upper vertex P1 and the left vertex P2 of the outer rail 14, it is possible to suppress damage to the outer rail 14. FIG.
Further, in the present embodiment, no guide hole gh is formed in the third range H3. This makes it possible to facilitate processing of the outer rail 14 and attachment to the rail base 13 . Note that one or more guide holes gh may be formed in the third range H3.

As described above, in this embodiment, the outer rail 14 is formed with five guide holes gh along the longitudinal direction. At this time, the arrangement intervals of the five guide holes gh are uneven. In particular, the arrangement interval of the five guide holes gh is set so as to be wider toward the tip side (end side). In other words, the arrangement interval of the five guide holes gh is set so as to become narrower toward the proximal end (starting end).
Each guide hole gh is formed at a position where the game ball shot by the game ball shooting device 430 does not contact. That is, as shown in FIG. 72, each guide hole gh is formed at the end of the outer rail 14 in the width direction on the far side (the front side of the game board 11). In particular, each guide hole gh is formed at a position on the inner side (front side of the game board 11) in the width direction of the outer rail 14 from the front side of the game board 11 by the radius of the game ball from the front position.

Next, a method for attaching each rail 12, 14 to the game board 11 will be described.
To attach the inner rail 12 to the game board 11, a positioning projection (not shown) provided on the back side of the inner rail 12 is inserted into a positioning recess (not shown) provided on the front of the game board 11. As a result, the inner rail 12 is arranged at a predetermined position in front of the game board 11 . Then, the inner rail 12 is fixed to the front surface of the game board 11 by screwing.
To attach the outer rail 14 to the game board 11 , first, the rail base 13 is attached to the front surface of the game board 11 . For this purpose, a positioning projection (not shown) provided on the back side of the rail base 13 is inserted into a positioning recess (not shown) provided on the front of the game board 11 . As a result, the rail base 13 is arranged at a predetermined position in front of the game board 11 . Then, the rail base 13 is fixed to the front surface of the game board 11 by screwing.
Next, the outer rail 14 is attached to the rail base 13 . For this, the outer peripheral surface of the outer rail 14 is arranged along the guide surface 13 b of the rail base 13 . Also, the proximal bent portion 14a of the outer rail 14 is inserted (fitted) into the proximal support portion of the rail base 13, and the distal bent portion 14b of the outer rail 14 is inserted (fitted) into the distal support portion of the rail base 13. Further, each protrusion pr provided on the guide surface 13b is inserted (fitted) into each guide hole gh provided on the outer rail 14 . As a result, the outer rail 14 is attached to the rail base 13 in a state in which substantially the entire longitudinal direction of the outer peripheral surface of the outer rail 14 is supported by the guide surface 13b.

In front of the game board 11, a game area 30 is defined by the inner rail 12, the outer rail 14, and the like. In the game area 30, a left path (left hitting area) formed on the left side of the main image display device 31 and a right path (right hitting area) formed on the right side of the main image display device 31 are configured as paths along which game balls flow down.
In addition, on the front surface of the game board 11, the inner guide surface 12a of the inner rail 12 and the outer guide surface 14c of the outer rail 14 are arranged facing each other at a predetermined interval. A shooting path r1 for guiding the game ball shot by the game ball shooting device 430 to the game area 30 is formed between the inner guide surface 12a and the outer guide surface 14c.
Further, in the game area 30, a guiding path r2 is formed to guide (guide) the game ball shot from the shooting path r1 to the right side path. The guide passage r2 is formed at the upper end of the game area 30. As shown in FIG. The guide path r2 is formed above the main image display device 31. As shown in FIG. The guide passage r2 extends in an arc shape when viewed from the front side.
In this embodiment, the outer guide surface 14c constitutes the outer peripheral surface ra of the guide passage r2. A decorative portion 33 is provided above the opening in the front of the game board 11 . An inner peripheral surface rb of the guide passage r2 is formed on the upper surface of the decorative portion 33. As shown in FIG.
The game ball shot by the game ball shooting device 430 passes through the shooting path r1 and flows into the game area 30. - 特許庁At this time, when the momentum of the shot game ball is weak, the game ball that has passed through the shooting path r1 flows into the left path. On the other hand, when the momentum of the shot game ball is strong, the game ball that has passed through the shooting path r1 passes through the guide path r2 and flows into the right path.

Here, the positional relationship between the design portion 40 and the guide passage r2 will be described.
73 is a cross-sectional view taken along line AA shown in FIG. 1. FIG. 74 is an enlarged view of FIG. 73. FIG. In addition, in FIG.73 and FIG.74, the code|symbol "B" shows the game ball.
As shown in FIG. 73 , a design portion 40 is provided at the upper end portion of the front frame unit 4 . The design portion 40 is provided so as to surround the transparent plates g1 and g2 when viewed from the front side. The design portion 40 is provided so as to bulge (protrude) from the front of the front frame unit 4 (front frame) toward the front side. In particular, the design portion 40 is provided so as to bulge (protrude) toward the front side with respect to the transparent plates g1 and g2.
Specifically, the design portion 40 includes an upper surface 41 extending from the front of the front frame unit 4 (front frame) toward the front side, a front surface 42 extending downward from the front-side end (front end) of the upper surface 41, and a lower surface 43 extending from the lower end of the front surface 42 toward the rear side. As a result, the design portion 40 has a substantially U-shaped cross section.
The rear end (rear end) of the lower surface 43 of the design portion 40 extends to the front of the transparent plate g1. In this embodiment, the rear-side end of the lower surface 43 of the design portion 40 is in contact with the front surface of the transparent plate g1.
In particular, the lower surface 43 of the design portion 40 is inclined in the depth direction so that the front side is lower and the rear side is higher. As a result, a part of the upper end of the game board 11 is covered (concealed) by the lower end of the design portion 40 when viewed from the front side.
In addition, the lower surface 43 of the design portion 40 is curved such that each end in the left-right direction is low and the central portion in the left-right direction is high.

In the following description, as shown in FIGS. 73 and 74, an imaginary line perpendicular to the front surface of the game board 11 and passing through a portion (hereafter referred to as "peripheral vertex") of the outer peripheral surface ra of the guide path r2, which is located at the highest position (apex/apex), is referred to as a "first reference line k1". In addition, in this embodiment, the outer peripheral vertex coincides with the upper vertex P1.
An imaginary line that extends along the vertical direction, intersects the first reference line k1, and intersects the end (rear end) on the back side of the lower surface 43 of the design portion 40 is a “first vertical line” (not shown). A portion of the lower surface 43 of the design portion 40 that intersects the first vertical line is defined as a "first design portion d1".
In addition, a virtual line that extends along the vertical direction, intersects the first reference line k1, and intersects the lowest portion (lowest portion) of the lower surface 43 of the design portion 40 is defined as a “second vertical line” (not shown). A portion of the lower surface 43 of the design portion 40 that intersects the second vertical line is defined as a "second design portion d2".
An imaginary line that is orthogonal to the front surface of the game board 11 and passes through a portion of the inner peripheral surface rb of the guide path r2 that is located directly below the outer peripheral vertex is defined as a "second reference line k2". That is, the second reference line k2 is parallel to the first reference line k1 directly below the first reference line k1.
As a result, an imaginary line that extends along the vertical direction, intersects the second reference line k2, and intersects the rear end (rear end) of the lower surface 43 of the design portion 40 coincides with the first vertical line. As described above, the portion of the lower surface 43 of the design portion 40 that intersects the first vertical line is the first design portion d1.
In addition, an imaginary line that extends along the vertical direction, intersects the second reference line k2, and intersects the lowest portion (lowest portion) of the lower surface 43 of the design portion 40 coincides with the second vertical line. As described above, the portion of the lower surface 43 of the design portion 40 that intersects the second vertical line is the second design portion d2.

In this embodiment, the first design portion d1 is arranged below (lower than) the first reference line k1. In particular, the distance (dimension) A from the first reference line k1 to the first design portion d1 is equal to or less than the diameter of the game ball (4 [mm] in this embodiment). Here, the distance A is the height difference between the position of the first reference line k1 and the position of the first design portion d1.
Further, in the present embodiment, the second design portion d2 is arranged below (lower than) the first reference line k1. In particular, the distance (dimension) B from the first reference line k1 to the second design portion d2 is equal to or greater than the diameter of the game ball (40 [mm] in this embodiment). Here, the distance B is the height difference between the position of the first reference line k1 and the position of the second design portion d2.
Thus, in the present embodiment, the second design portion d2 is arranged below (lower than) the first reference line k1, and in particular, the distance B from the first reference line k1 to the second design portion d2 is equal to or greater than the diameter of the game ball, thereby making it possible to increase the size of the design portion 40 in the vertical direction. On the other hand, by setting the distance A from the first reference line k1 to the first design portion d1 to be equal to or less than the diameter of the game ball, it is possible to secure the visibility of the game ball from the front side when the game ball is strongly shot by the game ball launcher 430 and rolls along the outer peripheral surface ra of the guide path r2. As described above, since the pachinko machine 1 ensures the visibility of the game balls, the player is prevented from overlooking the game balls, and the game can be played normally. As a result, the game can be played stably.

Further, in the present embodiment, the first design portion d1 is arranged above (higher than) the second reference line k2. In particular, the distance (dimension) C from the second reference line k2 to the first design portion d1 is greater than or equal to the radius of the game ball (14 [mm] in this embodiment). Here, the distance C is the height difference between the position of the second reference line k2 and the position of the first design portion d1.
Furthermore, in the present embodiment, the second design portion d2 is arranged below (lower than) the second reference line k2. In particular, the distance (dimension) D from the second reference line k2 to the second design portion d2 is equal to or greater than the diameter of the game ball (22 [mm] in this embodiment). Here, the distance D is the height difference between the position of the second reference line k2 and the position of the second design portion d2.
Thus, in the present embodiment, the second design portion d2 is arranged below (lower than) the second reference line k2, and in particular, the distance D from the second reference line k2 to the second design portion d2 is equal to or greater than the diameter of the game ball, thereby making it possible to increase the size of the design portion 40 in the vertical direction. On the other hand, by setting the distance C from the second reference line k2 to the first design portion d1 to be equal to or greater than the radius of the game ball, the game ball is weakly launched by the game ball launching device 430, and when the game ball rolls along the inner peripheral surface rb of the guide passage r2, it is possible to ensure the visibility of the game ball from the front side. As described above, since the pachinko machine 1 ensures the visibility of the game balls, the player is prevented from overlooking the game balls, and the game can be played normally. As a result, the game can be played stably.

A board lamp 21 (see FIG. 3) is arranged in the game area 30 of the game board 11 . The board lamp 21 includes a plurality of light emitting elements (LEDs) driven by dynamic lighting control.
The main image display device 31 is attached to the back side of the set plate. The main image display device 31 is composed of a variable display device such as a liquid crystal display or a CRT (Cathode Ray Tube) display.
The main image display device 31 includes a display screen 31a capable of displaying various effects images (moving images and still images).
The display screen 31a can be configured with three first performance symbol display areas a1 to a3 (not shown) in which a first performance symbol z1 (not shown) is displayed, and one second performance symbol display area a4 (not shown) in which a second performance symbol z2 (not shown) is displayed.
The first production pattern z1 includes identification information (symbols) such as numbers, letters, symbols, and characters. In each of the first effect symbol display areas a1 to a3, it is possible to perform variable display and stop display of the first effect symbol z1. The second effect pattern z2 is composed of a color bar. In the second effect symbol display area a4, it is possible to perform variable display and stop display of the second effect symbol z2.

The variable display of the production patterns z1 and z2 means display in which the first production pattern z1 is moved (scrolled) in each of the first production pattern display areas a1 to a3, and the type of the second production pattern z2 displayed in the second production pattern display area a4 is changed (the color represented by the color bar is sequentially changed).
The stop display of the performance symbols z1 and z2 refers to a display in which the first performance symbol z1 of one type is stopped at the lottery result display positions of the respective first performance symbol display areas a1 to a3, and the second performance symbol z2 of one type is displayed in the second performance symbol display area a4 (the color bar represents a predetermined color).
Then, the result of the special pattern lottery (first special pattern lottery or second special pattern lottery) is displayed by combining the first performance pattern z1 stop-displayed in the three first performance pattern display areas a1 to a3 and the second performance pattern z2 stop-displayed in the second performance pattern display area a4.
Further, the display screen 31a can be configured with reserved pattern display areas b1 and b2 (not shown) in which reserved patterns h (not shown) are displayed.
In the pending symbol display area b1, the pending symbol h corresponding to the game information during the notification display (variation display and stop display of special symbols) is displayed. In the reserved symbol display area b2, a reserved symbol h corresponding to the game information whose notification display is being reserved is displayed.

The sub-image display device 32 is arranged on the front side of the main image display device 31 .
The sub-image display device 32 is composed of a variable display device such as a liquid crystal display or a CRT display. The sub-image display device 32 has a display screen 32a capable of displaying effect images.
The sub-image display device 32 can be vertically displaced (moved) by a driving mechanism (not shown). Specifically, the sub-image display device 32 can be displaced within a predetermined range including an origin position (see FIG. 2) and an effect position (not shown) below the origin position.
The sub image display device 32 arranged (displaced) at the origin position is arranged above the display screen 31a of the main image display device 31 and does not cover the display screen 31a. On the other hand, the sub-image display device 32 arranged (displaced) at the rendering position is arranged on the front side of the display screen 31a of the main image display device 31 and covers part of the display screen 31a.

A first start port 51 is provided below the display screen 31 a in the game area 30 . The first starting port 51 is a ball-entering port (so-called “navel”) that opens upward, and is always capable of entering a game ball. The first starting port 51 is capable of entering a game ball flowing down the left path (impossible to enter a game ball flowing down the right path).
In the first start port 51, a special figure 1 start port switch 101 (see FIG. 3) is arranged. The special figure 1 starting port switch 101 outputs a detection signal to the main control board 200 in response to the detection of the game ball entering the first starting port 51 (entering the game ball to the first starting port 51). The main control board 200 executes the first special symbol lottery according to the input of the detection signal from the special figure 1 starting port switch 101 .

On the left side of the first starting opening 51 in the game area 30, an upper left other winning opening 55, a middle left winning opening 56, and a lower left winning opening 57 are provided. Each of the other prize winning openings 55 to 57 is a ball entry opening that opens upward, and game balls can be entered at all times. Each of the other winning holes 55 to 57 allows entry of game balls flowing down the left path (impossibility of entry of game balls flowing down the right path).
The game board 11 is provided with a left winning slot switch 106 (see FIG. 3). The left winning port switch 106 outputs a detection signal in response to detection of a game ball entering the upper left other winning port 55 (a game ball entering the upper left other winning port 55), a game ball entering the left center other winning port 56 (a game ball entering the left center other winning port 56), and a game ball entering the lower left other winning port 57 (a game ball entering the lower left other winning port 57). Output for 0. The main control board 200 causes the game ball payout device 440 to execute a prize ball payout operation in response to the input of the detection signal from the left winning hole switch 106 .

A starting gate 41 is provided on the right side of the display screen 31 a in the game area 30 . The starting gate 41 is formed so that game balls can always pass through it. The starting gate 41 allows passage of game balls flowing down the right path (impossibility of passage of game balls flowing down the left path).
The starting gate 41 is provided with a gate switch 104 (see FIG. 3). The gate switch 104 outputs a detection signal to the main control board 200 in response to detection of a game ball passing through the start gate 41 (passage of the start gate 41 by the game ball). The main control board 200 executes a normal symbol lottery according to the input of the detection signal from the gate switch 104 .

A large winning opening 53 is provided below the starting gate 41 in the game area 30 . The big winning hole 53 is provided with a special electric accessory (special electric role) 53a (a so-called "attacker") capable of being displaced between a closed state in which a game ball cannot enter the big winning hole 53 and an open state in which a game ball can enter the big winning hole 53.例文帳に追加
The special electric accessory 53a is opened and closed by a special electric accessory solenoid 65 (see FIG. 3). The special electric accessory 53a is normally closed to the big winning port 53 to make it impossible to enter the game ball, but when the first special symbol lottery or the second special symbol lottery is won and a big win game state is generated, the special electric accessory 53a is opened to allow the entry of the game ball. The big winning opening 53 allows entry of game balls flowing down the right path (impossibility of entry of game balls flowing down the left path).
A count switch 103 (see FIG. 3) is arranged in the big winning opening 53 . The count switch 103 outputs a detection signal to the main control board 200 in response to detection of a game ball entering the big winning hole 53 (entering the game ball into the big winning hole 53). The main control board 200 causes the game ball payout device 440 to execute a prize ball payout operation in response to the input of the detection signal from the count switch 103 .

A second starting opening 52 is provided below the big winning opening 53 in the game area 30 . The second starting port 52 is provided with a normal electric accessory (ordinary electric member) 52a (so-called "electric tulip") that can be displaced between a closed state that makes it impossible for a game ball to enter the second starting port 52 and an open state that allows a game ball to enter the second starting port 52.例文帳に追加
The normal electric accessory 52a is opened and closed by a normal electric accessory solenoid 64 (see FIG. 3). In the second starting port 52, the normal electric accessory 52a is normally closed to make it impossible to enter the game ball, but when the normal pattern lottery is won, the normal electric accessory 52a is opened to allow the entry of the game ball. The second starting port 52 is capable of entering a game ball flowing down the right path (impossible to enter a game ball flowing down the left path).
Inside the second starting port 52, a special figure 2 starting port switch 102 (see FIG. 3) is arranged. The special figure 2 starting port switch 102 outputs a detection signal to the main control board 200 in response to the detection of the game ball entering the second starting port 52 (entering the game ball to the second starting port 52). The main control board 200 executes the second special symbol lottery according to the input of the detection signal from the special figure 2 starting port switch 102 .

A right other prize winning opening 54 is provided below the second start opening 52 in the game area 30 . The right other prize winning port 54 is a ball entrance opening upward, and game balls can be entered at all times. The right other prize winning port 54 is capable of entering a game ball flowing down the right path (impossible to enter a game ball flowing down the left path).
A right prize winning port switch 105 (see FIG. 3) is arranged in the right other prize winning port 54 . The right winning opening switch 105 outputs a detection signal to the main control board 200 in response to detection of a game ball that has entered the other right winning opening 54 (entrance of a gaming ball to the other right winning opening 54). The main control board 200 causes the game ball payout device 440 to execute a prize ball payout operation in response to the input of the detection signal from the right winning opening switch 105 .

At the lowest position in the game area 30, an out port 58 is provided for discharging game balls that have not entered (won a prize) in any of the winning ports 51-57.
Here, the inner frame unit 3 includes a discharge path (not shown) through which game balls discharged from the game area 30 pass. Specifically, the discharge path is attached to the back side of the inner frame of the inner frame unit 3 . The pachinko machine 1 is configured such that all game balls hit into the game area 30 (all game balls discharged from the game area 30) pass through the discharge path. That is, the game ball launched into the game area 30 is discharged from the game area 30 by entering one of the winning openings 51 to 57 or passing through the out opening 58 and flows into the discharge path.
Specifically, the game balls that have entered the winning holes 51 to 57 are guided to the discharge path after being detected by the switches 101 to 103, 105, 106 provided in the winning holes. Also, the game ball discharged from the out port 58 is guided to the discharge path.
The inner frame unit 3 is provided with an out switch 109 (see FIG. 3). Then, the out switch 109 outputs a detection signal to the main control board 200 in response to detection of a game ball passing through the discharge path (a game ball discharged from the game area 30). As a result, all game balls ejected from the game area 30 are detected by the out switch 109 .
Furthermore, in the game area 30, a plurality of nails (not shown) are arranged so as to guide the game balls to the respective prize winning openings 51 to 57 and the starting gate 41. As shown in FIG.

A main display device 60 is arranged on the game board 11 . The main display device 60 includes a plurality of lighting elements (segments). Each lighting element is composed of a light-emitting element (LED in this embodiment).
Information about the game is displayed on the main display device 60 .
The main display device 60 includes a special figure 1 display device, a special figure 2 display device, a normal figure display device, a special figure 1 reservation display device, a special figure 2 reservation display device, a normal figure reservation display device, a round display device, a right-handed display device, a probability variable display device, and a time reduction display device.
Specifically, the main display device 60 includes 32 lighting elements (LED1 to LED32).
In the main display device 60, LED1 to LED8 constitute a special figure 1 display device, LED7 to LED16 constitute a special figure 2 display device, LED17 and 18 constitute a general figure display device, LED19 to LED23 constitute a round display device, LED24 constitutes a right-handed display device, LED25 and 26 constitute a special figure 1 reservation display device, and LED27 and 28 constitute a special figure 2 reservation display device. , LEDs 29 and 30 constitute a normal figure holding display device, LED 31 constitutes a variable probability display device, and LED 32 constitutes a time saving display device.

The special figure 1 display device is capable of performing variable display and stop display of the first special symbol consisting of numbers, symbols, and the like. Then, in the special figure 1 display device, the result of the first special symbol lottery is displayed by the stopped and displayed first special symbol.
The special figure 2 display device is capable of performing variable display and stop display of the second special pattern consisting of numbers, patterns, and the like. Then, in the special figure 2 display device, the result of the second special symbol lottery is displayed by the stopped and displayed second special symbol.
Here, the display of the special symbol (first special symbol or second special symbol) in the special symbol display device and the display of the performance symbols z1 and z2 in the performance symbol display areas a1 to a4 are associated with each of the time when the variable display is started, the time when the stop display is started, and the lottery results indicated by the symbols stopped and displayed.
Then, when the first special pattern (stop pattern) stopped and displayed on the special figure 1 display device becomes a specific pattern (jackpot pattern), or when the second special pattern (stop pattern) stopped and displayed on the special figure 2 display device becomes a specific pattern (jackpot pattern), a big win game state which is a game state advantageous to the player is generated.

The normal pattern display device can perform variable display and stop display of normal patterns consisting of numbers, patterns, and the like. Then, in the normal pattern display device, the results of the normal pattern lottery are displayed by the stopped normal symbols. Then, when the normal pattern stop-displayed on the normal pattern display device becomes a specific pattern (normal pattern per pattern), the normal pattern per game state, which is a game state advantageous to the player, is generated.

The special figure 1 reservation display device displays the number of times the display of the lottery result of the first special symbol lottery is withheld (the number of special figure 1 reservations).
The special figure 2 reservation display device displays the number of times the display of the lottery result of the second special symbol lottery is withheld (the number of special figure 2 reservations).
The normal pattern lottery holding display device displays the number of times the display of the lottery result of the normal pattern lottery is held (normal pattern lottery number).
The round display device displays the number of round games executed during the jackpot game state (type of jackpot game state).
The right hitting display device displays the path (left path or right path) along which the game ball should be hit.
The variable probability display device displays the game state at the time of power return (while the special figure high probability state is occurring or the special figure low probability state is occurring).
The current game state (executing or stopping the time saving control) is displayed on the time saving display device.

Also, the pachinko machine 1 is provided with one or a plurality of movable units (not shown). In this embodiment, the front frame unit 4 is provided with one or more movable units, and the game board unit 10 is provided with one or more movable units.
Each movable body unit of the front frame unit 4 is arranged on the front surface of the design part 40, the upper surface of the receiving plate unit SU, etc., and is capable of performing a predetermined performance action.
Each movable unit of the game board unit 10 is attached to the front side of the set plate. Specifically, each movable body unit is arranged in a space (hereinafter referred to as “effect space”) between the game board 11 and the main image display device 31 (display screen 31a). Each movable body unit can perform a predetermined performance action in the performance space.
Each movable body unit includes an effect member, a drive mechanism, a drive source, and a position detection sensor 24 (see FIG. 3). In this embodiment, a motor 23 (see FIG. 3) is used as the drive source. The motor 23 is a stepping motor. Note that a configuration using a solenoid as a driving source may be employed.
The effect member can be displaced along a predetermined direction by a drive mechanism. Specifically, the effect member can be displaced to a plurality of positions including an initial position and a effect position. The effect member is driven (displaced) by a motor 23 .

The position detection sensor 24 is configured by a photosensor or the like. The position detection sensor 24 detects the position of the production member. Specifically, the position detection sensor 24 includes a light projecting section and a light receiving section that receives the light projected from the light projecting section. Then, the position detection sensor 24 outputs a detection signal to the effect control board 300 in accordance with the reception (detection) of the light projected from the light projecting unit by the light receiving unit. On the other hand, the position detection sensor 24 stops outputting the detection signal to the production control board 300 when the light receiving section does not receive (detect) the light projected from the light projecting section.
A shield plate is provided at a predetermined position of the effect member. Then, when the effect member is arranged at the initial position, the shielding plate is arranged between the light projecting part and the light receiving part of the position detection sensor 24 to block light from entering the light receiving part. Thereby, when the production member is arranged at the initial position, the output of the detection signal from the position detection sensor 24 to the production control board 300 is stopped. On the other hand, when the production member is not arranged at the initial position, a detection signal is output from the position detection sensor 24 to the production control board 300 .
Thereby, the effect control board 300 can detect whether or not the effect member is arranged at the initial position depending on the input state of the detection signal from the position detection sensor 24 .

Further, the pachinko machine 1 is provided with detection sensors for detecting various abnormal states.
In this embodiment, as detection sensors, a glass frame opening sensor 107, an inner frame opening sensor 108, a vibration detection sensor 113, a radio wave detection sensor 114, a magnetic detection sensor 115, and the like are arranged.
The glass frame opening sensor 107 detects opening of the front frame unit 4 with respect to the inner frame unit 3 . Then, the glass frame opening sensor 107 transmits a detection signal to the main control board 200 via the payout control board 400 according to the opening of the front frame unit 4 with respect to the inner frame unit 3 .
The inner frame open sensor 108 detects opening of the inner frame unit 3 with respect to the outer frame unit 2 . Then, the inner frame opening sensor 108 transmits a detection signal to the main control board 200 via the payout control board 400 according to the opening of the inner frame unit 3 with respect to the outer frame unit 2 .

The vibration detection sensor 113 detects vibration of the game board 11 . In this embodiment, the vibration detection sensor 113 is arranged on the game board 11 . Then, the vibration detection sensor 113 transmits a detection signal to the main control board 200 in response to detection of vibration of the game board 11 .
The radio wave detection sensor 114 detects radio waves generated around the game board 11 . In this embodiment, two radio wave detection sensors 114 are arranged on the game board 11 . Each radio wave detection sensor 114 transmits a detection signal to the main control board 200 in response to detection of radio waves.
The magnetism detection sensor 115 detects magnetism generated around the game board 11 . In this embodiment, three magnetic detection sensors 115 are arranged. Specifically, one magnetic detection sensor 115 is arranged in the inner frame unit 3 (discharge path). Also, two magnetic detection sensors 115 are arranged on the game board 11 . Then, the magnetic detection sensor 115 arranged in the inner frame unit 3 transmits a detection signal to the main control board 200 via the payout control board 400 in response to detection of magnetism. Further, each magnetic detection sensor 115 arranged on the game board 11 transmits a detection signal to the main control board 200 in accordance with detection of magnetism.

(Control system configuration)
Next, the configuration of the control system in the pachinko machine 1 will be described.
FIG. 3 is a block diagram showing the configuration of the control system of the pachinko machine. FIG. 6 is an address map of the memory area used by the CPU 210. As shown in FIG.
The pachinko machine 1 includes various control boards.
Specifically, as shown in FIG. 3, the pachinko machine 1 includes a main control board 200, an effect control board 300, a payout control board 400, and a plurality of control boards such as a power supply board 600, a driver board 330, a sub-connection board 340, etc. that supply power (electric power) to each of the control boards 200, 300, 400, and the like.
The plurality of control boards 200, 300, 400, 600 are independent (separate) circuit boards. Each control board 200, 300, 400, 600 is housed in a separate board case.
The main control board 200 and the performance control board 300 are included in the game board unit 10 . Specifically, the main control board 200 and the effect control board 300 are attached to the back side of the game board 11 .
The payout control board 400 is included in the inner frame unit 3 . Specifically, the payout control board 400 is attached to the back side of the inner frame included in the inner frame unit 3 .

(Configuration of main control board 200)
First, the configuration of the main control board 200 will be described.
The main control board 200 controls the progress of the game.
The main control board 200 includes a one-chip microcomputer (one-chip microcomputer), a clock generation circuit 202, a random number generation circuit 203, an input port 204, an output port 205, a performance display device 206, a RAM clear switch 207, a setting key switch 208, a sink driver 240, source drivers 250a and 250b, and the like.
A one-chip microcomputer is an LSI integrated with a CPU core, a register, a semiconductor memory, and the like. Specifically, the one-chip microcomputer includes a CPU 210, a ROM 220, a RAM 230, and the like.

The main control board 200 includes a memory area used by the CPU 210 . As shown in FIG. 6, the memory area used by the CPU 210 includes a memory area (0000H to 2FFFH) allocated to the ROM 220 and a memory area (F000H to F3FFH) allocated to the RAM 230 .
Here, in FIG. 6, addresses for specifying memory areas are shown in hexadecimal numbers ("H" indicates hexadecimal numbers).

The ROM 220 (memory area of the ROM 220) includes a used area m1 (0000H to 1A7AH) and an unused area m2 (2000H to 2BFFH).
The used area m1 includes a program area, an unused area, and a data area. The program area stores a program (program code) for controlling the progress of the game. The data area stores data (program data) for controlling the progress of the game. Note that the used area m1 may be configured without an unused area.

The unused area m2 includes a program area and a data area.
The program area stores a program (program code) for executing processing related to tests defined by gaming machine regulations, and a program (program code) for controlling the display of the performance display device 206 (specifically, calculating the base ratio). The data area stores data (program data) for executing processing related to tests defined by gaming machine regulations and data (program data) for controlling the display of the performance display device 206 .
In addition to the use area m1 and the non-use area m2, the ROM 220 also includes an unused area, a ROM comment area, a program management area, and the like.
Arbitrary data such as program titles and versions are stored in the ROM comment area. On the other hand, the program management area stores information necessary for the CPU 210 to execute various programs.
Further, in the ROM 220, an unused area m3 of predetermined bytes (for example, 16 bytes or more) is provided between the used area m1 and the unused area m2. This clarifies the boundary between the use area m1 and the non-use area m2.

The RAM 230 (memory area of the RAM 230) includes a used area M1 (F000H to F1FFH) and an unused area M2 (F300H to F3FFH).
The use area M1 includes a work area and a stack area.
The work area is used as an area for temporarily storing various data during execution of the program (program for controlling the progress of the game) stored in the use area m1. On the other hand, the stack area is used as an area for temporarily saving various data during execution of the program (program for controlling the progress of the game) stored in the use area m1. Note that the used area M1 may be configured without including an unused area.
Specifically, the work area includes a set value area, a gaming machine state flag area, a checksum area, a backup flag area, an error related area, a normal game related area 1, and a normal game related area 2.
A setting value is stored in the setting value area. A gaming machine status flag is stored in the gaming machine status flag area. A checksum is stored in the checksum area. A backup flag is stored in the backup flag area. Information about errors is stored in the error-related area. The normal game-related area 1 stores a sub-command pointer and the like. The normal game-related area 2 stores input/output data in the main control board 200, data for arithmetic processing, various counters (random number counter, timer counter, etc.), lottery results, flags for managing the game state, and the like. In particular, the normal game-related area 2 includes an area (game information storage area, which will be described later) for storing game information obtained by inputting a detection signal from each of the special figure 1 starter switch 101, the special figure 2 starter switch 102, and the gate switch 104.

The unused area M2 includes a work area and a stack area.
The work area is used as an area for temporarily storing various data during execution of a program stored in the non-use area m2 (a program for executing processing related to tests defined by gaming machine regulations, or a program for controlling the display of the performance display device 206). On the other hand, the stack area is used as an area for temporarily saving various data during the execution of a program stored in the non-use area m2 (a program for executing processing related to tests defined by game machine regulations or a program for controlling the display of the performance display device 206).
Specifically, the work area includes a performance display related area. The performance display related area is used as an area for temporarily storing various data during the execution of the program for controlling the display of the performance display device 206. FIG.
In addition, the RAM 230 is provided with an unused area M3 of predetermined bytes (16 bytes or more) between the used area M1 and the unused area M2. This clarifies the boundary between the use area M1 and the non-use area M2.

In this embodiment, it is permitted to refer to the data stored in the non-use area M2 in the process based on the program (program for controlling the progress of the game) stored in the use area m1.
On the other hand, it is prohibited to rewrite (change) the data stored in the non-use area M2 by processing based on the program (program for controlling the progress of the game) stored in the use area m1.
In addition, it is permitted to refer to the data stored in the use area M1 in the process based on the program stored in the non-use area m2 (the program for executing the process related to the test specified by the gaming machine regulations or the program for controlling the display of the performance display device 206).
On the other hand, the data stored in the use area M1 is prohibited from being rewritten (changed) by processing based on a program stored in the non-use area m2 (a program for executing processing related to the test defined by the game machine regulations or a program for controlling the display of the performance display device 206).
A game in the pachinko machine 1 can be progressed (completed) by a program (a program for controlling the progress of the game) stored in the use area m1.

The clock generation circuit 202 generates a clock (synchronization signal) at a predetermined clock frequency (12 [MHz] in this embodiment) and outputs this clock to the CPU 210 and the random number generation circuit 203 respectively.
The random number generation circuit 203 includes a first loop counter for generating winning random numbers for the normal symbol lottery, a second loop counter for generating big winning random numbers for the first special symbol lottery, a third loop counter for generating big winning random numbers for the second special symbol lottery, and a fourth loop counter for generating reach group random numbers.
The first loop counter updates the value of the loop counter by 1 within a predetermined range (within the range of 0 to 65535 in this embodiment) each time one clock is input from the clock generation circuit 202, thereby generating a winning random number for the normal symbol lottery. In this embodiment, the value of the first loop counter is updated every 0.083 [μs] (1 [s]/12 [MHz]=0.083 [μs]).
The second loop counter updates the value of the loop counter by one within a predetermined range (within the range of 0 to 65535 in this embodiment) each time one clock is input from the clock generation circuit 202, thereby generating a jackpot random number for the first special symbol lottery. In this embodiment, the value of the second loop counter is updated every 0.083 [μs] (1 [s]/12 [MHz]=0.083 [μs]).

The third loop counter updates the value of the loop counter by 1 within a predetermined range (within the range of 0 to 65535 in this embodiment) each time one clock is input from the clock generation circuit 202, thereby generating a jackpot random number for the second special symbol lottery. In this embodiment, the value of the third loop counter is updated every 0.083 [μs] (1 [s]/12 [MHz]=0.083 [μs]).
The fourth loop counter generates a reach group random number by updating the value of the loop counter by 1 within a predetermined range (0 to 10006 in this embodiment) each time 32 clocks are input from the clock generation circuit 202 (once when the clock frequency is divided by 32). In this embodiment, the value of the fourth loop counter is updated every 2.666 [μs] (32 [s]/12 [MHz]=2.666 [μs]).

The input port 204 includes a plurality of input ports (input port 0 to input port 3 in this embodiment).
Input port 0 receives a detection signal from the glass frame opening sensor 107, a detection signal from the inner frame opening sensor 108, a detection signal from the vibration detection sensor 113, a detection signal from the radio wave detection sensor 114, a detection signal from the magnetic detection sensor 115, and the like.
Input port 1 receives a RAM clear signal from RAM clear switch 207, a detection signal from setting key switch 208, a steering wheel detection signal from firing condition detector 422, and the like.
A detection signal from the count switch 103, a detection signal from the right winning slot switch 105, a detection signal from the left winning slot switch 106, a detection signal from the out switch 109, a detection signal from the other radio wave detection sensor 114, and the like are input to the input port 2.
To the input port 3, a detection signal from the special figure 1 starter switch 101, a detection signal from the special figure 2 starter switch 102, a detection signal from the gate switch 104, etc. are input.

Each input port (input port 0 to input port 3) is provided with a reception storage area corresponding to each switch/sensor (detection signal). In the reception storage area corresponding to each switch/sensor, 1-bit data indicating the reception state of the detection signal from the switch/sensor is set.
Specifically, in the reception storage area corresponding to each switch sensor, "1" is set when the detection signal from the switch sensor is input (high level), and "0" is set when the detection signal from the switch sensor is not input (low level).

The output port 205 includes a plurality of output ports (output port 0 to output port 4 in this embodiment).
The output port 0 outputs data signals (“SEGDATA0” to “SEGDATA7”) for controlling lighting of the main display device 60 . A data signal output from the output port 0 is input to the source driver 250a.
The output port 1 outputs common signals (“COM0” to “COM3”) for controlling lighting of the main display device 60 and the performance display device 206, and a launch enable signal for detecting launch conditions, which will be described later. A common signal output from the output port 1 is input to the sink driver 240 .

Output port 2 outputs an external signal. At this time, the external signal output from the output port 2 is input to the hall computer via the payout control board 400 and the external terminal board 450 .
The output port 3 outputs a control signal for controlling the drive of the normal electric accessory solenoid 64, a control signal for controlling the drive of the special electric accessory solenoid 65, and the like.
The output port 4 outputs data signals (“7SEGDATA0” to “7SEGDATA7”) for controlling lighting of the performance display device 206 . A data signal output from the output port 4 is input to the source driver 250b.

Also, the main control board 200 is configured to include a command output port 1 and a command output port 2 . Then, the CPU 210 transmits a control command (subcommand) from the command output port 1 to the effect control board 300 and transmits a control command (payout command) to the payout control board 400 from the command output port 2 .
Command output port 1 and command output port 2 each have a transmission data register (not shown), a FIFO (First In First Out) buffer (not shown), and a transmission shift register (not shown).
The transmission data register outputs the control command input based on the subcommand transmission processing (step S2-4), which will be described later, to the FIFO buffer.
The FIFO buffer is composed of multiple registers and is capable of storing multiple control commands. The FIFO buffer stores the control commands input from the transmission data register and outputs the stored control commands to the transmission shift register in the input order.
The transmission shift register performs parallel-serial conversion on the control command input from the FIFO buffer, and transmits it to the effect control board 300 or the payout control board 400 as serial data.

Performance display device 206 includes a plurality of lighting elements (segments). Each lighting element is composed of a light-emitting element (LED in this embodiment). It should be noted that the performance display device 206 is arranged on the back side of the game board 11, so that it cannot be visually recognized by the player.
As will be described later, in the pachinko machine 1, a game ready state, a setting change state, a setting confirmation state, a setting abnormality state, a RAM abnormality state, and a backup abnormality state are defined as states of the gaming machine (hereinafter referred to as "game machine state"). The information displayed on the performance display device 206 changes according to the gaming machine state that has occurred.

The performance display device 206 includes four (four-digit) display units (not shown). Each display is composed of eight lighting elements. That is, each display unit is composed of a 7-segment LED capable of displaying numbers, symbols, etc., and a dot-segment LED capable of displaying dots such as a decimal point.
Specifically, the performance display device 206 includes 32 lighting elements (LED33 to LED64). In the performance display device 206, LED33 to LED40 are the first digit display portion, LED41 to LED48 are the second digit display portion, LED49 to LED56 are the third digit display portion, and LED57 to LED64 are the fourth digit display portion.

The game can be played while the playable state is being generated. Then, the base ratio is displayed on the performance display device 206 while the playable state is occurring.
In this embodiment, the performance display device 206 alternately displays the first base ratio and the second base ratio every predetermined time (5.0 [s] in this embodiment) while the playable state is occurring.
The “first base ratio” is the base ratio of the current section (the base ratio calculated for the period from the start of the current section to the current time).
The “second base ratio” is the base ratio of the previous section (the final base ratio calculated for the previous section).
Specifically, in the performance display device 206, of the four-digit display section, the upper two-digit display section displays information for identifying the type of base ratio (first base ratio or second base ratio), and the lower two-digit display section displays a number indicating the base ratio (percentage).

While the setting change state is occurring, the setting value can be changed. While the setting change state is occurring, the performance display device 206 displays the setting values stored (set) in the setting value area of the RAM 230 .
Specifically, in the performance display device 206, information indicating that the setting change state is occurring is displayed by the display section of the upper three digits of the display section of the four digits (specifically, the upper first digit is "r", the upper second digit is "n.", and the upper third digit is "-").
While the setting confirmation state is occurring, the setting value can be confirmed. While the setting confirmation state is occurring, the performance display device 206 displays the setting values stored (set) in the setting value area of the RAM 230 .
Specifically, in the performance display device 206, information indicating that the setting confirmation state is occurring is displayed by the upper three-digit display section of the four-digit display section (specifically, the upper first digit is "r", the upper second digit is "n.", and the upper third digit is not displayed), and the least significant one-digit display section displays a number indicating the setting value stored in the setting value area.

The game cannot progress while the game stop state (setting error state, RAM error state, and backup error state) is occurring. Then, while the game stop state is occurring, the performance display device 206 displays an error code corresponding to the abnormality that has occurred.
Specifically, in the performance display device 206, of the four-digit display section, the upper three-digit display section displays information indicating that a game stoppage is occurring (specifically, "E" in the upper first digit, "r." in the upper two digits, and no display in the upper third digit), and the display section with the lowest one digit displays a number indicating an error code corresponding to an abnormality that has occurred (setting abnormal state, RAM abnormal state, or backup abnormal state).

The RAM clear switch 207 is a tactile switch. In other words, the RAM clear switch 207 includes an operation unit that can be pressed. The RAM clear switch 207 outputs a RAM clear signal to the input port 1 when the operation unit is pressed.
The setting key switch 208 is a key lock switch. In other words, the setting key switch 208 includes an operation section provided with a keyhole. The operation unit is unlocked by inserting a special key into the keyhole, and can be rotated (switched) from the OFF state to the ON state. The setting key switch 208 outputs a detection signal to the input port 1 when the operation unit is in the ON state.

The sink driver 240 controls the output of common signals to the respective display devices 60 and 206 according to the common signals (“COM0” to “COM3”) output from the output port 1. FIG.
The source driver 250a controls the output of data signals to the main display device 60 according to the data signals (“SEGDATA0” to “SEGDATA7”) output from the output port 0. FIG.
The source driver 250b controls the output of data signals to the performance display device 206 according to the data signals (“7SEGDATA0” to “7SEGDATA7”) output from the output port 4. FIG.

In the pachinko machine 1, a source driver 250a corresponding to the main display device 60 and a source driver 250b corresponding to the performance display device 206 are provided. Application of the power supply voltage Vcc to the data signal lines is individually controlled by the main display device 60 and the performance display device 206 .
On the other hand, in the pachinko machine 1, a sink driver 240 common to the main display device 60 and the performance display device 206 is provided. Grounding of the common signal line is collectively controlled by the main display device 60 and the performance display device 206 .
This eliminates the need to provide the sink driver 240 corresponding to each of the main display device 60 and the performance display device 206. As a result, the need to provide output ports (output ports for outputting common signals) corresponding to each of the main display device 60 and the performance display device 206 is eliminated.
Therefore, it is possible to reduce the number of components required to control the lighting of the main display device 60 and the performance display device 206. In addition, the main control board 200 (CPU 210) does not need to generate common signals corresponding to the main display device 60 and the performance display device 206, respectively, and the control load for controlling the lighting of the main display device 60 and the performance display device 206 can be reduced.

The main control board 200 also includes a test signal output circuit (not shown).
In the test signal output process (step S4-24) to be described later, the CPU 210 generates test information (test signal) indicating an internal state (jackpot game state, execution state of time saving control, special symbol lottery probability state, etc.), and stores the generated test signal in the port output request buffer of the RAM 230. As a result, the test signal stored in the port output request buffer is output from the predetermined output port. A test signal output from a predetermined output port is input to an interface board of a test computer (not shown) via a test signal output circuit.
In addition, in the main control board 200, the detection signal from the special figure 1 starter switch 101, the detection signal from the special figure 2 starter switch 102, the detection signal from the gate switch 104, the detection signal from the count switch 103, the detection signal from the right winning opening switch 105, the detection signal from the left winning opening switch 106, the detection signal from the out switch 109, etc. is entered.
Furthermore, in the main control board 200, a control signal for controlling the driving of each solenoid (ordinary electric accessory solenoid 64, special electric accessory solenoid 65, etc.) output from the output port 3 is input to each solenoid 64, 65 and input to the interface board of the computer for testing via the test signal output circuit.

(Configuration of payout control board 400)
Next, the configuration of the payout control board 400 will be described.
FIG. 4 is a block diagram showing the configuration of the firing condition detection circuit and the firing control circuit.
The payout control board 400 controls the shooting of game balls to the game area 30 and the payout of game balls.
The payout control board 400 includes a one-chip microcomputer.
A one-chip microcomputer is an LSI integrated with a CPU core, a register, a semiconductor memory, and the like. Specifically, a one-chip microcomputer includes a CPU, a ROM, a RAM, and the like.
The payout control board 400 controls the game ball payout operation (prize ball payout operation) by the game ball payout device 440 based on the control command received from the main control board 200 . Also, the payout control board 400 controls the game ball payout operation (rental ball payout operation) by the game ball payout device 440 based on the ball lending instruction signal received from the CR unit 700 .
In addition, the payout control board 400 controls the game ball shooting operation by the game ball shooting device 430 (shooting solenoid 431) based on the resistance value (voltage value) input from the shooting volume 411, the touch signal input from the touch sensor 412, the firing stop signal input from the firing stop switch 413, the firing permission signal input from the main control board 200, and the CR connection signal input from the CR unit 700.
Hereinafter, a method for controlling the game ball shooting operation by the payout control board 400 will be described in detail.

As shown in FIG. 4, the payout control board 400 includes a launch condition detection circuit 420 and a launch control circuit 425 as circuits for controlling the game ball payout operation.
The firing condition detection circuit 420 is a circuit that detects establishment of firing conditions, which will be described later.
The firing condition detection circuit 420 includes an operation detection section 421 , a firing condition detection section 422 and a firing condition detection section 423 .
The operation detection unit 421 is a circuit that detects a rotation operation (amount of rotation operation) of the handle operation unit.
The operation detection unit 421 includes an operational amplifier that controls the output of the operation detection signal (makes the operation detection signal high level or low level) according to the resistance value (voltage value) of the emission volume 411 .

Specifically, in the firing handle unit 6, the resistance value of the firing volume 411 changes according to the amount of rotation operation of the handle operation section. Then, the operation detection unit 421 detects the resistance value (voltage value) of the firing volume 411, and based on the detected resistance value (voltage value), the presence or absence of the rotation operation of the handle operation unit and the amount of rotation operation of the handle operation unit.
Then, the operation detection unit 421 generates an operation detection signal while detecting a rotation operation of the handle operation unit, and outputs the generated operation detection signal to the firing enable condition detection unit 422 (makes the operation detection signal high level). On the other hand, the operation detection unit 421 stops outputting the operation detection signal to the firing enable condition detection unit 422 (makes the operation detection signal low level) when the rotation operation of the handle operation unit is not detected.
Further, the operation detection unit 421 generates a firing intensity signal corresponding to the amount of rotation operation of the handle operation unit (the resistance value of the firing volume 411) while detecting the rotation operation of the handle operation unit, and outputs the generated firing intensity signal to the firing control circuit 425.

The firing enable condition detection unit 422 is a circuit that detects establishment of the firing enable condition.
The firing enable condition detection unit 422 includes an AND gate IC (logic IC) that controls the output/stop of a predetermined signal according to the AND operation result of the operation detection signal, the touch signal, and the firing stop signal, and a transistor that switches the output/stop of the steering wheel detection signal according to the predetermined signal output from the AND gate IC.
The "fireable condition" is a condition related to the player's operation (player's intention) among a plurality of conditions constituting the later-described firing condition.
The firing enable condition includes (1) a condition based on the detection status of the firing volume 441 and the operation detection unit 421 (detection status of the rotation operation of the handle operation part), (2) a condition based on the detection status of the touch sensor 412 (detection status of contact with the handle operation part by the player), and (3) a condition based on the detection status of the fire stop switch 413 (detection status of the press operation of the fire stop button).

In the present embodiment, the firing enable condition is established when all of the following conditions are satisfied: (1) the firing volume 441 and the operation detection unit 421 have detected the rotating operation of the handle operation unit, (2) the touch sensor 412 has detected the player's contact with the handle operation unit, and (3) the firing stop switch 413 has not detected the pressing operation of the firing stop button. On the other hand, when at least one of the conditions (1) to (3) is not satisfied, the condition for enabling shooting is not satisfied.
Here, the firing enable condition may include (1) a condition based on the detection status of the firing volume 441 and the operation detection unit 421 (detection status of the rotation operation of the handle operation part), (2) a condition based on the detection status of the touch sensor 412 (detection status of contact with the handle operation part by the player), and (3) a configuration that does not include a condition based on the detection status of the fire stop switch 413 (detection status of the pressing operation of the fire stop button).
In other words, a configuration may be adopted in which the firing enable condition is satisfied when both of (1) the firing volume 441 and the operation detection unit 421 detect a rotation operation of the handle operation unit, and (2) the touch sensor 412 detects the player's contact with the handle operation unit, and the firing enable condition is not satisfied when at least one of the conditions (1) and (2) is not satisfied.

Specifically, the firing enable condition detection unit 422 detects whether or not the firing enable condition is established based on the operation detection signal input from the operation detection unit 421, the touch signal input from the touch sensor 412, and the firing stop signal input from the firing stop switch 413.
At this time, the firing condition detection unit 422 detects that the firing condition is established when all of the operation detection signal, the touch signal, and the firing stop signal are input. On the other hand, when at least one signal among the operation detection signal, the touch signal, and the firing stop signal is not input, the fulfillment of the firing enable condition is not detected.
The firing condition detection unit 422 generates a handle detection signal when detecting the establishment of the firing condition, and outputs the generated handle detection signal to each of the main control board 200 and the firing condition detection unit 423 (sets the handle detection signal to high level). On the other hand, the firing condition detection unit 422 stops outputting the handle detection signal to each of the main control board 200 and the firing condition detection unit 423 (sets the handle detection signal to a low level) when it does not detect that the firing condition is satisfied.

The firing condition detection unit 423 is a circuit that detects establishment of firing conditions.
The firing condition detection unit 423 includes an AND gate IC (logic IC) that controls the output/stop of the firing signal in accordance with the AND operation result of the handle detection signal, the firing permission signal, and the CR connection signal.
The "shooting condition" is a condition for shooting a game ball (game ball shooting operation) to the game area 30 by the game ball shooting device 430 (shooting solenoid 431).
In this embodiment, the firing condition is met when all of the following conditions are met: (1) the firing enable condition is satisfied, (2) the firing permission signal is input from the main control board 200, and (3) the CR connection signal is input from the CR unit 700. On the other hand, when at least one of the conditions (1) to (3) is not satisfied, the launch condition is not established.
The "fire permission signal" is output from the main control board 200 to the firing condition detection unit 423 when a playable state is set on the premise that communication between the main control board 200 and the payout control board 400 is possible (the main control board 200 and the payout control board 400 are electrically connected).

Here, a configuration may be adopted in which the firing enable signal is output from the main control board 200 to the firing condition detection section 423 while the main control board 200 is powered on regardless of the state of the gaming machine. That is, when communication is possible between the main control board 200 and the payout control board 400 (when the main control board 200 and the payout control board 400 are electrically connected), the firing permission signal may be configured to be output from the main control board 200 to the firing condition detection unit 423.
The “CR connection signal” is output from the CR unit 700 to the firing condition detection section 423 when communication between the CR unit 700 and the payout control board 400 is possible (when the CR unit 700 and the payout control board 400 are electrically connected).

Specifically, the firing condition detection unit 423 detects whether or not the firing condition is established based on the handle detection signal input from the firing enable condition detection unit 422, the firing permission signal input from the main control board 200, and the CR connection signal input from the CR unit 700.
At this time, the firing condition detector 423 detects that the firing condition is established when all of the handle detection signal, the firing permission signal, and the CR connection signal are input. On the other hand, when at least one signal among the handle detection signal, the firing permission signal, and the CR connection signal is not input, the fulfillment of the firing condition is not detected.
The firing condition detector 423 generates a firing signal while detecting that the firing condition is established, and outputs the generated firing signal to the firing control circuit 425 (making the firing signal high level). On the other hand, the firing condition detector 423 stops outputting the firing signal to the firing control circuit 425 (makes the firing signal low level) when it does not detect that the firing condition is met.

The shooting control circuit 425 is a circuit that controls the shooting intensity of the game ball by the game ball shooting device 430 and the shooting timing of the game ball by the game ball shooting device 430 . That is, the shooting control circuit 425 controls the output of the drive signal to the game ball shooting device 430 (shooting solenoid 431).
Specifically, the firing control circuit 425 includes a clock generating section (not shown), a firing timing control section (not shown), and a firing solenoid driving section (not shown).
The clock generator outputs a clock signal of a predetermined frequency to the launch timing controller.
The firing timing control section generates a pulse signal for controlling firing timing based on the clock signal input from the clock generating section, and outputs the generated pulse signal to the firing solenoid driving section. At this time, the launch timing control section generates a pulse signal so that the number of game balls launched per minute is a predetermined number (for example, 100 [balls]).
The firing solenoid drive section controls the output of the drive signal to the firing solenoid 431 based on the firing signal input from the firing condition detection section 423, the pulse signal input from the firing timing control section, and the firing intensity signal input from the operation detection section 421.
Specifically, when the firing signal is input from the firing condition detection unit 423, the firing solenoid driving unit receives a pulse signal from the firing timing control unit as a trigger. As a result, the game ball is shot with an intensity corresponding to the shot intensity signal input from the operation detection section 421 .
On the other hand, the firing solenoid drive section stops outputting the drive signal to the firing solenoid 431 when the firing signal is not input from the firing condition detection section 423 . As a result, the shooting of the game ball is stopped.

The game ball shooting device 430 includes a ball-striking mallet (not shown) and a shooting solenoid 431 for driving the ball-striking mallet. The firing solenoid 431 is composed of a rotary solenoid. Here, the ball hitting mallet may be driven by another driving source such as a motor.
A game ball is supplied to the game ball launcher 430 from a ball feeding unit (not shown). Then, when a drive signal is input to the shooting solenoid 431, the shooting solenoid 431 is driven according to the input drive signal, and a game ball is shot out by the ball hitting mallet. As a result, the game ball is shot to the game area 30. - 特許庁

As described above, in the pachinko machine 1, on the premise that the main control board 200 is set to a playable state, and that communication is possible between the CR unit 700 and the payout control board 400, when the handle operation unit is rotated (displaced from the initial position toward the limit position side) by the player's contact without pressing the discharge stop button, the game ball shooting operation by the game ball shooting device 430 is started. During execution of the game ball shooting operation by the game ball shooting device 430, the game ball is shot to the game area 30 with strength corresponding to the amount of rotation operation of the handle operation section.
Further, when the shooting stop button is pressed, the game ball shooting operation by the game ball shooting device 430 is stopped. That is, even when the handle operation portion is rotated by the player's contact, the game ball shooting operation by the game ball shooting device 430 is stopped when the shooting stop button is pressed.
Furthermore, when the handle operation portion is returned to the initial position (when the handle operation portion is not rotated), the game ball shooting operation by the game ball shooting device 430 is stopped. In other words, even when the player is in contact with the handle operating portion, the shooting operation of the game ball by the game ball shooting device 430 is stopped when the handle operating portion is returned to the initial position.

In particular, in the pachinko machine 1, the output of the handle detection signal to the main control board 200 from the ready-to-launch condition detector 422 is maintained while the ready-to-launch condition is satisfied (hereinafter referred to as the "ready-to-launch state").
That is, while the rotation operation of the handle operation unit is detected, the contact with the handle operation unit is detected, and the pressing operation of the firing stop button is not detected (fireable state), the output of the handle detection signal from the firing condition detection circuit 420 to the main control board 200 is maintained.
At this time, as long as the firing ready state is occurring, regardless of whether or not a firing permission signal is input from the main control board 200 to the firing condition detection circuit 420 (regardless of the gaming machine state set in the main control board 200), the output of the handle detection signal from the firing condition detection circuit 420 to the main control board 200 is maintained.
Also, as long as the firing ready state is occurring, regardless of whether or not a CR connection signal is input from the CR unit 700 to the firing condition detection circuit 420 (regardless of whether communication is possible between the CR unit 700 and the payout control board 400), the output of the handle detection signal from the firing condition detection circuit 420 to the main control board 200 is maintained.
As described above, the main control board 200 can detect (grasp) whether or not the ready-to-fire state is occurring, and can control the progress of the game, the contents of the presentation, etc. according to the state of occurrence of the ready-to-fire state.

That is, when the main control board 200 detects that the handle detection signal has changed from the non-input state to the input state (the handle detection signal has changed from a low level to a high level), it transmits a game situation designation command designating generation (start) of a firing ready state to the presentation control board 300. - 特許庁
On the other hand, when the main control board 200 detects that the handle detection signal has changed from the input state to the non-input state (the handle detection signal has changed from high level to low level), the main control board 200 transmits a game situation designation command for designating cancellation (end) of the firing ready state to the performance control board 300. - 特許庁
Thereby, the performance control board 300 can detect the generation of the ready-to-fire state by receiving the game situation designation command designating the generation of the ready-to-fire state, and can detect the cancellation of the ready-to-fire state by receiving the game state designation command to designate the cancellation of the ready-to-fire state.
Then, the effect control board 300 can change the content of the effect depending on whether or not the state of being ready to be fired is occurring.

(Configuration of production control board 300)
Next, the configuration of the effect control board 300 will be described.
FIG. 5 is a block diagram showing the configuration of the effect control board. FIG. 52 is a block diagram showing the structure of a sound circuit. FIG. 54 is a diagram showing channel router settings.
The effect control board 300 controls effects (display effects, sound effects, lamp effects, movable object effects, etc.) based on control commands received from the main control board 200 .
As shown in FIG. 5 , the effect control board 300 includes a microcomputer (one-chip microcomputer) 301 and various external devices externally connected to the microcomputer 301 .
In this embodiment, various external devices include a control ROM 302, a CGROM (Character Generator Read Only Memory) 303, a DRAM (Dynamic Random Access Memory) 304, a digital amplifier 305, and the like.

The control ROM 302 stores a control program for controlling the operation of the microcomputer 301, various data necessary for executing the control program, various command lists set in the control register of the sound circuit 323, various operating parameters (such as frequency correction parameters) to be transmitted to the digital amplifier 305, and the like. In particular, the control ROM 302 stores (memorizes) performance scenario data corresponding to each performance number, animation table corresponding to each display performance number, command list corresponding to each sound performance control number, various compressed lamp drive data, and various compressed motor drive data.
The "compressed lamp driving data" is data obtained by compressing (encoding) the lamp driving data in a predetermined format. "Lamp drive data" is data for driving various lamps 20 and 21 (data specifying luminance values of lamps 20 and 21 belonging to each system).
The "compressed motor drive data" is data obtained by compressing (encoding) the motor drive data in a predetermined format. "Motor driving data" is data for driving various motors 23 (data defining the output value of each motor 23).
In this embodiment, a NOR flash memory (NOR ROM) is used as the control ROM 302 . Here, as the control ROM 302, an EEPROM (Electrically Erasable Programmable Read Only Memory) may be used.
Control ROM 302 is connected to HOST interface 313 of microcomputer 301 .

The CGROM 303 stores (stores) various compressed image data, various compressed audio data, and the like.
"Compressed image data" is data obtained by compressing (encoding) image data (material data) in a predetermined format. "Image data (material data)" is data of an image (moving image/still image) that is a material for drawing processing.
"Compressed audio data" is data obtained by compressing (encoding) audio data in a predetermined format. “Audio data” is audio data output from various speakers 22 .
In this embodiment, a NAND flash memory (NAND ROM) is used as the CGROM 303 . Specifically, the CGROM 303 is configured by an SSD (Solid State Drive) using a NAND flash memory as a storage unit.
CGROM 303 is connected to CG bus interface 314 of microcomputer 301 . The CG bus interface 314 is a SATA (Serial AT Attachment) standard connection interface. As a result, various data stored in the CGROM 303 are read by SATA transfer.

The DRAM 304 is provided with a preload area. Various data (specifically, compressed image data, compressed audio data, etc.) stored in the CGROM 303 are transferred (preloaded) to the preload area.
Further, the DRAM 304 is provided with a drawing command buffer area. In this embodiment, the drawing command buffer area adopts a double buffering method, and the DRAM 304 is provided with two drawing command buffer areas.
The two drawing command buffer areas are configured with the same size. While one of the two drawing command buffer areas is designated as the construction area, the other drawing command buffer area is designated as the transfer area. Designation of the construction area and designation of the transfer area are alternately switched for each drawing command buffer area for each frame.
Then, for each drawing command buffer area, a display list, which will be described later, is stored (generated/constructed) in the drawing command buffer area during the period designated as the construction area, and the display list stored in the drawing command buffer area is transferred to the VDP (specifically, the preloader circuit 319) during the period designated as the transfer area.
DRAM 304 is connected to DRAM interface 315 of microcomputer 301 .

A microcomputer 301 is an LSI integrated with a CPU core, a register, a semiconductor memory, and the like.
The microcomputer 301 controls production operations by various production means based on control commands received from the main control board 200 .
"Various rendering means" includes various image display devices 31 and 32, various speakers 22, various lamps 20 and 21, and various motors 23 (various movable bodies). Therefore, the "effect operations by various effect means" include display of effect images by various image display devices 31 and 32, output of sound by various speakers 22, driving (lighting) of various lamps 20 and 21, driving of various motors 23 (various movable bodies), and the like.
The microcomputer 301 includes internal devices such as a CPU 310 , a CPU work memory 311 , a CPU interface 312 , a host interface 313 , a CG bus interface 314 , a DRAM interface 315 , a VRAM 316 , a serial communication controller 317 , a transfer circuit 318 , a preloader circuit 319 , a display circuit 320 , a graphics decoder circuit 321 , a drawing circuit 322 and a sound circuit 323 . Configured.

The CPU 310 is connected to the HOST interface 313 via the CPU interface 312 . The HOST interface 313 is also connected to the main control board 200 and receives control commands from the main control board 200 . Furthermore, a data bus 324 is connected to the HOST interface 313 .
This allows the CPU 310 to receive control commands (sub-commands) from the main control board 200 via the HOST interface 313 .
Also, the CPU 310 can communicate with internal devices such as a serial communication controller 317 , a preloader circuit 319 , a display circuit 320 and a sound circuit 323 via the HOST interface 313 and data bus 324 .
The CPU 310 can also read various data (control programs, control data, etc.) stored in the control ROM 302 via the HOST interface 313 .
The CPU 310 can also read various data (compressed audio data) stored in the CGROM 303 via the HOST interface 313 , data bus 324 and CG bus interface 314 .
Furthermore, the CPU 310 can execute data reading/writing with respect to the DRAM 304 via the HOST interface 313 , data bus 324 and DRAM interface 315 .

The CPU 310 executes various kinds of arithmetic processing required to control the performance operations by various kinds of performance means, control processing of internal devices according to the various kinds of arithmetic processing, and the like.
At this time, the CPU 310 uses the CPU work memory (RAM) 311 and the DRAM 304 as a work area for various arithmetic processing, a buffer area for various arithmetic processing data, a table data area, a buffer area for various input/output data, and the like.
That is, the CPU 310 selects the effect (effect number) to be executed based on the control command received from the main control board 200, and selects and sets the effect scenario data corresponding to the selected effect number. In addition, according to the selected/set production scenario data, instruction information (internal commands) for controlling various internal devices (VDP, sound circuit 323, lamp controller 317a, motor controller 317b, etc.) is sequentially generated.

Specifically, CPU 310 sets the animation table in the animation table setting area according to the instruction information. Then, according to the set animation table, a display list is generated in the drawing command buffer area specified in the construction area.
A "display list" is a collection of drawing commands for one frame. That is, the display list describes drawing commands for one frame in a predetermined order. Then, in VDP, drawing data for one frame is generated by executing processing based on each drawing command in the order described in the display list.
The "drawing command" is information specifying the content of the drawing process (drawing control) to be executed by the VDP. In particular, the drawing command specifies the address of the storage area where the compressed image data used for drawing is stored (hereinafter referred to as "image address"), the magnification (enlargement/reduction) when drawing the image data, the coordinates (coordinates in the frame buffer area) for drawing the image data, the transmittance (transparency, transparency, transparency) when drawing the image data, and the like.

Also, the CPU 310 transfers (preloads) the compressed audio data stored in the CGROM 303 to the preload area of the DRAM 304 when the power is turned on.
That is, the NAND type flash memory such as the CGROM 303 is easier to increase the capacity than the NOR type flash memory such as the control ROM 302, but the data reading speed is slow. Therefore, if the compressed audio data is read directly from the CGROM 303 (NAND type flash memory) when the sound circuit 323 executes the audio output process, the processing performance may drop significantly.
Therefore, in the pachinko machine 1, the compressed audio data stored in the CGROM 303 is transferred to the DRAM 304, which is a storage means having a faster data read speed than the CGROM 303, before the audio output processing is executed. By adopting a configuration in which the compressed audio data is read from the DRAM 304 when the audio output process is executed, deterioration in processing performance is prevented.

Specifically, when the power is turned on, the CPU 310 transfers (preloads) predetermined compressed audio data among the compressed audio data stored in the CGROM 303 to the preload area of the DRAM 304 . At this time, in this embodiment, all compressed audio data stored in the CGROM 303 are transferred to the preload area of the DRAM 304 . Here, part of the compressed audio data stored in the CGROM 303 may be transferred to the preload area of the DRAM 304 .
After the transfer of the predetermined compressed audio data is completed, the pachinko machine 1 enters a state in which it is possible to control the output of audio from the various speakers 22 (audio output processing by the sound circuit 323). In other words, before the transfer of the predetermined compressed audio data is completed, it becomes impossible to control the output of audio from the various speakers 22 (audio output processing by the sound circuit 323).
Further, after the transfer of the predetermined compressed audio data is completed, the various image display devices 31 and 32 are ready to control the display of effect images (drawing processing by VDP). In other words, before the transfer of the predetermined compressed audio data is completed, the various image display devices 31 and 32 cannot control the display of effect images (drawing processing by VDP).
On the other hand, before the transfer of the predetermined compressed audio data is completed, it becomes possible to control the driving (emission) of the various lamps 20 and 21 (lamp driving processing by the lamp controller 317a).
Further, before the transfer of the predetermined compressed audio data is completed, it becomes possible to control the driving of the various motors 23 (various movable bodies) (motor driving processing by the motor controller 317b).

The transfer circuit 318 transfers various data between internal devices.
Specifically, the transfer circuit 318 transfers the display list stored in the drawing command buffer area designated as the transfer area to the preloader circuit 319 . The transfer circuit 318 also transfers the display list rewritten by the preloader circuit 319 to the drawing circuit 322 .

The VRAM 316 is provided with an image expansion area. Image data (material data) developed (restored/decoded) by the graphics decoder circuit 321 is temporarily stored in the image development area.
In addition, the VRAM 316 is provided with a frame buffer area. In this embodiment, a double buffering method is adopted for the frame buffer area, and two frame buffer areas are provided in the VRAM 316 .
The two frame buffer areas are configured with the same size. While one of the two frame-buffer areas is designated as the drawing area, the other frame-buffer area is designated as the output area. Designation of the drawing area and designation of the output area are alternately switched for each frame buffer area for each frame.
For each frame buffer area, drawing data for one frame is stored (generated and drawn) in the frame buffer area during the period designated as the drawing area, and a video signal is output based on the drawing data for one frame stored in the frame buffer area during the period designated as the output area.

In the microcomputer 301, the preloader circuit 319, display circuit 320, graphics decoder circuit 321, rendering circuit 322, etc. function as a VDP (Video Display Processor).
The VDP controls display of effect images by various image display devices 31 and 32 . Specifically, the VDP generates drawing data in response to receiving a display list (drawing command) from the CPU 310, generates a video signal based on the generated drawing data, and outputs the generated video signal to various image display devices 31 and 32.
The preloader circuit 319 can read out various data (compressed image data) stored in the CGROM 303 via the CG bus interface 314 .
In particular, the preloader circuit 319 transfers (preloads) the compressed image data stored in the CGROM 303 to the preload area of the DRAM 304 before the rendering process by the rendering circuit 322 is executed.
That is, as described above, the NAND type flash memory such as the CGROM 303 is easier to increase the capacity than the NOR type flash memory such as the control ROM 302, but the data reading speed is slow. Therefore, if the compressed image data is read directly from the CGROM 303 (NAND flash memory) when the drawing circuit 322 executes drawing processing, the processing performance may be significantly reduced.
Therefore, in the pachinko machine 1, the compressed image data previously stored in the CGROM 303 is transferred to the DRAM 304, which is a storage means having a faster data read speed than the CGROM 303, before the drawing process is executed. By adopting a configuration in which the compressed image data is read from the DRAM 304 when the drawing process is executed, the deterioration of the processing performance is prevented.

Specifically, each time the preloader circuit 319 receives a display list, the preloader circuit 319 transfers (preloads) one frame of compressed image data specified by the display list among the compressed image data stored in the CGROM 303 to the preload area of the DRAM 304. At this time, the preloader circuit 319 rewrites the display list.
That is, in the display list generated by the CPU 310, an address specifying a storage area of the CGROM 303 is described as an image address included in each drawing command. Therefore, for each drawing command included in the display list, the preloader circuit 319 transfers the compressed image data stored in the storage area (storage area of the CGROM 303) specified by the image address included in the drawing command to a predetermined area of the DRAM 304, and then rewrites the image address included in the drawing command to an address that specifies the storage area after transfer (the predetermined area of the DRAM 304). As a result, a new display list with rewritten image addresses is generated.
In this embodiment, the preloader circuit 319 transfers (preloads) the compressed image data stored in the CGROM 303 to the preload area of the DRAM 304 . However, the preloader circuit 319 may transfer the compressed image data stored in the CGROM 303 to a predetermined area (preload area) of the VRAM 316 .
The display list rewritten by the preloader circuit 319 is transferred to the drawing circuit 320 by the transfer circuit 318 .

The drawing circuit 322 stores (generates/renders) drawing data for one frame in the frame buffer area designated as the drawing area according to the display list received from the preloader circuit 319 .
Specifically, every time the drawing circuit 320 receives a display list, it reads out from the DRAM 304 one frame of compressed image data specified in the display list. One frame of compressed image data read from the DRAM 304 is restored (decoded/decoded) by the graphic decoder circuit 321 and stored (expanded) in the image expansion area of the VRAM 316 . The rendering circuit 320 then uses the image data stored in the image rendering area to generate rendering data for one frame in the frame buffer area designated as the rendering area.

The display circuit 320 generates a video signal based on drawing data for one frame stored (generated and drawn) in a frame buffer area designated as an output area, and outputs the generated video signal to various image display devices 31 and 32. In this embodiment, digital RGB signals are output as video signals. Here, a configuration in which an LVDS (Low voltage differential signaling) signal is output as the video signal may be employed.
Specifically, the display circuit 320 includes a data acquisition circuit (not shown), a scaler circuit (not shown), a color correction circuit (not shown), a ditherer circuit (not shown), a synchronization signal generation circuit (not shown), and the like.
The data acquisition circuit reads the drawing data stored in the frame buffer area designated as the output area.
The scaler circuit can apply scaling processing (enlargement processing/reduction processing) to the drawing data read by the data acquisition circuit.

The color correction circuit can apply color correction processing to the drawing data processed by the scaler circuit.
The ditherer circuit can apply dithering processing to the drawing data processed by the color correction circuit.
The drawing data after processing by the dithering circuit is output as a video signal (digital RGB signal).
A synchronization signal generation circuit generates a horizontal synchronization signal and a vertical synchronization signal (Vsync). Then, the synchronizing signal generation circuit outputs the generated horizontal synchronizing signal and vertical synchronizing signal to various image display devices 31 and 32 . Also, the synchronization signal generation circuit outputs the generated vertical synchronization signal to the CPU 310 .
Here, in the present embodiment, the display of the effect image (the display of the effect image based on drawing data for one frame) on each of the image display devices 31 and 32 is updated every 16.66 [ms]. Therefore, the synchronization signal generation circuit outputs a vertical synchronization signal to the CPU 310 (high level) every 16.66 [ms].

The sound circuit 323 (built-in sound source) controls output (playback) of sounds (effect sounds) from the various speakers 22 .
As shown in FIG. 52, the sound circuit 323 includes 40 tracks (track 1 to track 40), 8 audio buses (audio bus 1 to audio bus 8), 8 channels (channel 1 to channel 8), and a control register (not shown).
In this embodiment, the various speakers 22 include an upper left speaker, an upper right speaker, a middle left speaker, a middle right speaker, a lower speaker, and a woofer. One speaker is connected (electrically connected) to each channel via the digital amplifier 305 . Specifically, the upper left speaker is connected to channel 1, the upper right speaker is connected to channel 2, the left middle speaker is connected to channel 3, the right middle speaker is connected to channel 4, the lower speaker is connected to channel 5, and the woofer is connected to channel 6. On the other hand, channels 7 and 8 are not connected to speakers.
Here, the upper left speaker, the upper right speaker, the middle left speaker, and the middle right speaker are configured as high-range and middle-range speakers (full-range speakers). On the other hand, the lower speaker and woofer are configured as low-frequency speakers. It should be noted that the woofer has a lower output frequency band (in a frequency band with a lower frequency characteristic) and a larger output (W) than the lower speaker.
The sound circuit 323 has an independent sequencer (not shown) for each track. This makes it possible to independently control reproduction, stop, volume, etc. of audio data for each track.
Each track is provided with a compressed audio decoder 351, a track fader 352, a programmable pan 353, and the like.
The compressed audio decoder 351 restores (decodes/decodes) the compressed audio data. A track fader 352 sets the volume of the track. The programmable pan 353 controls sound localization by outputting track audio data to an arbitrary audio bus.

A switcher 354, a ducker 355, a channel router 356, and the like are provided for the eight audio buses.
The switcher 354 assigns the audio data of the eight audio buses and the audio data of the eight external serial inputs (not shown) to the eight audio buses. In this embodiment, eight external serial inputs are not used. The ducker 355 ducks (reduces) the volume of the other audio buses based on the volume of audio data input from a predetermined audio bus among the eight audio buses. The channel router 356 establishes connections between each audio bus (audio bus 1 to audio bus 8) and each channel (channel 1 to channel 8).

As shown in FIG. 54, in this embodiment, a channel router 356 connects audio bus 1 and channel 1 . Also, an audio signal generated by channel 1 is input to the upper left speaker. As a result, the sound based on the audio data assigned to the audio bus 1 is output from the upper left speaker.
Audio bus 2 and channel 2 are also connected by channel router 356 . Also, an audio signal generated by channel 2 is input to the upper right speaker. As a result, the sound based on the audio data assigned to the audio bus 2 is output from the upper right speaker.
Also, channel router 356 connects audio bus 3 and channel 3 . Also, the audio signal generated by channel 3 is input to the left center speaker. As a result, the sound based on the audio data assigned to the audio bus 3 is output from the middle left speaker.
Also, channel router 356 connects audio bus 4 and channel 4 . Also, the audio signal generated by channel 4 is input to the middle right speaker. As a result, the sound based on the audio data assigned to the audio bus 4 is output from the middle right speaker.

Also, the channel router 356 connects the audio bus 5 and the channel 5 . Also, an audio signal generated by channel 5 is input to the lower speaker. As a result, the sound based on the audio data assigned to the audio bus 5 is output from the lower speaker.
Also, the channel router 356 connects the audio bus 6 and the channel 6 . Also, the audio signal generated by channel 6 is input to the woofer. As a result, sound based on the audio data assigned to the audio bus 6 is output from the woofer.
Also, the channel router 356 connects the audio bus 7 and the channel 6 . As a result, sound based on the audio data assigned to the audio bus 7 is output from the woofer.
On the other hand, audio bus 8 is not linked to any channel by channel router 356 .
As described above, in this embodiment, channels 7 and 8 are not used, and audio data are not input.

The eight channels include a channel volume 357, an equalizer 358, a limiter 359, a post effector 360, a master volume 361, an audio serial output 362, and the like.
Channel volume 357 sets the volume of each channel. The equalizer 358 sets enhancement/reduction of a specific frequency band (corrects frequency) for each channel. In this embodiment, the equalizer 358 is not used. Limiter 359 prevents clipping by compressing sounds above the threshold for each channel. The post-effector 360 sets, for each channel, enhancement/reduction of a specific frequency band, sound volume, delay in sounding timing, and the like. The master volume 361 collectively sets the volume for all channels. The audio serial output 362 converts the audio data of each channel for serial transmission to the digital amplifier 305 .

The CPU 310 sets the command list read from the control ROM 302 in the control register of the sound circuit 323 according to the command information. As a result, the sound circuit 323 operates according to the command list set in the control register.
The “command list” is information specifying the operation of the sound circuit 323 . As described above, a command list corresponding to each sound effect control number is stored.
In this embodiment, as the command list, a command list for designating the start of sound effect, a command list for designating volume adjustment, a command list for designating the end of sound effect, and the like are defined.
The command list designating the start of the sound production includes information designating the compressed audio data to start playing, information designating the track to which the compressed audio data is to be assigned, information designating the number of times the compressed audio data is to be reproduced, information designating the volume of the compressed audio data (audio data), information designating the panpot ratio of the compressed audio data (audio data), and the like.
"Panpot ratio" is information for designating the audio bus (audio bus 1 to audio bus 8) to which audio data is assigned. In other words, the panpot ratio is information that designates the volume of each audio bus when allocating audio data to each audio bus. In this embodiment, the volume balance of eight audio buses (audio bus 1 to audio bus 8) is designated by the panpot ratio. Specifically, the volume ratio of the audio buses 1 to 8 is designated by the panpot ratio.
On the other hand, the command list for designating volume adjustment includes information for designating the track whose volume is to be adjusted, information for designating the content of adjustment, and the like.
On the other hand, the command list specifying the end of the sound production includes information specifying the track whose reproduction is to be stopped.
As described above, in the present embodiment, playback, stop, volume adjustment, etc. of audio data are controlled for each track.

The serial communication controller 317 includes a lamp controller 317a and a motor controller 317b.
The lamp controller 317a controls driving (light emission) of various lamps 20 and 21 .
Specifically, CPU 310 sets an LED register according to command information (message) set in a lamp command buffer area, which will be described later. Then, the lamp controller 317a generates lamp drive data according to the setting of the LED register, and outputs the generated lamp drive data to the lamp drivers 332 and 342 together with the clock signal. At this time, the lamp driving data is output as serial data.
The ramp controller 317a includes a ramp decoder circuit (not shown). The lamp decoder circuit reads the compressed lamp drive data specified by the command information from the control ROM 302 . It also restores (decodes/decodes) the read compressed lamp drive data. Then, it generates lamp driving data based on the restored lamp driving data, and outputs the generated lamp driving data to the lamp drivers 332 and 342 .

The motor controller 317b controls driving of various motors 23 (various movable bodies).
Specifically, CPU 310 sets a motor register according to command information (message) set in a movable body command buffer area, which will be described later. Then, the motor controller 317b generates motor driving data according to the setting of the motor register, and outputs the generated motor driving data to the motor drivers 333 and 343 together with the clock signal. At this time, the motor drive data is output as serial data.
The motor controller 317b includes a motor sequencer circuit (not shown). The motor sequencer circuit reads compression motor drive data specified by the command information from the control ROM 302 . It also restores (decodes/decodes) the read compressed motor drive data. Then, based on the restored motor drive data, the motor drive data is generated, and the generated motor drive data is output to the motor drivers 333 and 343 .
The motor controller 317b receives information indicating the detection status of the various sensors 24 from the driver board 330, and also receives information indicating the detection status of the switches 25 to 29 and information indicating the detection status of the various sensors 24 from the sub-connection board 340.

(Regarding suppression of current consumption by the ducking function)
Next, suppression of current consumption (power consumption) by the ducking function will be described.
FIG. 55 is a diagram for explaining the ducking function. FIG. 56 is a diagram showing the contents of command lists corresponding to sound effects A and B. FIG.
The pachinko machine 1 is provided with an overcurrent protection circuit (not shown) in a path for supplying current (power) from the power supply board 600 to various devices (various lamps 20, 21, various speakers 22, various motors 23, etc.). The overcurrent protection circuit cuts off (or limits) current output to various devices when detecting a current output exceeding a predetermined value.
Here, the woofer has a larger output (W) than the other speakers (upper left speaker, upper right speaker, middle left speaker, middle right speaker, and lower speaker). Therefore, when the volume of the sound output from the woofer increases, the current consumption of the woofer increases, resulting in an increase in the total current consumption of the various speakers 22, which may cause the overcurrent protection circuit to operate and cut off (or limit) the current output to various devices.
On the other hand, in a sound effect composed of sounds output from various speakers 22 (upper left speaker, upper right speaker, left middle speaker, right middle speaker, lower speaker, and woofer), if the volume of the sound output by the woofer is lowered, the impression of the low range is weakened, the image of the sound effect is spoiled, and the effect of the sound effect may be reduced.

Therefore, in the pachinko machine 1, the ducking function of the ducker 355 is used to suppress the increase in the total volume output by the various speakers 22, thereby suppressing the increase in the total current consumption of the various speakers 22. At this time, in this embodiment, when the volume of the sound output from the woofer exceeds a predetermined threshold, the volume of the sound output from the other speakers is reduced. Specifically, when the volume of the sound output from the woofer exceeds the threshold, the volume of the sound output from the lower speaker whose frequency characteristics overlap with those of the woofer (overlapping frequency bands that can be output) is reduced.
As a result, it is possible to suppress an increase in the total current consumption of the various speakers 22 while preventing the image of the sound production from being spoiled (preventing the impression of the bass range from being weakened).
"Total volume output by various speakers 22" is the maximum value of the total volume output by all speakers (upper left speaker, upper right speaker, middle left speaker, middle right speaker, lower speaker, and woofer) during execution of one sound effect.
"Total current consumption by various speakers 22" is the maximum value of total current consumption output by all speakers (upper left speaker, upper right speaker, middle left speaker, middle right speaker, lower speaker, and woofer) during execution of one sound effect.

Here, when the volume of the sound output from the woofer exceeds the threshold, there is a risk that the overcurrent protection circuit will be activated at the timing when the volume of the sound output from the woofer exceeds the threshold in a sound effect in which the total current consumption of the various speakers 22 exceeds a predetermined value (hereinafter referred to as "high-volume sound effect"). Therefore, in the high-volume sound effect, when the volume output from the woofer exceeds the threshold, it is necessary to reduce the volume of the sound output from the other speakers (specifically, the lower speaker).
On the other hand, even if the volume of the sound output from the woofer exceeds the threshold value, the total current consumption by the various speakers 22 does not exceed a predetermined value (hereinafter referred to as "low volume sound effect"), there is no risk of the overcurrent protection circuit being activated at the timing when the volume of the sound output from the woofer exceeds the threshold value. Therefore, in the low-volume sound effect, even if the volume output from the woofer exceeds the threshold, it is not necessary to reduce the volume of the sound output from other speakers (specifically, the lower speaker).
Therefore, in this embodiment, of the audio buses 1 to 8, the audio bus 8 to which no speaker is connected (the audio bus 8 to which the audio signal based on the assigned audio data is not output to the speaker) is used to control the operation/non-operation of the ducking function according to the type of sound effect (high-volume sound effect/low-volume sound effect).

That is, in the present embodiment, the ducker 355 is set to decrease (duck) the volume of the audio bus 5 to which the lower speaker is connected based on the input of the audio bus 8 to which no speaker is connected.
Specifically, the ducker 355 constantly monitors the volume of the audio data assigned to the audio bus 8 while the pachinko machine 1 is powered on, and when the volume of the audio data assigned to the audio bus 8 exceeds a threshold value, the ducking function is activated to reduce (reduce, limit, or suppress) the volume of the audio data assigned to the audio bus 5. Further, when the volume of the audio data assigned to the audio bus 8 becomes equal to or less than a threshold value after the ducking function is activated, the volume of the audio data assigned to the audio bus 5 is set to return to the original volume.
In the command list designating the start of the high-volume sound performance, a panpot ratio is defined so that the audio data assigned to the audio bus 6 among the audio data constituting the high-volume performance is also assigned to the audio bus 8 with the same volume as the audio bus 6.例文帳に追加

As a result, the audio data assigned to the audio bus 6 is also assigned to the audio bus 8 with the same volume as that of the audio bus 6 when a loud sound effect is executed. That is, the same audio data is assigned to the audio bus 6 and the audio bus 8 with the same volume. As a result, the ducker 355 reduces the volume of the audio data assigned to the audio bus 5 when the volume of the audio data assigned to the audio bus 8 exceeds the threshold. In other words, the ducker 355 reduces the volume of the audio data assigned to the audio bus 5 when the volume of the audio data assigned to the audio bus 6 exceeds the threshold. Therefore, when the volume of the sound output from the woofer exceeds the threshold, it is possible to reduce the volume of the sound output from the lower speaker. The same audio data as a part of the audio data assigned to the audio bus 6 (one of the element data constituting the audio data assigned to the audio bus 6) may be assigned to the audio bus 8 at the same volume as the audio bus 6.
On the other hand, in the command list designating the start of the low-volume sound presentation, the panpot ratio is defined so that the audio data assigned to the audio bus 6 among the audio data constituting the low-volume presentation is not assigned to the audio bus 8. - 特許庁That is, no audio data is assigned to the audio bus 8 in the command list specifying the start of the low-volume sound effect.
As a result, the audio data assigned to the audio bus 6 is not assigned to the audio bus 8 when the low-volume sound effect is executed. Therefore, even if the volume of the sound output from the woofer exceeds the threshold, the volume of the sound output from the lower speaker is not reduced.

For example, in the pachinko machine 1, sound effects A and sound effects B are defined as types of sound effects. The sound effect A is a high-volume sound effect. On the other hand, the sound effect B is a low volume sound effect.
That is, in the sound effect A, the volume output from the woofer exceeds the threshold at a predetermined timing. In the sound effect A, when the volume output from the woofer exceeds the threshold value, the total current consumption of the various speakers 22 exceeds a predetermined value, and the overcurrent protection circuit may be activated.
Therefore, in the sound effect A, when the volume output from the woofer exceeds the threshold, the ducking function is activated to reduce the volume output from the lower speaker.
On the other hand, in sound effect B, the volume output from the woofer exceeds the threshold at a predetermined timing. However, in the sound effect B, even if the volume output from the woofer exceeds the threshold, the total current consumption by the various speakers 22 does not exceed the predetermined value, and there is no danger of the overcurrent protection circuit being activated.
Therefore, in the sound effect B, even if the volume output from the woofer exceeds the threshold, the ducking function does not operate and the volume output from the lower speaker is maintained.
A specific description will be given below.

Sound effect A is composed of audio data A (compressed audio data A), audio data B (compressed audio data B), audio data C (compressed audio data C), and audio data D (compressed audio data D).
Audio data A is vocal audio data. Audio data B is audio data of a guitar sound. The audio data C is audio data of the bass tone 1 . The voice data D is the voice data of the bass sound 2 .
As shown in FIG. 56(a), in a command list (hereinafter referred to as "command list A") for specifying the start of sound effect A, playback of audio data A (compressed audio data A), playback of audio data B (compressed audio data B), playback of audio data C (compressed audio data C), and playback of audio data D (compressed audio data D) are specified.
In command list A, panpot ratios are defined such that audio data A is assigned (output) to each audio bus 1, 2, 3, and 4 at a predetermined volume, audio data B is assigned (output) to each audio bus 1, 2, 3, and 4 at a predetermined volume, audio data C is assigned (output) to audio bus 5 at a predetermined volume, and audio data D is assigned (output) to audio buses 6 and 8 at a predetermined volume.

Particularly, in command list A, the panpot ratio is defined so that audio data D is assigned to audio buses 6 and 8 at the same volume.
Thus, in the sound effect A, the audio data A is reproduced by each audio bus 1, 2, 3, 4 (each channel 1, 2, 3, 4), and the sound (vocal) based on the audio data A is output from the upper left speaker, the upper right speaker, the left middle speaker, and the right middle speaker. Also, the audio data B is reproduced by each audio bus 1, 2, 3, 4 (channels 1, 2, 3, 4), and the sound (guitar sound) based on the audio data B is output from the upper left speaker, the upper right speaker, the left middle speaker, and the right middle speaker. Also, the audio data C is reproduced by the audio bus 5 (channel 5), and the sound (bass sound 1) based on the audio data C is output from the lower speaker. Also, the audio data D is reproduced by the audio bus 6 (channel 6), and the sound (bass sound 2) based on the audio data D is output from the woofer.
In particular, the ducker 355 monitors the volume of the compressed data D assigned to the audio bus 8, and reduces the volume of the compressed data C assigned to the audio bus 5 in response to the volume of the compressed data D exceeding the threshold. Also, when the volume of the compressed data D becomes equal to or less than the threshold, the volume of the compressed data C assigned to the audio bus 5 is restored to the original volume specified in the command list A.
As described above, in the sound effect A, the volume of the audio data D assigned to the audio buses 6 and 8 exceeds the threshold value at a predetermined timing, but at this time, the volume of the compressed data C assigned to the audio bus 5 is reduced.
As a result, even if the sound volume of the audio data D assigned to the audio buses 6 and 8 exceeds the threshold value, the total current consumption of various speakers 22 does not exceed a predetermined value, and the overcurrent protection circuit can be prevented from operating.
In particular, when the volume of the sound output by the woofer exceeds the threshold, it is possible to suppress an increase in the total current consumption of the various speakers 22 while maintaining the volume of the sound output by the woofer.

The sound effect B is composed of audio data E (compressed audio data E), audio data F (compressed audio data F), audio data G (compressed audio data G), and audio data H (compressed audio data H).
The audio data E is vocal audio data. The audio data F is audio data of a guitar sound. The audio data G is the audio data of the bass sound 1 . The voice data H is voice data of the base sound 2 .
As shown in FIG. 56(b), in a command list (hereinafter referred to as "command list B") for specifying the start of sound effect B, playback of audio data E (compressed audio data E), playback of audio data F (compressed audio data F), playback of audio data G (compressed audio data G), and playback of audio data H (compressed audio data H) are specified.
In command list B, panpot ratios are defined so that audio data E is assigned (output) to each audio bus 1, 2, 3, and 4 at a predetermined volume, audio data F is assigned (output) to each audio bus 1, 2, 3, and 4 at a predetermined volume, audio data G is assigned (output) to audio bus 5 at a predetermined volume, and audio data H is assigned (output) to each audio bus 6 at a predetermined volume. In command list B, compressed data is not assigned to audio bus 8 .
Thus, in the sound effect B, the audio data E is reproduced by each audio bus 1, 2, 3, 4 (each channel 1, 2, 3, 4), and the sound (vocal) based on the audio data E is output from the upper left speaker, the upper right speaker, the left middle speaker, and the right middle speaker. Also, the audio data F is reproduced by each audio bus 1, 2, 3, 4 (each channel 1, 2, 3, 4), and the sound (guitar sound) based on the audio data F is output from the upper left speaker, the upper right speaker, the left middle speaker, and the right middle speaker. Also, the audio data G is reproduced by the audio bus 5 (channel 5), and the sound (bass sound 1) based on the audio data G is output from the lower speaker. Also, the audio data H is reproduced by the audio bus 6 (channel 6), and the sound (bass sound 2) based on the audio data H is output from the woofer.
In particular, in the ducker 355, the volume of the audio data assigned to the audio bus 8 is monitored, but since the audio data is not assigned to the audio bus 8 in the sound effect B, the ducker function does not operate.
That is, in the sound effect B, the volume of the audio data H assigned to the audio bus 6 exceeds the threshold at a predetermined timing, but even if the volume of the audio data H assigned to the audio bus 6 exceeds the threshold, the total current consumption by the various speakers 22 does not exceed the predetermined value, and the overcurrent protection circuit does not operate.
Therefore, it is not necessary to decrease the volume of the audio data G assigned to the audio bus 5 when the volume of the audio data H assigned to the audio bus 6 exceeds the threshold.
Therefore, in the command list B, the audio data H assigned to the audio bus 6 is not assigned to the audio bus 8, so that the ducker function is not activated.

As described above, in the pachinko machine 1, the same volume of the audio data assigned to the audio bus 6 as that of the audio bus 6 is assigned to the audio bus 8 as well, so that when the volume of the audio data assigned to the audio buses 6 and 8 exceeds the threshold, the ducker function is activated and the volume of the audio data assigned to the audio bus 5 can be reduced. becomes.
On the other hand, as for the low-volume sound presentation, the audio data assigned to the audio bus 6 is not assigned to the audio bus 8, so that even when the volume of the audio data assigned to the audio bus 6 exceeds the threshold, the ducker function does not operate and the volume of the audio data assigned to the audio bus 5 can be maintained.
Therefore, in the pachinko machine 1, depending on whether or not the audio data is assigned to the audio bus 8, it is possible to control the operation/non-operation of the ducker function. Therefore, it becomes possible to control the operation/non-operation of the ducker function in units of audio data.

(Control method of production by production control board 300)
Next, the control method of the production|presentation by the production|presentation control board 300 is demonstrated.
The CPU 310 selects an effect (effect number) to be executed according to the control command received from the main control board 200 . Then, the effect scenario data corresponding to the selected effect number and the effect scenario timer corresponding to the effect scenario data are set in the effect scenario setting area of the DRAM 304 .
"Production scenario data" is information that defines the progress of production. Specifically, a plurality of pieces of process data are registered in chronological order in the production scenario data. That is, the production scenario data registers a plurality of process data and information designating the start time (start timing) of the process based on each process data.
Each process data contains one or more command information. For example, as command information, command information specifying the start of a sub-effect (display effect, sound effect, lamp effect, or movable body effect), command information (hereinafter referred to as "effect end command") specifying the end of the sub-effect (display effect, sound effect, lamp effect, or movable body effect), etc. are defined.

Also, the CPU 310 controls the progress of the effect based on the effect scenario data set in the effect scenario setting area.
Specifically, the CPU 310 updates the performance scenario timer set in the performance scenario setting area at a predetermined cycle, and determines whether process data registered in the performance scenario data set in the performance scenario setting area includes process data whose start time has come based on the value of the performance scenario timer after updating. When it is determined that there is process data whose start time has come, each command information included in the process data is stored (stored) in the corresponding buffer area.
At this time, the command information regarding the display effect (command information specifying the start of the display effect, command information specifying the end of the display effect, etc.) is stored in the display command buffer area. On the other hand, command information relating to sound effects (command information specifying various sound effect control numbers) is stored in the sound command buffer area. On the other hand, command information relating to the lamp effect (command information specifying the start of the lamp effect, command information specifying the end of the lamp effect, etc.) is stored in the lamp command buffer area. On the other hand, command information (command information specifying the start of the movable body presentation, command information specifying the end of the movable body presentation, etc.) regarding the movable body presentation is stored in the movable body command buffer area.

(Control method of display effects)
Next, a method of controlling the display effect (display) by the effect control board 300 will be described.
The control ROM 302 stores an animation table corresponding to each display effect (each display effect number). An animation table corresponding to each display effect is associated with display priority information corresponding to the display effect (images forming the display effect).
"Display priority information" is information that designates display priority.
"Display priority" is information that designates the priority order of display (drawing).
Then, when a plurality of display effects (displays) are temporally overlapped and executed, the display of the display screen 31a (the effect image displayed on the display screen 31a) is configured based on the plurality of display effects (images related to the plurality of display effects). In this case, among a plurality of display effects (plurality of images) constituting the display (the effect image), a display effect (image) having a higher display priority is preferentially displayed with respect to a display effect (image) having a lower display priority. That is, among the plurality of display effects (the plurality of images) forming the effect image, a display effect (image) having a higher display priority is preferentially displayed.
In other words, among a plurality of display effects (plurality of images) constituting the effect image, a display effect (image) having a higher display priority is displayed on the near side (player side) than a display effect (image) having a lower display priority. That is, among the plurality of display effects (the plurality of images) forming the effect image, the display effects (images) having higher display priorities are displayed closer to the viewer.
As a result, when a display effect (image) with a higher display priority and a display effect (image) with a lower display priority among a plurality of display effects (a plurality of images) constituting the effect image are overlapped, the display effect (image) with a higher display priority is preferentially displayed for the overlapping part.

The CPU 310 (display control unit) determines whether command information is stored in the display command buffer area at a predetermined cycle. Then, when it is determined that command information is stored in the display command buffer area, each command information stored in the display command buffer area is analyzed, and processing according to the analysis result is executed.
At this time, when the command information designating the start of the display performance is stored in the display command buffer area, the animation table corresponding to the display performance number designated by the command information is read out of the animation tables stored in the control ROM 302.例文帳に追加Then, the read animation table is set (stored/registered) in the animation table setting area of the DRAM 304 .
As a result, the animation table stored in the control ROM 302 is duplicated in the animation table setting area. A plurality of animation tables can be set in the animation table setting area.

The “animation table” is information (various parameters for controlling the display of images) that defines the progress of display effects (display of effect images) by the various image display devices 31 and 32 . In other words, the animation table is information that defines the movement of images.
Specifically, a predetermined number of pieces of frame information are registered in chronological order in the animation table. Then, for a predetermined number of frame information registered in the animation table, the display effect progresses by sequentially executing the display of the image based on each frame information according to the registered order.
Each piece of frame information is various parameters for controlling (executing/configuring) display of an image for one frame. That is, each frame information includes information (image address information) that specifies image data (compressed image data) used for drawing, information that specifies the display priority of the image data (the display effect) (display priority information), information that specifies the magnification (enlargement/reduction ratio) when the image data is drawn (hereinafter referred to as “display magnification information”), information that specifies the coordinates for drawing the image data (coordinates in the frame buffer area) (hereinafter referred to as “display coordinate information”), and the transparency of the image data when it is drawn (transparency). It includes information (hereinafter referred to as “transmittance information”) specifying transparency/transparency) and the like.

Then, CPU 310 controls display of effect images corresponding to each frame based on one or more animation tables set in the animation table setting area.
Specifically, CPU 310 executes a command construction process, which will be described later, at a predetermined cycle.
In the command building process, first, the sub-scenario timer corresponding to each animation data set in the display scenario setting area is updated. Next, based on all the animation tables set in the animation table setting area, a display list is constructed in the drawing command buffer area designated in the construction area.
Specifically, for all the animation tables set in the animation table setting area, among the frame information registered in each animation table, the frame information selected as the target for constructing the display list is acquired. A display list is constructed based on all the acquired frame information.
As a result, the VDP is controlled according to the display list generated in the drawing command buffer area, and the display effect (display of the effect image by the main image display device 31) is controlled.
That is, when one piece of animation data is set in the display scenario setting area, a display list is constructed that designates drawing of image data designated by the one piece of animation data.
On the other hand, when a plurality of animation data are set in the display scenario setting area, a display list is constructed which designates execution of drawing of image data designated by the plurality of animation data in a predetermined order.
At this time, based on the display priority specified by the display priority information set in the display scenario setting area, the order of executing the drawing of the image data corresponding to the display priority information is set.

(Sound effect control method)
Next, a method of controlling sound effects by the effect control board 300 will be described.
The CPU 310 (sound control unit) determines whether command information is stored in the sound command buffer area at a predetermined cycle. Then, when it is determined that the command information is stored in the sound command buffer area, each command information stored in the sound command buffer area is analyzed, and processing according to the analysis result is executed.
Specifically, the command list corresponding to the sound effect control number specified by the command information is read from the control ROM 302 and the read command list is set in the control register of the sound circuit 323 . As a result, the sound circuit 323 operates according to the command list set in the control register.

(Lamp effect control method)
Next, the control method of the lamp production by the production control board 300 will be described.
CPU 310 periodically determines whether command information is stored in the lamp command buffer area. When it is determined that command information is stored in the lamp command buffer area, each command information stored in the lamp command buffer area is analyzed, and processing is executed according to the analysis result.
At this time, when the command information designating the start of the lamp performance is stored in the lamp command buffer area, the compressed lamp driving data corresponding to the lamp performance number designated by the command information is read out and the read compressed lamp driving data is set in the lamp register. As a result, the lamp controller 317a controls the lamp effect (drive (lighting) of the various lamps 20 and 21) according to the compressed lamp drive data set in the lamp register.

(Control method for movable body production)
Next, a method of controlling the movable body effect by the effect control board 300 will be described.
The CPU 310 determines whether command information is stored in the movable body command buffer area at a predetermined cycle. Then, when it is determined that command information is stored in the movable body command buffer area, each command information stored in the movable body command buffer area is analyzed, and processing according to the analysis result is executed.
At this time, when command information designating the start of the movable body performance is stored in the movable body command buffer area, the compression motor drive data designated by the command information is read, and the read compression motor drive data is set in the motor register. As a result, the motor controller 317b controls the movable body effect (drive of various motors 23 (various movable bodies)) according to the compression motor driving data set in the motor register.

(Configuration of Driver Board 330)
The driver board 330 includes a parallel-serial conversion circuit 331 , a lamp driver 332 and a motor driver 333 .
The lamp driver 332 controls the driving (light emission) of the light emitting element group of each system constituting the board surface lamp 21 according to the lamp driving data input from the lamp controller 317a.
At this time, in the lamp driving data, luminance values corresponding to each system constituting the board surface lamp 21 are specified. An excitation signal (driving current) corresponding to the luminance value specified by the lamp driving data is supplied to each system constituting the board lamp 21 . As a result, the driving (light emission) of the light-emitting element groups constituting the system is controlled for each system.
The motor driver 333 controls the output of excitation signals (drive currents) for various motors 23 (motors 23 constituting various movable units) provided in the game board unit 10 according to motor drive data input from the motor controller 317b.
At this time, the output value of each motor 23 arranged on the game board unit 10 is specified in the motor driving data. An excitation signal (driving current) corresponding to the output value specified by the motor driving data is supplied to each motor 23 . Thus, the driving of each motor 23 is controlled.
Detection signals from various sensors 24 are input to the parallel-serial conversion circuit 331 . The parallel-serial conversion circuit 331 converts the detection signals from the various sensors 24 into serial data and outputs the serial data to the serial communication controller 317 .

(Configuration of Sub Connection Board 340)
The sub-connection board 340 includes a parallel-serial conversion circuit 341 , a lamp driver 342 and a motor driver 343 .
The lamp driver 342 controls driving (light emission) of the light emitting element groups of each system constituting the frame lamp 20 according to the lamp driving data input from the lamp controller 317a.
At this time, in the lamp drive data, luminance values corresponding to each system constituting the frame lamp 20 are specified. An excitation signal (driving current) corresponding to the luminance value specified by the lamp driving data is supplied to each system constituting the frame lamp 20 . As a result, the driving (light emission) of the light emitting element groups forming the system is controlled for each system.
The motor driver 343 controls the output of excitation signals (driving currents) for various motors 23 (motors 23 constituting various movable units) provided in the front frame unit 4 according to motor drive data input from the motor controller 317b.
At this time, the output value of each motor 23 arranged in the front frame unit 4 is specified in the motor drive data. An excitation signal (driving current) corresponding to the output value specified by the motor driving data is supplied to each motor 23 . Thus, the driving of each motor 23 is controlled.
Detection signals from various sensors 24 and detection signals from various switches 25 to 29 are input to the parallel-to-serial conversion circuit 341 . The parallel-serial conversion circuit 341 converts the detection signals from the various sensors 24 and the detection signals from the various switches 25 to 29 into serial data and outputs the serial data to the serial communication controller 317 .

(Configuration of Digital Amplifier 305)
Next, the configuration of the digital amplifier 305 will be described.
The digital amplifier 305 converts and amplifies the audio data (digital signal) input from the sound circuit 323 to an analog signal, and outputs the analog signal to the various speakers 22 (upper left speaker, upper right speaker, middle left speaker, middle right speaker, and woofer). At this time, the digital amplifier 305 performs frequency correction, volume correction, etc. for each channel (channel 1 to channel 8).
In particular, the digital amplifier 305 incorporates a DSP (Digital Signal Processor). By transmitting frequency correction parameters from the CPU 310 to the digital amplifier 305, the digital amplifier 305 can set a 10-band (frequency band) PEQ (Parametric Equalizer), a 3-band (frequency band) DRC (Dynamic Range Controller), a crossover filter, a bass enhancement function, etc. for each channel (channel 1 to channel 8).

Specifically, the digital amplifier 305 includes four CPU cores (core 1 to core 4). The core 1 executes frequency correction, volume correction, etc. for audio data of channels 1 and 2 (upper left speaker/upper right speaker). The core 2 executes frequency correction, volume correction, etc. for audio data of channels 3 and 4 (left center speaker and right center speaker). The core 3 performs frequency correction, volume correction, etc. on the audio data of channel 5 (woofer). Core 4 is unused.
Further, the digital amplifier 305 is provided with a frequency correction parameter setting register in which frequency correction parameters are set (stored). Then, the digital amplifier 305 performs frequency correction on the audio data of each channel (channel 1 to channel 8) according to the frequency correction parameter set in the frequency correction parameter setting register.
In this embodiment, the frequency correction parameter setting register includes a frequency correction parameter setting unit 1 corresponding to core 1 (channels 1 and 2), a frequency correction parameter setting unit 2 corresponding to core 2 (channels 3 and 4), and a frequency correction parameter setting unit 3 corresponding to core 3 (channels 5 and 6).
Then, the core 1 performs frequency correction on the audio data of channels 1 and 2 (upper left speaker/upper right speaker) according to the frequency correction parameter set in the frequency correction parameter setting unit 1 . Further, the core 2 performs frequency correction on the audio data of channels 3 and 4 (left center speaker/right center speaker) according to the frequency correction parameter set in the frequency correction parameter setting unit 2 . Furthermore, the core 3 performs frequency correction on the audio data of channel 5 (woofer) according to the frequency correction parameter set in the frequency correction parameter setting unit 3 .

(Control of digital amplifier 305 by CPU 310)
Next, control of the digital amplifier 305 by the CPU 310 will be described.
FIG. 53 is a diagram showing types of frequency correction parameters.
The control ROM 302 stores frequency correction parameters.
“Frequency correction parameter” is information specifying the content of frequency correction executed by the digital amplifier 305 .
As will be described later, CPU 310 transmits frequency correction parameters to digital amplifier 305 via serial communication controller 317 . As a result, in the digital amplifier 305, the frequency correction parameter received from the CPU 310 is set in the frequency correction parameter setting register, and the audio data of each channel is subjected to frequency correction according to the frequency correction parameter set in the frequency correction parameter setting register.
As shown in FIG. 53, in the present embodiment, as the type of frequency correction parameter, four types with different contents of frequency correction (specifically, "normal/frequency correction parameter", "jackpot/frequency correction parameter", "time saving/frequency correction parameter" and "inspection/frequency correction parameter") are defined. In the control ROM 302, "normal time/frequency correction parameter", "big hit time/frequency correction parameter", "time saving/frequency correction parameter" and "inspection time/frequency correction parameter" are stored.

"Normal/frequency correction parameter" is a frequency correction parameter corresponding to the occurrence of the normal game state. That is, the "normal/frequency correction parameter" is information specifying the content of the frequency correction executed by the digital amplifier 305 during the occurrence of the normal game state.
"Normal game state" is a game state in which the jackpot game state is not generated and the time saving control is stopped.
In particular, in the "normal frequency correction parameter", the content of frequency correction for each channel (each speaker) is designated (regulated) according to the frequency characteristics of each speaker (so that the frequency characteristics of each speaker can be utilized).
The "normal frequency correction parameter" includes a "normal frequency correction parameter 1" corresponding to the core 1, a "normal frequency correction parameter 2" corresponding to the core 2, and a "normal frequency correction parameter 3" corresponding to the core 3.

"Normal time/frequency correction parameter 1" is information specifying the content of frequency correction for audio data of channels 1 and 2 (upper left speaker/upper right speaker) by core 1. FIG. Specifically, the “normal time/frequency correction parameter 1” designates enhancement of the high and middle sound ranges and removal (cut) of the low sound range. As a result, when the "normal time/frequency correction parameter 1" is set in the frequency correction parameter setting unit 1, the high and middle ranges of the audio data of channels 1 and 2 (upper left speaker and upper right speaker) are emphasized and the low range is removed.
“Normal time/frequency correction parameter 2” is information specifying the content of frequency correction for audio data of channels 3 and 4 (left middle speaker/right middle speaker) by core 2 . Specifically, the "normal time/frequency correction parameter 2" designates enhancement of the high and middle sound ranges and removal of the low sound range. As a result, when the "normal frequency correction parameter 2" is set in the frequency correction parameter setting unit 2, the high and middle sound ranges are emphasized and the low sound range is removed for the audio data of channels 3 and 4 (left middle speaker and right middle speaker).
“Normal time/frequency correction parameter 3” is information specifying the content of frequency correction for the audio data of channel 5 (woofer) by the core 3 . Specifically, the “normal time/frequency correction parameter 3” designates enhancement of the low range and removal of the high and middle ranges. As a result, when the "normal frequency correction parameter 3" is set in the frequency correction parameter setting unit 3, the low range is emphasized and the high and middle ranges are removed for the audio data of channel 5 (woofer).

The "jackpot/frequency correction parameter" is a frequency correction parameter corresponding to the occurrence of the jackpot gaming state. That is, the "jackpot/frequency correction parameter" is information specifying the content of the frequency correction executed by the digital amplifier 305 during the occurrence of the jackpot gaming state.
In particular, in the "jackpot frequency correction parameter", the content of frequency correction for each channel (each speaker) is specified (regulated) according to the frequency characteristics of each speaker (so that the frequency characteristics of each speaker can be utilized).
The ``jackpot time/frequency correction parameter'' includes a ``jackpot time/frequency correction parameter 1'' corresponding to the core 1, a ``jackpot time/frequency correction parameter 2'' corresponding to the core 2, and a ``jackpot time/frequency correction parameter 3'' corresponding to the core 3.

The "jackpot/frequency correction parameter 1" is information specifying the content of frequency correction for the sound data of channels 1 and 2 (upper left speaker/upper right speaker) by the core 1. FIG. Specifically, the "jackpot/frequency correction parameter 1" designates enhancement of the high and middle sound ranges and removal of the low sound range. As a result, when the "jackpot/frequency correction parameter 1" is set in the frequency correction parameter setting unit 1, the high and middle sound ranges are emphasized and the low sound range is removed for the audio data of channels 1 and 2 (upper left speaker/upper right speaker).
The "jackpot/frequency correction parameter 2" is information specifying the content of frequency correction for the sound data of channels 3 and 4 (left center speaker/right center speaker) by the core 2. FIG. Specifically, the "jackpot/frequency correction parameter 2" designates enhancement of the high and middle sound ranges and removal of the low sound range. As a result, when the ``frequency correction parameter 2 at the time of big hit'' is set in the frequency correction parameter setting part 2, the high sound range and the middle sound range are emphasized and the low sound range is removed for the sound data of the channels 3 and 4 (left middle speaker/right middle speaker).
The "jackpot/frequency correction parameter 3" is information for designating the content of frequency correction for the sound data of channel 5 (woofer) by the core 3. FIG. Specifically, the "jackpot/frequency correction parameter 3" designates enhancement of the low range and removal of the high and middle ranges. Thus, when the ``frequency correction parameter 3 at the time of jackpot'' is set in the frequency correction parameter setting part 3, the low frequency range is emphasized and the high frequency range and the middle frequency range are removed for the sound data of the channel 5 (woofer).

"Time saving time and frequency correction parameter" is a corresponding frequency correction parameter during execution of time saving control. That is, the "time saving/frequency correction parameter" is information that designates the content of the frequency correction performed by the digital amplifier 305 during execution of the time saving control.
In particular, in the "time saving / frequency correction parameter", the contents of frequency correction of each channel (each speaker) are specified (regulated) according to the frequency characteristics of each speaker (so that the frequency characteristics of each speaker can be utilized).
The “time saving/frequency correction parameter” includes “time saving/frequency correction parameter 1” corresponding to core 1, “time saving/frequency correction parameter 2” corresponding to core 2, and “time saving/frequency correction parameter 3” corresponding to core 3.

The “time saving/frequency correction parameter 1” is information specifying the content of frequency correction for the audio data of channels 1 and 2 (upper left speaker/upper right speaker) by the core 1 . Concretely, the "time saving/frequency correction parameter 1" designates enhancement of the high and middle sound ranges and removal of the low sound range. As a result, when the "time saving/frequency correction parameter 1" is set in the frequency correction parameter setting unit 1, the high and middle sound ranges are emphasized for the audio data of channels 1 and 2 (upper left speaker/upper right speaker), and the low range is removed.
"Time saving/frequency correction parameter 2" is information specifying the content of frequency correction for audio data of channels 3 and 4 (left middle speaker/right middle speaker) by core 2. FIG. Concretely, the "time saving/frequency correction parameter 2" designates enhancement of the high and middle sound ranges and removal of the low sound range. As a result, when the "time saving/frequency correction parameter 2" is set in the frequency correction parameter setting unit 2, the high and middle ranges of the audio data of channels 3 and 4 (left middle speaker and right middle speaker) are emphasized and the low range is removed.
The “time-saving/frequency correction parameter 3” is information specifying the content of frequency correction for the audio data of channel 5 (woofer) by the core 3 . Concretely, the "time saving time/frequency correction parameter 3" designates enhancement of the low range and removal of the high and middle ranges. As a result, when the "time saving/frequency correction parameter 3" is set in the frequency correction parameter setting unit 3, the low range is emphasized and the high and middle ranges are removed for the audio data of channel 5 (woofer).

The "inspection/frequency correction parameter" is a frequency correction parameter that corresponds to the execution of operation confirmation processing, which will be described later. That is, the "inspection/frequency correction parameter" is information specifying the content of the frequency correction executed by the digital amplifier 305 during execution of the operation confirmation process.
In particular, in the "normal time/frequency correction parameter", the content of frequency correction for each channel (each speaker) is designated (regulated) regardless of the frequency characteristics of each speaker. In the present embodiment, the "inspection frequency correction parameter" is information specifying that frequency correction is not performed for all channels (all speakers).
The "inspection frequency correction parameter" includes "inspection frequency correction parameter 1" corresponding to the core 1, "inspection frequency correction parameter 2" corresponding to the core 2, and "inspection frequency correction parameter 3" corresponding to the core 3.

The “inspection/frequency correction parameter 1” is information specifying the content of frequency correction for audio data of channels 1 and 2 (upper left speaker/upper right speaker) by the core 1 . Specifically, the “inspection/frequency correction parameter 1” specifies that no correction is performed (no correction) for all frequency bands. As a result, when the "inspection/frequency correction parameter 1" is set in the frequency correction parameter setting unit 1, frequency correction is not executed for the audio data of channels 1 and 2 (upper left speaker/upper right speaker).
The “inspection/frequency correction parameter 2” is information specifying the content of frequency correction for audio data of channels 3 and 4 (left middle speaker/right middle speaker) by the core 2 . Specifically, the “inspection/frequency correction parameter 2” specifies that no correction is performed (no correction) for all frequency bands. As a result, when the "inspection/frequency correction parameter 2" is set in the frequency correction parameter setting unit 2, frequency correction is not executed for the audio data of channels 3 and 4 (left middle speaker/right middle speaker).
The “inspection/frequency correction parameter 3” is information specifying the content of frequency correction for the audio data of channel 5 (woofer) by the core 3 . Specifically, the “inspection/frequency correction parameter 3” specifies that no correction is to be performed (no correction) for all frequency bands. As a result, when the "inspection frequency correction parameter 3" is set in the frequency correction parameter setting unit 3, frequency correction is not executed for the audio data of channel 5 (woofer).

The DRAM 304 is provided with a frequency correction parameter number setting area 1, a frequency correction parameter number setting area 2, and a frequency correction parameter number setting area 3. FIG.
In the frequency correction parameter number setting area 1, information specifying the type of frequency correction parameter set in the frequency correction parameter setting unit 1 (hereinafter referred to as "frequency correction parameter number") is set (stored).
In the frequency correction parameter number setting area 2, information (frequency correction parameter number) specifying the type of frequency correction parameter set in the frequency correction parameter setting section 2 is set (stored).
In the frequency correction parameter number setting area 3, information (frequency correction parameter number) specifying the type of frequency correction parameter set in the frequency correction parameter setting section 3 is set (stored).
In this embodiment, as the frequency correction parameter number, a value (specifically, "0") that specifies the "normal time/frequency correction parameter", a value (specifically, "1") that specifies the "jackpot time/frequency correction parameter", a value that specifies the "time saving/frequency correction parameter" (specifically, "2"), and a value that specifies the "inspection time/frequency correction parameter" (specifically, "3") are defined.
Any value from "0" to "3" is set in each frequency correction parameter number setting area (frequency correction parameter number setting area 1 to frequency correction parameter number setting area 3).

The control ROM 302 also stores post-effector frequency correction parameters.
The “post-effector frequency correction parameter” is information specifying the content of frequency correction executed by the post-effector 360 .
In this embodiment, as the types of post-effector frequency correction parameters, two types with different content of frequency correction (specifically, "normal/post-effector frequency correction parameter" and "inspection/post-effector frequency correction parameter") are defined. In the control ROM 302, "normal post-effector frequency correction parameter" and "inspection post-effector frequency correction parameter" are stored.
"Normal/post-effector frequency correction parameter" is a post-effector frequency correction parameter that corresponds to a game. That is, the "normal time/post effector frequency correction parameter" is information specifying the content of frequency correction executed by the post effector 360 during a game. In particular, the "normal/post-effector frequency correction parameter" designates execution of predetermined frequency correction for audio data of each channel (channel 1 to channel 8).
The "inspection/post-effector frequency correction parameter" is a post-effector frequency correction parameter that corresponds to the execution of operation confirmation processing, which will be described later. That is, the "inspection/post-effector frequency correction parameter" is information specifying the content of frequency correction to be performed by the post-effector 360 during execution of the operation check process. In particular, the "inspection/post-effector frequency correction parameter" specifies that no frequency correction be performed for audio data of all channels (channels 1 to 8).

The sound circuit 323 is provided with a post-effector frequency correction parameter number register in which a post-effector frequency correction number is set. In the post-effector frequency correction parameter number register, either a value (specifically, "0") specifying the "normal post-effector frequency correction parameter" or a value (specifically, "1") specifying the "inspection-time post-effector frequency correction parameter" is set.
Then, the post-effector 360 refers to the post-effector frequency correction parameter stored in the control ROM 302 according to the value set in the post-effector frequency correction parameter number register, and executes frequency correction.
Specifically, when the post-effector frequency correction parameter number register is set to "0", the post-effector 360 performs frequency correction according to the "normal post-effector frequency correction parameter" stored in the control ROM 302. On the other hand, when "1" is set in the post-effector frequency correction parameter number register, frequency correction is executed according to the "post-effector frequency correction parameter during inspection" stored in the control ROM 302. FIG.

(Setting frequency correction parameters during game play)
When the pachinko machine 1 is powered on, the CPU 310 initializes the value of each frequency correction parameter number setting area (frequency correction parameter number setting area 1 to frequency correction parameter number setting area 3) of the DRAM 304 in the initialization process (step S28-1) included in the sub CPU initialization process described later. As a result, a value (specifically, "0") designating the "normal frequency correction parameter" is set in each frequency correction parameter number setting area.
Also, CPU 310 initializes the value of the post-effector frequency correction parameter number register of sound circuit 323 in the initialization process (step S28-1). As a result, a value (specifically, "0") designating the "normal post-effector frequency correction parameter" is set in the post-effector frequency correction parameter number register.
As a result, the post-effector 360 thereafter performs frequency correction on the audio data of each channel according to the "normal/post-effector frequency correction parameter".

In addition, in the digital amplifier setting process (step S28-4), after transmitting the reset signal to the digital amplifier 305, the CPU 310 transmits “normal frequency correction parameter” (“normal frequency correction parameter 1” to “normal frequency correction parameter 3”) to the digital amplifier 305.
As a result, in the digital amplifier 305, after various registers (frequency correction parameter setting registers (frequency correction parameter setting unit 1, frequency correction parameter setting unit 2, and frequency correction parameter setting unit 3), volume setting (correction) register, terminal setting register, status information setting register, etc.) are initialized (cleared), the "normal/frequency correction parameter" is set in the frequency correction parameter setting register. That is, "normal time/frequency correction parameter 1" is set in the frequency correction parameter setting unit 1, "normal time/frequency correction parameter 2" is set in the frequency correction parameter setting unit 2, and "normal time/frequency correction parameter 3" is set in the frequency correction parameter setting unit 3.
As a result, the digital amplifier 305 thereafter performs frequency correction on the audio data of channels 1 and 2 (upper left speaker and upper right speaker) according to the "normal frequency correction parameter 1", frequency correction of the audio data of channels 3 and 4 (middle left speaker and middle right speaker) according to the "normal frequency correction parameter 2", and frequency correction of the audio data of channel 5 (woofer) according to the "normal frequency correction parameter 3".

In addition, the CPU 310 sets a value (specifically, "1") for designating a "jackpot/frequency correction parameter" in each frequency correction parameter number setting area (frequency correction parameter number setting area 1 to frequency correction parameter setting area 3) of the DRAM 304 at the start of the jackpot gaming state.
In addition, the CPU 310 transmits to the digital amplifier 305 “jackpot/frequency correction parameter” (“jackpot/frequency correction parameter 1” to “jackpot/frequency correction parameter 3”).
As a result, the “jackpot/frequency correction parameter” is set in the frequency correction parameter setting register of the digital amplifier 305 . That is, a “jackpot/frequency correction parameter 1” is set in the frequency correction parameter setting unit 1, a “jackpot/frequency correction parameter 2” is set in the frequency correction parameter setting unit 2, and a “jackpot/frequency correction parameter 3” is set in the frequency correction parameter setting unit 3.
Then, in the digital amplifier 305, frequency correction is performed on the audio data of channels 1 and 2 (upper left speaker/upper right speaker) according to the "jackpot/frequency correction parameter 1", frequency correction is performed on the audio data of channels 3 and 4 (left middle speaker/right middle speaker) according to the "jackpot/frequency correction parameter 2", and frequency correction is performed on the audio data of channel 5 (woofer) according to the "jackpot/frequency correction parameter 3".

In addition, when the CPU 310 does not start the time saving control in response to the end of the jackpot game state, at the end of the jackpot game state, each frequency correction parameter number setting area (frequency correction parameter number setting area 1 to frequency correction parameter setting area 3) of the DRAM 304. A value (specifically, “0”) that specifies the “normal frequency correction parameter” is set.
The CPU 310 also transmits “normal frequency correction parameters” (“normal frequency correction parameters 1” to “normal frequency correction parameters 3”) to the digital amplifier 305 .
As a result, the “normal frequency correction parameter” is set in the frequency correction parameter setting register of the digital amplifier 305 . That is, "normal time/frequency correction parameter 1" is set in the frequency correction parameter setting unit 1, "normal time/frequency correction parameter 2" is set in the frequency correction parameter setting unit 2, and "normal time/frequency correction parameter 3" is set in the frequency correction parameter setting unit 3.
As a result, the digital amplifier 305 thereafter performs frequency correction on the audio data of channels 1 and 2 (upper left speaker and upper right speaker) according to the "normal frequency correction parameter 1", frequency correction of the audio data of channels 3 and 4 (middle left speaker and middle right speaker) according to the "normal frequency correction parameter 2", and frequency correction of the audio data of channel 5 (woofer) according to the "normal frequency correction parameter 3".

On the other hand, when the CPU 310 starts the time saving control in response to the end of the jackpot game state, at the end of the jackpot game state, each frequency correction parameter number setting area (frequency correction parameter number setting area 1 to frequency correction parameter setting area 3) of the DRAM 304. A value (specifically, “2”) that specifies the “time saving/frequency correction parameter” is set.
In addition, the CPU 310 transmits “time saving/frequency correction parameter” (“time saving/frequency correction parameter 1” to “time saving/frequency correction parameter 3”) to the digital amplifier 305 .
As a result, the “time saving/frequency correction parameter” is set in the frequency correction parameter setting register of the digital amplifier 305 . That is, "time saving/frequency correction parameter 1" is set in the frequency correction parameter setting unit 1, "time saving/frequency correction parameter 2" is set in the frequency correction parameter setting unit 2, and "time saving/frequency correction parameter 3" is set in the frequency correction parameter setting unit 3.
As a result, after that, in the digital amplifier 305, frequency correction is performed on the audio data of channels 1 and 2 (upper left speaker/upper right speaker) according to the "time saving/frequency correction parameter 1", frequency correction is performed on the audio data of channels 3 and 4 (left middle speaker/right middle speaker) according to the "time saving/frequency correction parameter 2", and frequency correction is performed on the audio data of channel 5 (woofer) according to the "time saving/frequency correction parameter 3".

In addition, the CPU 310 sets a value (specifically, “0”) that specifies the “normal frequency correction parameter” in each frequency correction parameter number setting area (frequency correction parameter number setting area 1 to frequency correction parameter setting area 3) of the DRAM 304 at the end of the time saving control (when the number of times of time saving is completed).
The CPU 310 also transmits “normal frequency correction parameters” (“normal frequency correction parameters 1” to “normal frequency correction parameters 3”) to the digital amplifier 305 .
As a result, the “normal/frequency correction parameter” is set in the frequency correction parameter setting register of the digital amplifier 305 . That is, "normal time/frequency correction parameter 1" is set in the frequency correction parameter setting unit 1, "normal time/frequency correction parameter 2" is set in the frequency correction parameter setting unit 2, and "normal time/frequency correction parameter 3" is set in the frequency correction parameter setting unit 3.
As a result, the digital amplifier 305 thereafter performs frequency correction on the audio data of channels 1 and 2 (upper left speaker and upper right speaker) according to the "normal frequency correction parameter 1", frequency correction of the audio data of channels 3 and 4 (left middle speaker and right middle speaker) according to the "normal frequency correction parameter 2", and frequency correction of the audio data of channel 5 (woofer) according to the "normal frequency correction parameter 3".

As described above, while the normal game state is occurring, the post effector 360 performs frequency correction of the audio data of each channel (channel 1 to channel 8) based on the "normal time/post effector frequency correction parameter", and the digital amplifier 305 performs frequency correction of the audio data of each channel (channel 1 to channel 8) based on the "normal time/frequency correction parameter".
On the other hand, during the occurrence of the jackpot game state, the post effector 360 performs frequency correction of the audio data of each channel (channel 1 to channel 8) based on the "normal time/post effector frequency correction parameter", and the digital amplifier 305 performs frequency correction of the audio data of each channel (channel 1 to channel 8) based on the "jackpot time/frequency correction parameter".
On the other hand, during execution of the time saving control, the frequency correction of the audio data of each channel (channel 1 to channel 8) is performed by the post effector 360 based on the “normal time/post effector frequency correction parameter”, and the digital amplifier 305 performs frequency correction of the audio data of each channel (channel 1 to channel 8) based on the “time saving time/frequency correction parameter”.
In particular, in the "normal time/frequency correction parameter", "jackpot time/frequency correction parameter" and "time saving/frequency correction parameter", for each channel, the content of frequency correction is defined so that sound data that matches the frequency characteristics of the speaker connected to the channel is generated. As a result, the characteristics of each speaker can be brought out, and the performance effect of sound presentation can be improved.

Here, in the digital amplifier 305, when the frequency correction parameter set in the frequency correction parameter setting register (frequency correction parameter setting unit 1 to frequency correction parameter setting unit 3) is changed, the volume of the corresponding channel is corrected to "0" (mute/no sound), and then the frequency correction parameter is changed.
Specifically, when the frequency correction parameter set in the frequency correction parameter setting unit 1 is changed, the volume is set to "0" for channels 1 and 2, and then the frequency correction parameter is changed. After the frequency correction parameter is changed, channels 1 and 2 are restored to their original volumes.
On the other hand, when the frequency correction parameter set in the frequency correction parameter setting unit 2 is changed, the volume is set to "0" for channels 3 and 4, and then the frequency correction parameter is changed. After the frequency correction parameter is changed, channels 3 and 4 are restored to their original volumes.
On the other hand, when the frequency correction parameter set in the frequency correction parameter setting unit 3 is changed, the volume is set to "0" for channels 5 and 6, and then the frequency correction parameter is changed. After the frequency correction parameter is changed, channels 5 and 6 are restored to their original volumes.

(Frequency correction parameter setting at the time of execution of operation check processing)
The main control board 200 is provided with inspection terminals (not shown) to which an inspection device can be connected. By operating the inspection device connected to the inspection terminal, it is possible to transmit a predetermined inspection command from the main control board 200 to the effect control board 300 .
When CPU 310 receives a predetermined inspection command, CPU 310 executes speaker inspection processing.
In the speaker test process, first, in each frequency correction parameter number setting area (frequency correction parameter number setting area 1 to frequency correction parameter setting area 3) of the DRAM 304, a value (specifically, "3") that designates the "frequency correction parameter during inspection" is set.
In addition, in the post-effector frequency correction parameter number register of the sound circuit 323, a value (specifically, "1") is set to designate the "post-effector frequency correction parameter during inspection".
As a result, the post-effector 360 thereafter performs frequency correction on the audio data of each channel in accordance with the "inspection/post-effector frequency correction parameter".

Furthermore, “inspection frequency correction parameters” (“inspection frequency correction parameters 1” to “inspection frequency correction parameters 3”) are transmitted to the digital amplifier 305 .
As a result, the “inspection/frequency correction parameter” is set in the frequency correction parameter setting register of the digital amplifier 305 . That is, "inspection/frequency correction parameter 1" is set in the frequency correction parameter setting unit 1, "inspection/frequency correction parameter 2" is set in the frequency correction parameter setting unit 2, and "inspection/frequency correction parameter 3" is set in the frequency correction parameter setting unit 3.
Then, in the digital amplifier 305, frequency correction is performed on the audio data of channels 1 and 2 (upper left speaker and upper right speaker) according to the "frequency correction parameter 1 during inspection", frequency correction is performed on the audio data of channels 3 and 4 (middle left speaker and middle right speaker) according to "frequency correction parameter 2 during inspection", and frequency correction is performed on the audio data of channel 5 (woofer) according to "frequency correction parameter 3 during inspection".

In the speaker inspection process, next, an operation confirmation process is executed.
In the operation confirmation process, a predetermined test sound (effect sound, voice, etc.) is output from each of the upper left speaker, upper right speaker, middle left speaker, middle right speaker, and woofer in a predetermined order. Accordingly, the inspector inspects whether or not the speaker is operating normally based on the inspection sound output from each speaker (operation check).
In this embodiment, when the pachinko machine 1 is powered off, the speaker inspection process (operation confirmation process) is terminated.
Here, if the test sound output from each speaker is subjected to the same frequency correction as during the game, the tester may not be able to hear the test sound. For example, when each speaker outputs a test sound in a frequency band from high to midrange, if the test sound output from the woofer is frequency-corrected to remove the high and midrange, there is a risk that the inspector will not be able to hear the test sound output from the woofer.
Therefore, in the pachinko machine 1, the frequency correction of the audio data of each channel (channels 1 to 8) is controlled by the post effector 360 based on the "post effector frequency correction parameter during inspection" while the operation confirmation process of the speaker 22 is being executed, and the digital amplifier 305 controls the frequency correction of the audio data of each channel (channels 1 to 8) based on the "inspection/frequency correction parameter".
In particular, the "inspection/post-effector frequency correction parameter" specifies that frequency correction of audio data of each channel is not executed (audio data is passed through). Further, the contents of the "inspection frequency correction parameter" are defined so as not to execute frequency correction of the audio data of each channel (pass the audio data).
As a result, during execution of the operation confirmation process for the speaker 22, the sound circuit 323 and the digital amplifier 305 do not perform frequency correction for audio data of all channels.
Therefore, it is possible to prevent the examiner from being unable to hear the test sound output from each speaker 22 .

Here, each speaker may be damaged if sound in a frequency band that does not match the frequency characteristics of the speaker is output at a high volume.
Therefore, in the digital amplifier 305, during the period in which the frequency correction of the audio data of each channel is controlled based on the "inspection/frequency correction parameter", the volume (gain) of each channel may be suppressed (reduced) compared to the period in which the frequency correction of the audio data of each channel is controlled based on the "normal/frequency correction parameter", "jackpot/frequency correction parameter" or "time saving/frequency correction parameter".
For example, in the speaker inspection process, the "inspection/volume correction parameter" may be transmitted to the digital amplifier 305 together with the "inspection/frequency correction parameter", and the digital amplifier 305 may control the volume of each channel according to the "inspection/volume correction parameter" during execution of the operation check process. At this time, the "inspection time/volume correction parameter" specifies a smaller sound volume for each channel than during the game ("normal time/frequency correction parameter", "jackpot time/frequency correction parameter" or "time saving/frequency correction parameter" being set).

(Digital amplifier reset processing)
Next, digital amplifier reset processing will be described.
The digital amplifier 305 is provided with a status information setting register in which status information is set. Here, “status information” is information indicating the state of the digital amplifier 305 .
In addition, the digital amplifier 305 can detect the occurrence of various abnormal conditions such as overcurrent, high temperature, and duty ratio (τ) being maintained at an abnormal level. Then, when various abnormal states are not detected, a value (specifically, "0") corresponding to a normal state is set in the status information setting register, and a value (specifically, "1") corresponding to an abnormal state is set in the status information setting register in accordance with the detection of various types of abnormal information.
Further, CPU 310 acquires status information set in the status information setting register of digital amplifier 305 in a status information acquisition process (step S28-8) described later. Then, when it is determined that the acquired status information is a value (specifically, "1") corresponding to an abnormal state, a digital amplifier reset process (step S28-10), which will be described later, is executed.
In the digital amplifier reset process, a reset signal is transmitted to the digital amplifier 305 (the signal input to the reset terminal is turned on). Upon receiving the reset signal, the digital amplifier 305 initializes various registers. Specifically, frequency correction parameter setting registers (frequency correction parameter setting unit 1, frequency correction parameter setting unit 2, and frequency correction parameter setting unit 3), volume setting (correction) registers, terminal setting registers, status information setting registers, etc. are initialized (cleared). As a result, a value (specifically, "0") corresponding to the normal state is set in the status information setting register.

Here, when a reset signal is transmitted to the digital amplifier 305 while the pachinko machine 1 is powered on, the frequency correction parameter setting registers (frequency correction parameter setting unit 1, frequency correction parameter setting unit 2, and frequency correction parameter setting unit 3) are initialized, and the sound quality of the sound output from the speaker 22 changes before and after the reset signal is transmitted, which may cause the player to feel uncomfortable.
Therefore, in the pachinko machine 1, after transmitting the reset signal to the digital amplifier 305, the information set in the frequency correction parameter setting register (frequency correction parameter setting unit 1, frequency correction parameter setting unit 2, and frequency correction parameter setting unit 3) is configured to return to the information before the reset signal is transmitted (before the occurrence of an abnormal state is detected in the digital amplifier 305).
That is, after executing the digital amplifier reset process, the CPU 310 executes the parameter restoration process (step S28-11).
In the parameter restoration process, first, the values of the frequency correction parameter number setting areas (frequency correction parameter number setting area 1 to frequency correction parameter number setting area 3) of the DRAM 304 are confirmed. Then, the frequency correction parameter corresponding to the value of each frequency correction parameter number setting area is read from the control ROM 302 and the read frequency correction parameter is transmitted to the digital amplifier 305 .

Specifically, when the value of frequency correction parameter number setting area 1 is "0", the value of frequency correction parameter number setting area 2 is "0", and the value of frequency correction parameter number setting area 3 is "0", "normal/frequency correction parameter 1", "normal/frequency correction parameter 2", and "normal/frequency correction parameter 3" are transmitted to digital amplifier 305. As a result, in the digital amplifier 305, "normal/frequency correction parameter 1" is restored to the frequency correction parameter setting unit 1, "normal/frequency correction parameter 2" is restored to the frequency correction parameter setting unit 2, and "normal/frequency correction parameter 3" is restored to the frequency correction parameter setting unit 3.
On the other hand, when the value of the frequency correction parameter number setting region 1 is “1”, the value of the frequency correction parameter number setting region 2 is “1”, and the value of the frequency correction parameter number setting region 3 is “1”, “jackpot/frequency correction parameter 1”, “jackpot/frequency correction parameter 2” and “jackpot/frequency correction parameter 3” are transmitted to the digital amplifier 305. As a result, in the digital amplifier 305, the frequency correction parameter setting unit 1 is restored with the "frequency correction parameter 1 at the time of the big hit", the frequency correction parameter setting unit 2 is restored with the "frequency correction parameter 2 at the time of the big hit", and the frequency correction parameter setting unit 3 is restored with the "frequency correction parameter at the time of the big hit 3".
On the other hand, when the value of the frequency correction parameter number setting area 1 is “2”, the value of the frequency correction parameter number setting area 2 is “2”, and the value of the frequency correction parameter number setting area 3 is “2”, “time saving/frequency correction parameter 1”, “time saving/frequency correction parameter 2” and “time saving/frequency correction parameter 3” are transmitted to the digital amplifier 305. As a result, in the digital amplifier 305, the "time saving/frequency correction parameter 1" is returned to the frequency correction parameter setting unit 1, the "time saving/frequency correction parameter 2" is returned to the frequency correction parameter setting unit 2, and the "time saving/frequency correction parameter 3" is returned to the frequency correction parameter setting unit 3.

As described above, in the pachinko machine 1, even when the digital amplifier 305 is initialized (reset) while the performance control board 300 is powered on, the sound quality of the sound output from the speaker 22 does not change before and after the digital amplifier 305 is initialized. Therefore, it is possible to prevent the player from feeling uncomfortable.
Here, when an abnormal state occurs in the digital amplifier 305 while the power supply to the pachinko machine 1 is being turned on, the initialization/restoration processing (step S28-10, step S28-11) is executed only for the digital amplifier 305 without executing the initialization/restoration processing for the performance control board 300 as described above.
On the other hand, when an abnormal state occurs in the performance control board 300 while the power to the pachinko machine 1 is being turned on, the power to the pachinko machine 1 is cut off and then turned on again, whereby the performance control board 300 is initialized and restored (step S28-1), and the digital amplifier 305 is initialized and restored (step S28-4). As a result, various memories for controlling the performance in the performance control board 300 (the value of the frequency correction parameter number setting area, the value of the set value storage area, the value of the flag area indicating the execution status of the time saving control, the value of the flag area indicating the performance mode, etc.) are initialized (the value before the occurrence of the abnormal state is deleted and the initial value is set again).

(Regarding gaming machine status)
In the pachinko machine 1, six states (specifically, playable state, setting change state, setting confirmation state, setting error state, RAM error state, and backup error state) are defined as gaming machine states.
The RAM 230 of the main control board 200 is provided with a gaming machine state flag area. In the gaming machine status flag area, a value corresponding to one of six gaming machine statuses (specifically, a game available status, a setting change status, a setting confirmation status, a setting abnormality status, a RAM abnormality status, and a backup abnormality status) is stored (set) as a gaming machine status flag. Then, in the pachinko machine 1, a gaming machine state corresponding to the value stored in the gaming machine state flag area is generated.

The "playable state" is a gaming machine state in which a game can be played.
Execution of the processes of steps S4-9 to S4-18, which will be described later, is permitted while the game-enabled state is occurring. As a result, the game (regular game and special game) can be progressed.
Also, the base ratio is displayed on the performance display device 206 while the playable state is occurring. In addition, information about the game is displayed on the main display device 60 .

The “setting change state” is a game machine state in which the setting values stored in the setting value area of the RAM 230 can be changed.
The configuration change state occurs when the configuration change condition is satisfied. In this embodiment, when the power is turned on, a detection signal is input from the inner frame open sensor 108, a detection signal is input from the setting key switch 208, and a detection signal is input from the RAM clear switch 207. When the detection signal is input, the setting change condition is established. That is, when the power is turned on, if the inner frame unit 3 is open, the key switch 208 is rotated to the ON state, and the RAM clear switch 207 is pressed, the setting change state is generated.
While the setting change state is occurring, execution of the processing of steps S4-9 to S4-18, which will be described later, is prohibited. As a result, the game (specifically, normal game and special game) is stopped.
Also, while the setting change state is occurring, the performance display device 206 displays the setting values stored in the setting value area. Also, all the lighting elements forming the main display device 60 are extinguished. Furthermore, security information (external information) is output to the external device.
Furthermore, by pressing the RAM clear switch 207 while the setting change state is occurring, the setting value stored in the setting value area can be changed. When the key switch 208 is rotated to the OFF state while the setting change state is being generated, the game ready state is generated instead of the setting change state. As a result, the set value stored in the set value area is determined.

The “setting confirmation state” is a game machine state in which the setting values stored in the setting value area of the RAM 230 can be confirmed.
The set-verify state occurs when the set-verify condition is satisfied. In this embodiment, when the power is turned on, a detection signal is input from the inner frame open sensor 108, a detection signal is input from the setting key switch 208, and a detection signal is input from the RAM clear switch 207. When the detection signal is not input, the setting confirmation condition is established. That is, when the power is turned on, if the inner frame unit 3 is open, the key switch 208 is rotated to the ON state, and the RAM clear switch 207 is not pressed, the setting confirmation state is generated.
Execution of the processing of steps S4-9 to S4-18, which will be described later, is prohibited while the setting confirmation state is occurring. As a result, the game (specifically, normal game and special game) is stopped.
Also, while the setting confirmation state is occurring, the performance display device 206 displays the setting values stored in the setting value area. This makes it possible to confirm the set value stored in the set value area. Also, all the lighting elements forming the main display device 60 are extinguished. Furthermore, security information (external information) is output to the external device.
Note that the set values stored in the set value area cannot be changed while the setting confirmation state is occurring.
When the key switch 208 is rotated to the OFF state while the setting confirmation state is being generated, the game ready state is generated instead of the setting confirmation state.

The "setting error state" is a gaming machine state in which a setting error has occurred.
The abnormal setting state is generated when it is determined that the set value set in the set value area is not within the specified range while the playable state is being generated.
Execution of the processing of steps S4-9 to S4-18, which will be described later, is prohibited while the setting error state is occurring. As a result, the game (specifically, normal game and special game) is stopped.
Further, while the abnormal setting state is occurring, the performance display device 206 displays an error code designating the occurrence of the abnormal setting. Also, all the lighting elements forming the main display device 60 are extinguished. Furthermore, security information (external information) is output to the external device.
In order to recover from the setting error state, it is necessary to execute power shutdown and power on to cause a setting change state.

"RAM abnormal state" is a gaming machine state in which a RAM abnormality occurs.
The RAM abnormal state occurs when it is determined that a read/write abnormality has occurred in the RAM 230 when the power is turned on.
Execution of the processes of steps S4-9 to S4-18, which will be described later, is prohibited while the RAM abnormal state is occurring. As a result, the game (specifically, normal game and special game) is stopped.
Further, while the RAM abnormality state is occurring, the performance display device 206 displays an error code designating the occurrence of the RAM abnormality. Also, all the lighting elements forming the main display device 60 are extinguished. Furthermore, security information (external information) is output to the external device.
In order to recover from the RAM abnormal state, it is necessary to execute power shutdown and power on to cause the setting change state.

The “backup abnormality state” is a gaming machine state in which a backup abnormality has occurred.
The backup abnormality state is generated when it is determined that the RAM 230 has a backup abnormality (specifically, a backup flag abnormality or a checksum abnormality) when the power is turned on.
Execution of the processing of steps S4-9 to S4-18, which will be described later, is prohibited while the backup abnormal state is occurring. As a result, the game (specifically, normal game and special game) is stopped.
Further, while the backup abnormality state is occurring, the performance display device 206 displays an error code designating the occurrence of the backup abnormality. Also, all the lighting elements that constitute the main display device 60 are extinguished. Furthermore, security information (external information) is output to the external device.
In order to recover from the backup abnormal state, it is necessary to execute power shutdown and power on to cause a setting change state.

(About setting value)
Next, setting values (setting information) set in the pachinko machine 1 will be described.
The "set value" is information specifying the probability of winning a special symbol lottery (first special symbol lottery and second special symbol lottery) (probability of winning a jackpot game state). In this embodiment, values from "0" to "5" are defined as the set values.
The RAM 230 of the main control board 200 is provided with a set value area. Any one of "0" to "5" is stored (set) in the setting value area as the setting value. Then, in the pachinko machine 1, the probability of winning the special symbol lottery is determined according to the value set in the set value area.
In this embodiment, the winning probability of the special symbol lottery corresponding to each setting value is, in order from the highest winning probability, the winning probability corresponding to the setting value = "5", the winning probability corresponding to the setting value = "4", the winning probability corresponding to the setting value = "3", the winning probability corresponding to the setting value = "2", the winning probability corresponding to the setting value = "1", and the winning probability corresponding to the setting value = "0" (winning probability "high" → winning probability "low").

Especially, in the pachinko machine 1, it is possible to change (select) the setting value stored in the setting value area while the setting change state is occurring. Here, the change of the setting value is executed by the administrator of the pachinko machine 1 (such as an employee of the game hall where the pachinko machine 1 is installed).
That is, as described above, when the power is turned on, if the inner frame unit 3 is open, the key switch 208 is rotated to the ON state, and the RAM clear switch 207 is pressed, the setting change state is generated.
While the setting change state is occurring, the performance display device 206 displays the setting values stored in the setting value area. Further, each time the RAM clear switch 207 is pressed, the set value stored in the set value area is changed. At this time, when the setting value set in the setting value area is changed, the setting value displayed on the performance display device 206 is also changed accordingly.
When the key switch 208 is rotated to the OFF state while the setting change state is being generated, the game ready state is generated instead of the setting change state. As a result, the set value stored in the set value area is determined.

(About base ratio)
In the pachinko machine 1, the base ratio (base value) is calculated by the CPU 210 while the playable state is occurring. In this embodiment, the base ratio is calculated only during the occurrence of a predetermined game state (specifically, during the occurrence of the special figure low probability state and during the stop of the time saving control).
Then, the calculated base ratio is displayed on the performance display device 206 while the playable state is occurring.
The “base ratio” is information calculated based on the number of game balls launched into the game area 30 and the number of prize balls paid out according to the entry of the game balls into predetermined ball entrances (in this embodiment, the first start hole 51, the second start hole 52 and other winning holes 54 to 57). Specifically, the base ratio is the ratio (percentage) of the number of payouts to the number of out balls.
In this embodiment, the base ratio is calculated for each predetermined section (period). As the predetermined section, a section in which a predetermined number (in this embodiment, 60000 [balls]) of out balls is detected (discharged) is defined. That is, each section starts when the previous section ends, and ends when the number of out-balls detected during the current section reaches a predetermined number (60000 [balls]). Then, the CPU 210 calculates the base ratio at any time (in real time) during each interval.

A predetermined time may be defined as the predetermined interval. That is, the CPU 210 may be configured to calculate the base ratio for each predetermined time.
"Number of out balls" refers to the number of out balls. “Out ball” refers to a game ball ejected from the game area 30 . Specifically, the out ball is a game ball that has passed through the discharge path (a game ball detected by the out switch 109).
In addition, the game ball discharged from the out port 58 may be used as an out ball. Specifically, the out switch 109 may be configured to detect only the game ball discharged from the out port 58, and the game ball detected by the out switch 109 may be the out ball.
The "number of payouts" refers to the total number of prize balls paid out according to the entry of game balls into the first start port 51, the second start port 52 and the other prize winning ports 54-57.

(Regarding various lotteries)
Next, various lotteries executed by the pachinko machine 1 will be described.
In the pachinko machine 1, a normal symbol lottery is executed when a game ball passes through a starting gate 41.例文帳に追加Then, when the normal symbol lottery is won, a normal per game state is generated. In the normal per game state, the normal electric accessory 52a is displaced (opened) from the closed state to the open state, and the entry of the game ball to the second start port 52 becomes possible.
In this embodiment, one type of "per normal pattern" is set as the type of per normal per game state generated when the normal symbol lottery is won.

In the case of winning the ``permanent pattern'' (winning in the normal pattern lottery), the normal pattern is controlled to be stopped and displayed as the ``permanent pattern'' in the general pattern display device.
On the other hand, when the normal pattern lottery is lost, the normal pattern display device is controlled so as to stop and display the normal pattern as a "missing pattern".
In the pachinko machine 1, it is possible to execute time-saving control as auxiliary control that is advantageous to the player.
During the execution of the time saving control, the time for performing the variable display of the special symbol (hereinafter referred to as "variation time") is shortened compared to when the time saving control is stopped. In this embodiment, during execution of the time saving control, the winning probability of the normal symbol lottery is improved, and the time for performing the variable display of the normal symbols is shortened compared to when the time saving control is stopped. In addition, during execution of the time saving control, the number of times of opening the normal electric accessory 52a is increased and the opening time of the normal electric accessory 52a is extended in the normal game per game state as compared with the stop of the time saving control.

In the case of winning the ``per normal figure'', the number of opening times of the normal electric accessory 52a is set to 1 [times] or 3 [times], and the opening time of the normal electric accessory 52a in each time is set to 0.5 [s] or 2.0 [s]. At this time, during execution of the time saving control, the number of opening times of the normal electric accessory 52a is set to 3 [times], and the opening time of the normal electric accessory 52a at each time is set to 2.0 [s]. On the other hand, while the time saving control is stopped, the number of opening times of the normal electric accessory 52a is set to 1 [times], and the opening time of the normal electric accessory 52a at each time is set to 0.5 [s].

In addition, in the pachinko machine 1, a first special pattern lottery is executed when a game ball enters a first start port 51, and a second special symbol lottery is executed when a game ball enters a second start port 52.例文帳に追加Then, when winning the first special symbol lottery or the second special symbol lottery, a big win game state is generated. In the jackpot game state, a round game is executed in which the special electric accessory 53a is displaced from the closed state to the open state, and a game ball can be entered into the big winning opening 53.
In this embodiment, ``big win 1'' and ``big win 2'' are set as the types of the big win game state generated when the first special pattern lottery is won, and ``big win 3'' to ``big win 6'' are set as the types of the big win game state generated when the second special pattern lottery is won.

When "big win 1" is won, the stop symbol (display mode) corresponding to "big win 1 symbol" is stopped and displayed on the special figure 1 display device. Further, in the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the "probability variation symbol" is stop-displayed.
Here, the ``variable probability pattern'' is, for example, a display mode in which the first performance patterns z1 stop-displayed at the lottery result display positions of the three first performance pattern display areas a1 to a3 are aligned with the ``number patterns'' indicating the same odd number such as ``7, 7, 7'', and the second performance pattern z2 stop-displayed in the second performance design display region a4 indicates a predetermined color.
When the "jackpot 2" is won, the stop pattern (display mode) corresponding to the "jackpot 2 pattern" is stopped and displayed on the special figure 1 display device. In addition, in the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the "normal symbol" is stop-displayed.
Here, the ``normal symbols'' are, for example, a display mode in which the first performance symbols z1 stop-displayed at the lottery result display positions of the three first performance symbol display areas a1 to a3 are arranged in a "number pattern" indicating the same even number such as "2, 2, 2", and the second performance symbol z2 stop-displayed in the second performance symbol display area a4 indicates a predetermined color.
When the "big win 3" is won, the stop pattern (display mode) corresponding to the "big win 3 pattern" is stop-displayed on the special figure 2 display device. Further, in the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the "probability variation symbol" is stop-displayed.
When the "big hit 4" is won, the stop pattern (display mode) corresponding to the "big hit 4 pattern" is stopped and displayed on the special figure 2 display device. Further, in the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the "probability variation symbol" is stop-displayed.
When the "big hit 5" is won, the stop pattern (display mode) corresponding to the "big hit 5 pattern" is stop-displayed on the special figure 2 display device. Further, in the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the "hidden symbol" is stop-displayed.
Here, the ``hidden pattern'' is a display mode in which, for example, the first performance symbols z1 stop-displayed at the lottery result display positions of the three first performance symbol display areas a1 to a3 are combined with a predetermined regularity such as "1, 2, 3", and the second performance symbol z2 stop-displayed in the second performance symbol display area a4 indicates a predetermined color.
When the "jackpot 6" is won, the stop pattern (display mode) corresponding to the "jackpot 6 pattern" is stop-displayed on the special figure 2 display device. Further, in the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the "hidden symbol" is stop-displayed.

On the other hand, when the special symbol lottery is lost (in the case of "loss"), the stop symbol (display mode) corresponding to the "loss symbol" is stopped and displayed in the special figure 1 display device or the special figure 2 display device. Further, in the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the "lost symbol" is stop-displayed.
Here, the ``missing pattern'' is, for example, a display mode in which the first performance pattern z1 stop-displayed in the three first performance pattern display regions a1 to a3 shows a predetermined color such as ``1, 6, 9'', etc., in which the number indicated by the ``number pattern'' stop-displayed in at least one region is different from the number indicated by the ``number pattern'' stop-displayed in the other region, and the second performance pattern z2 stop-displayed in the second performance pattern display region a4 indicates a predetermined color.

When "jackpot 1" to "jackpot 6" are won, a predetermined number of round games are executed in the jackpot game state.
In this embodiment, when "jackpot 1", "jackpot 2", "jackpot 5" or "jackpot 6" is won, the number of round games is set to 5 [times]. On the other hand, when the "jackpot 3" is won, the number of round games is set to 15 [times]. On the other hand, when the "jackpot 4" is won, the number of round games is set to 10 [times].
When "jackpot 1" to "jackpot 6" are won, the maximum opening time of the special electric accessory 53a in each round game is set to a predetermined time (29.0 [s] in this embodiment). Then, each round game is terminated when one of two conditions is satisfied: that the set longest open time has passed after the special electric accessory 53a is opened, or that the number of game balls entering the big winning hole 53 in the round game reaches a predetermined upper limit number (10 [balls] in this embodiment).

In addition, in the pachinko machine 1, a ``special symbol low probability state'' and a ``special symbol high probability state'' are defined as game states related to the winning probability of the special symbol lottery (the first special symbol lottery and the second special symbol lottery).
During the occurrence of the "special symbol low probability state", the winning probability of the special symbol lottery is the first probability (hereinafter referred to as "low probability").
During the occurrence of the "special symbol high probability state", the winning probability of the special symbol lottery is set to a second probability (hereinafter referred to as "high probability") higher than the first probability.
The main control board 200 sets the winning probability of each lottery so that the winning probability of the first special symbol lottery and the winning probability of the second special symbol lottery are synchronized. Here, the winning probability of the special symbol lottery means the probability of winning the "win"("big win 1" to "big win 6") that causes the big win game state.
In particular, in the pachinko machine 1, the winning probability of the special symbol lottery is the probability corresponding to the combination of the set value set in the set value area and the game state (special symbol low probability state or special symbol high probability state).

Specifically, when the set value is "0" and the "special symbol low probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/319.69. On the other hand, when the set value is "0" and the "special symbol high probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/32.13.
On the other hand, when the set value is "1" and the "special symbol low probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/312.08. On the other hand, when the set value is "1" and the "special symbol high probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/31.36.
On the other hand, when the set value is "2" and the "special symbol low probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/304.82. On the other hand, when the set value is "2" and the "special symbol high probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/30.62.

On the other hand, when the set value is "3" and the "special symbol low probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/297.89. On the other hand, when the set value is "3" and the "special symbol high probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/29.93.
On the other hand, when the set value is "4" and the "special symbol low probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/291.27. On the other hand, when the set value is "4" and the "special symbol high probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/29.26.
On the other hand, when the set value is "5" and the "special symbol low probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/284.94. On the other hand, when the set value is "5" and the "special symbol high probability state" is occurring, the probability of winning the special symbol lottery (big hit probability) is 1/28.62.

When a ``jackpot 2'' or ``jackpot 6'' is won, a ``special low probability state'' is generated in a period from the end of the jackpot game state to the occurrence of the next jackpot game state.
On the other hand, when "jackpot 1" or "jackpot 3" to "jackpot 5" are won, a "special figure high probability state" is generated according to the termination of the jackpot game state. In this embodiment, the "special figure high probability state" is started in response to the end of the big win game state, and ends in response to the start of the next big win game state (the end of the stop display of the "big win design").
In addition, the ``special figure high probability state'' is started in response to the end of the big win game state, and the number of special symbol lotteries executed during the occurrence of the ``special figure high probability state'' reaches a predetermined number of times (for example, 10000 [times]).

Further, when "jackpot 1" to "jackpot 6" are won, time saving control is executed after the jackpot game state ends.
The time-saving control is started in response to the end of the jackpot game state, and is terminated in response to establishment of one of the winning of the special pattern lottery (the ``big-win pattern'' is stopped and displayed) and the execution of notification display (variable display and stop display) of the special pattern for a predetermined number of time-saving times.
When "jackpot 2" or "jackpot 6" is won, 100 [times] is set as the predetermined number of times of time saving.
on the other hand. When "jackpot 1" or "jackpot 3" to "jackpot 5" are won, 10000 [times] is set as the predetermined number of times of time saving.

(Regarding control commands)
Next, control commands transmitted from the main control board 200 to the effect control board 300 and control commands transmitted and received between the main control board 200 and the payout control board 400 will be described.
The main control board 200 and the performance control board 300 are connected to each other via a harness for serial communication. Here, communication between the main control board 200 and the effect control board 300 is performed only in one direction from the main control board 200 to the effect control board 300, and communication from the effect control board 300 to the main control board 200 is not performed.
Each control command transmitted from the main control board 200 to the performance control board 300 is composed of 1-byte upper data indicating the type of control command and 1-byte lower data indicating the content of the control command.
Then, the main control board 200 transmits a control command composed of upper data and lower data to the effect control board 300 by serial communication. When the effect control board 300 receives a control command from the main control board 200, a serial communication reception interrupt occurs, and the data of the control command is stored in a predetermined area of the RAM by this interrupt processing.

In the pachinko machine 1, as a control command sent from the main control substrate 200 to the production control board 300, the design specified command specification, floating mode specified command, floating pattern specified command, stop designated command, gaming status designated command, open -specified command, open -time designated command, round designated command, round design. The ending designation command, the ending specification command, the first -to -read specification command, the second -to -reader specification command, the third -to -reader specification command, the error specification command, the demonstration specification command, the set value specified command, the gaming status specified command, etc. are set.
The symbol type designation command is a command for designating the type of stop symbol (stop symbol number). Specifically, the symbol type designation command designates one type of "losing symbol" and "big hit 1 symbol" to "big hit 6 symbols". The symbol type designation command is transmitted at the start of the variable display of special symbols. In this embodiment, the symbol type specifying command is set to correspond to each of the first special symbol lottery and the second special symbol lottery.

The variation mode specification command is a command that specifies the type of variation mode (variation mode number). The variation mode specification command specifies the variation time associated with the variation mode number by specifying the variation mode number. The variation mode designation command designates the variation time of the first half period (form of the first half of the variation performance) of the variation display (variation performance) of the special symbol.
In the present embodiment, m (plurality) types are set as the types of variation modes, each of which is associated with a different variation time. Then, the variation mode specifying command specifies one (“variation mode m”) of the m kinds of variation mode types (variation mode numbers).

The variation pattern specification command is a command that specifies the type of variation pattern (variation pattern number). The variation pattern specification command specifies the variation time associated with the variation pattern number by specifying the variation pattern number. The variation pattern specification command specifies the variation time of the second half period (mode of the second half period of the variation presentation) of the variation display (variation presentation) of the special symbol.
In this embodiment, n (plurality) kinds of fluctuation pattern types are set, each of which is associated with a different fluctuation time. Then, the variation pattern specification command specifies one (“variation pattern n”) of the n types of variation pattern types (variation pattern numbers).
The variation mode designation command and the variation pattern designation command are transmitted at the start of the variable display of the special symbols.

The stop designation command is a command for designating the stop display of special symbols (effect symbols z1, z2). The stop designation command is transmitted at the start of stop display of special symbols.
The game state designation command is a command for designating a game state (game state offset value).
Here, the "game state offset value" is information specifying the game state. In this embodiment, as the game state offset value, the value of the time reduction control flag, the value of the special figure high probability state flag, the value of the last big hit pattern flag, and the value of the rotation counter after the big hit are set.
The game state designation command designates one game state offset value. The game state designation command is transmitted when the power is turned on, when changing the special game phase, which will be described later, or the like.

The pending number designation command is a command for designating the pending number. In this embodiment, the pending number designation command designates the pending number (special figure 1 pending number or special figure 2 pending number) increased by "1", the pending number decreased by "1", the pending number and the like.
Here, the "special figure 1 pending number" refers to the number of notice display (fluctuation display and stop display) of the first special symbol in the special figure 1 display device is reserved. In addition, the "special figure 2 pending number" refers to the number of notice display (fluctuation display and stop display) of the second special symbol in the special figure 2 display device is reserved.
The pending number designation command is transmitted when power is turned on, when game information is stored, when variable display of special symbols is started, and the like. In this embodiment, as the reserved number designation command, those corresponding to each of the first special symbol lottery and the second special symbol lottery are set.

The opening designation command is a command that designates the start of the opening period (the start of the jackpot game state). The opening designation command designates the type of the jackpot gaming state (type of "jackpot design"). Concretely, the opening designation command designates one type of "jackpot 1 symbol" to "jackpot 6 symbols". The opening designation command is transmitted at the start of the opening period (at the start of the jackpot game state).
The round start designation command is a command for designating the start of a round game. The round start specifying command is transmitted at the start of the round game.
The round end designation command is a command that designates the end of the round game. The round end designation command is transmitted at the end of the round game.
The ending designation command is a command that designates the start of the ending period. The ending specifying command is sent at the beginning of the ending period.

The first look-ahead designation command is a command for designating the type of stop symbol (one type out of "lost symbol" and "big hit 1 symbol" to "big hit 6 symbols"). In this embodiment, the first prefetch designation command is set to correspond to each of the first special symbol lottery and the second special symbol lottery.
The second look-ahead designation command is a command that designates the contents of the variation mode. Specifically, the second prefetch designation command designates that the type of variation mode is undefined (“undefined value”) or one of m types of variation modes (variation mode numbers) (“variation mode m”). The second prefetch designation command is transmitted when game information is stored.
The third look-ahead designation command is a command that designates the contents of the variation pattern. Specifically, the third prefetch designation command specifies that the type of variation pattern is undefined (“undefined value”), or one of n types of variation patterns (variation pattern number) (“variation pattern n”). The third prefetch designation command is transmitted when game information is stored.

The error designation command is a command that designates the occurrence of various errors. In this embodiment, the error designation command designates occurrence of vibration error, magnetic error, radio wave error, or right-handed hitting error. The error designation command is sent when the occurrence of various errors is detected.
The demonstration designation command is a command that designates the start of the customer waiting state. The demonstration designation command is sent at the start of the customer waiting state.
The setting value designation command is a command for designating the setting value stored in the setting value area of the RAM 230 . The setting value designation command is transmitted when the RAM is cleared, when the power is restored after the power is turned on, when the setting change state ends, or when the setting confirmation state ends.
The game status designation command is a command for designating generation (start) or cancellation (end) of the state of being ready for shooting. The game status designation command is transmitted when the game ready state occurs (at the start) and when the play ready state is canceled (at the end).

The main control board 200 and the payout control board 400 are connected to each other via a harness for serial communication. Here, communication between the main control board 200 and the payout control board 400 is bidirectional. Each control command transmitted and received between the main control board 200 and the payout control board 400 consists of 1-byte data.
Then, the main control board 200 transmits a control command to the payout control board 400 by serial communication. In the payout control board 400, when a control command is received from the main control board 200, a serial communication reception interrupt occurs, and the data of the control command is stored in a predetermined area of the RAM by this interrupt processing. Also, the payout control board 400 transmits a control command to the main control board 200 by serial communication. In the main control board 200, when a control command is received from the payout control board 400, a serial communication reception interrupt occurs, and the data of the control command is stored in a predetermined area of the RAM 230 by this interrupt processing.

In the pachinko machine 1, as a control command transmitted from the main control board 200 to the payout control board 400, a command for designating the number of winning balls and the like are set.
The prize number designation command is a command for designating the number of prize balls to be paid out. In this embodiment, the number-of-prize-balls designation command designates the payout of n (n=1 to 15) prize balls. The command for specifying the number of prize balls is transmitted when the payout control board 400 executes the payout operation of the prize balls.
In addition, in the pachinko machine 1, as control commands transmitted from the payout control board 400 to the main control board 200, control commands specifying occurrence/cancellation of an error during payout, occurrence/cancellation of a full tank error, occurrence/cancellation of a jammed ball error, etc. are set. Each control command is sent upon detection of occurrence/release of various errors.

(Processing executed by main control board 200)
Next, processing executed by the main control board 200 will be described.
First, the functions of the hardware configured on the main control board 200 will be described.
When the pachinko machine 1 is powered on, the random number generation circuit 203 starts the hardware random number update process.
In the hard random number update process, each time one clock is input from the clock generation circuit 202 (every 0.083 [μs] in this embodiment), the values of the first to third loop counters are updated by "1" within a predetermined range (within the range of 0 to 65535 in this embodiment).

In addition, in the hard random number update process, every time 32 clocks are input from the clock generation circuit 202 (in this embodiment, every 2.666 [μs]), the value of the fourth loop counter is updated by "1" within a predetermined range (in this embodiment, within the range of 0 to 10006).
Then, the winning random number of the normal symbol lottery, the jackpot random number of the first special symbol lottery, the jackpot random number of the second special symbol lottery, and the reach group random number are respectively updated by the hard random number updating process. The hardware random number update process is executed as a function of the random number generation circuit 203 (hardware), and is executed independently of the process executed by the CPU 210 based on software, which will be described later.

When the pachinko machine 1 is powered on, the transmission shift registers of the command output ports 1 and 2 start control command transmission processing for transmitting the control command stored in the FIFO buffer to the performance control board 300 or the payout control board 400.例文帳に追加The control command transmission process is executed as a function of the command output ports 1 and 2 (hardware), and is executed independently of the process executed by the CPU 210 based on software, which will be described later.

Next, game control processing executed by the CPU 210 of the main control board 200 based on the program (software) stored in the ROM 220 will be described.

(CPU initialization processing)
First, CPU initialization processing executed by the CPU 210 will be described.
FIG. 7 is a flowchart showing CPU initialization processing.
When the pachinko machine 1 is powered on, the CPU 210 starts the CPU initialization process shown in FIG. The CPU initialization process is a process based on a program for controlling the progress of the game. That is, the CPU initialization processing is processing based on a program stored in the use area m1 (program area) of the ROM 220 .
When the CPU initialization process is started, first, the process moves to step S1-1.
In step S1-1, an initialization process is executed, and the process proceeds to step S1-2. In the initial setting process, a startup program is read from the ROM 220, and settings necessary for executing various processes such as register settings are performed.

In the initial setting process, the RAM clear signal from the RAM clear switch 207, the detection signal from the setting key switch 208, and the detection signal from the inner frame open sensor 108 are read.
Specifically, reading of the value set in the reception storage area corresponding to the RAM clear switch 207 is executed 2 [times], and it is determined whether or not the RAM clear switch 207 is turned on based on the read result of 2 [times]. Then, the determination result is saved as switch information for the RAM clear switch 207 . At this time, if it is determined that the ON state has occurred, a value indicating that the ON state has occurred (“1” in this embodiment) is stored as the switch information, and if it is determined that the ON state has not occurred, a value indicating that the ON state has not occurred (“0” in this embodiment) is stored as the switch information.

Also, the value set in the reception storage area corresponding to the setting key switch 208 is read two times, and it is determined whether or not the setting key switch 208 is turned on based on the two reading results. Then, the determination result is saved as switch information of the setting key switch 208 . At this time, when it is determined that the ON state has occurred, a value indicating that the ON state has occurred (“1” in this embodiment) is stored as the switch information, and when it is determined that the ON state has not occurred, a value indicating that the ON state has not occurred (“0” in this embodiment) is stored as the switch information.

Furthermore, the reading of the value set in the reception storage area corresponding to the inner frame open sensor 108 is executed 2 [times], and it is determined whether or not the inner frame open sensor 108 is turned on based on the read result of the 2 [times]. When it is determined that the ON state has not occurred, the switch information of the setting key switch 208 is rewritten to a value (“0” in this embodiment) indicating that the ON state has not occurred. On the other hand, if it is determined that the ON state has occurred, the switch information of the setting key switch 208 is not rewritten.

In step S1-2, wait processing time setting processing is executed, and the process proceeds to step S1-3. In the wait processing time setting process, a predetermined wait processing time (3.1 [s] in this embodiment) is set in the timer counter. As a result, measurement of the set wait processing time by the timer counter is started.
In step S1-3, it is determined whether or not the wait processing time set in step S1-2 has elapsed. If it is determined that the wait processing time has elapsed (Yes), the process proceeds to step S1-4, and if it is determined that the wait processing time has not elapsed (No), the processing of step S1-3 is repeated.

In step S1-4, RAM access permission processing is executed, and the process proceeds to step S1-5. In the RAM access permission process, necessary processes are executed to permit access to the work area of the RAM 230 .
Specifically, in the RAM access permission process, a value corresponding to access permission is stored as a RAM protection value in the RAM access protection area of the RAM 230 . As a result, access to the RAM 230 by the CPU 210 is permitted.

At step S1-5, a gaming machine state flag acquisition process is executed, and the process proceeds to step S1-6. In the gaming machine status flag acquisition process, the gaming machine status flag is acquired.
Specifically, in the gaming machine status flag acquisition process, the value (gaming machine status flag) stored in the gaming machine status flag area of the RAM 230 is saved (loaded) in the D register.
In step S1-6, it is determined whether or not the backup effective flag is normal, and if it is determined that the backup effective flag is normal (Yes), the process proceeds to step S1-7, and if it is determined that the backup effective flag is not normal (No), the process proceeds to step S1-18.
Here, when the value (backup effective flag) stored in the backup effective flag area of the RAM 230 is a predetermined effective value, it is determined that the backup effective flag is normal, and when the value stored in the backup effective flag area is not a predetermined effective value, it is determined that the backup effective flag is not normal.

In step S1-7, checksum calculation processing is executed, and the process proceeds to step S1-8. In the checksum calculation process, a checksum is calculated based on the backup information.
Specifically, in the checksum calculation process, first, the checksum is calculated based on the information stored in the use area M1 (F000H to F1FFH) of the RAM 230 among the backup information.
Next, the checksum is calculated based on the information stored in the non-use area M2 (F300H to F3FFH) of the RAM 230 among the backup information.
In step S1-8, it is determined whether or not the checksum calculated in step S1-7 is normal, and if it is determined that the checksum is normal (Yes), the process proceeds to step S1-9, and if it is determined that the checksum is not normal (No), the process proceeds to step S1-18.
Here, if both conditions of "the checksum value of the used area M1 calculated in step S1-7 matches the checksum value of the used area M1 stored in the checksum area of the RAM 230" and "the checksum value of the unused area M2 calculated in step S1-7 matches the checksum value of the unused area M2 stored in the checksum area", it is determined that the checksum is normal.
On the other hand, if at least one of the conditions "that the checksum value of the used area M1 calculated in step S1-7 matches the checksum value of the used area M1 stored in the checksum area of the RAM 230" and "that the checksum value of the unused area M2 calculated in step S1-7 matches the checksum value of the unused area M2 stored in the checksum area", it is determined that the checksum is not normal.

In step S1-9, a clear target area setting process at power-on is executed, and the process proceeds to step S1-10. In the power-on clear target area setting process, as a range to clear (initialize) the use area M1 of the RAM 230, areas other than the set value area and the gaming machine state flag area (specifically, the checksum area, the backup effective flag area, the error related area, the normal game related area 1, the normal game related area 2, and the stack area) are set.
In step S1-10, it is determined whether or not the RAM clear switch 207 is turned on. If it is determined that the ON state is not generated (No), the process proceeds to step S1-11, and if it is determined that the ON state is generated (Yes), the process proceeds to step S1-21.
Here, based on the switch information of the RAM clear switch 207 saved in step S1-1, it is determined whether or not the RAM clear switch 207 is turned on. At this time, when a value indicating that an ON state has occurred is stored as switch information, it is determined that an ON state has occurred, and when a value indicating that an ON state has not occurred is stored, it is determined that an ON state has not occurred.

In step S1-11, it is determined whether or not a playable state has occurred (set), and if it is determined that a playable state has occurred (Yes), the process proceeds to step S1-12, and if it is determined that the gameable state has not occurred (No), the process proceeds to step S1-14.
Here, based on the gaming machine state flag stored in the D register, it is determined whether or not the game ready state has occurred. At this time, when the game machine state flag stored in the D register is a value corresponding to the game possible state, it is determined that the game possible state is generated, and when it is not a value corresponding to the game possible state, it is determined that the game possible state is not generated.

In step S1-12, it is determined whether or not the setting confirmation condition is satisfied, and if it is determined that the setting confirmation condition is satisfied (Yes), the process proceeds to step S1-13, and if it is determined that the setting confirmation condition is not satisfied (No), the process proceeds to step S1-14.
The 'setting confirmation condition' is established when a playable state is generated, the RAM clear switch 207 is not turned on, the setting key switch 208 is turned on, and the inner frame open sensor 108 is turned on.
Here, in step S1-1, if the inner frame open sensor 108 is not turned on, the switch information of the setting key switch 208 is rewritten to a value indicating that it is not turned on. As a result, when both the setting key switch 208 and the inner frame open sensor 108 are in the on state, a value indicating that the setting key switch 208 is in the on state is saved as the switch information of the setting key switch 208 . On the other hand, when at least one of the setting key switch 208 and the inner frame open sensor 108 is not turned on, a value indicating that the setting key switch 208 is not turned on is stored as the switch information of the setting key switch 208.
Therefore, in step 1-12, it is determined whether or not the setting confirmation condition is satisfied based on the switch information of the setting key switch 208 saved in step S1-1. At this time, when a value indicating that the ON state is generated is stored as switch information, it is determined that the setting confirmation condition is established, and when a value indicating that the ON state is not generated is stored, it is determined that the setting confirmation condition is not satisfied.

In step S1-13, a setting confirmation state setting process is executed, and the process proceeds to step S1-14. In the setting confirmation state setting process, a value corresponding to the setting value confirmation state is set as the gaming machine state flag in the D register.
In step S1-14, a process for setting an area to be cleared upon power return is executed, and the process proceeds to step S1-15. In the clear target area setting process at the time of power return, as the range to clear (initialize) the use area M1 of the RAM 230, the setting value area, the gaming machine state flag area, the normal game related area 2, and other areas excluding the stack area (specifically, the checksum area, the backup effective flag area, the error related area, and the normal game related area 1) are set.

In step S1-15, an initialization process at the time of power return is executed, and the process proceeds to step S1-16. In the power recovery initialization process, the range set in step S1-14 is cleared (initialized) in the use area M1 of the RAM 230. FIG.
In step S1-16, a subcommand transmission process at power return is executed, and the process proceeds to step S1-17. In the power recovery subcommand transmission process, a subcommand (power recovery designation command) designating recovery from power shutdown is stored in the subcommand output request buffer of the RAM 230 .
In step S1-17, a payout command transmission process at power return is executed, and the process proceeds to step S1-32. In the payout command transmission process at the time of power recovery, a payout command designating recovery from power shutdown is stored in the payout command output request buffer of the RAM 230 .

In step S1-18, a backup abnormal state setting process is executed, and the process proceeds to step S1-19. In the backup abnormal state setting process, a value corresponding to the backup abnormal state is set as the gaming machine state flag in the D register.
In step S1-19, a non-use area read/write check process is executed, and the process proceeds to step S1-20. In the non-use area read/write check process, the non-use area M2 of the RAM 230 is cleared (initialized) and a read/write check is performed.
In step S1-20, a process for setting an area to be cleared in the event of an abnormality is executed, and the process proceeds to step S1-21. In the abnormal time clear target area setting process, all areas (specifically, the set value area, the gaming machine state flag area, the checksum area, the backup effective flag area, the error related area, the normal game related area 1, the normal game related area 2, and the stack area) are set as the range for clearing (initializing) the use area M1 of the RAM 230.
In step S1-21, a used area read/write check process is executed, and the process proceeds to step S1-22. In the used area read/write check process, the range set in step S1-20 in the used area M1 of the RAM 230 is cleared (initialized) and the read/write check is performed.

In step S1-22, it is determined whether or not the result of the read/write check performed in steps S1-19 and S1-21 is normal. If it is determined that the result of the read/write check is not normal (No), the process proceeds to step S1-23, and if it is determined that the result of the read/write check is normal (Yes), the process proceeds to step S1-24.
In step S1-23, RAM abnormality setting processing is executed, and the process proceeds to step S1-28. In the RAM abnormal state setting process, a value corresponding to the RAM abnormal state is set as the gaming machine state flag in the D register.
In step S1-24, it is determined whether or not the setting confirmation state has occurred (set), and if it is determined that the setting confirmation state has occurred (Yes), the process proceeds to step S1-25, and if it is determined that the setting confirmation state has not occurred (No), the process proceeds to step S1-26.
Here, based on the gaming machine state flag stored in the D register, it is determined whether or not the setting confirmation state has occurred. At this time, when the game machine state flag stored in the D register is a value corresponding to the setting confirmation state, it is determined that the setting confirmation state is generated, and when it is not a value corresponding to the setting confirmation state, it is determined that the setting confirmation state is not generated.
At step S1-25, a playable state setting process is executed, and the process proceeds to step S1-26. In the playable state setting process, a value corresponding to the playable state is set as the gaming machine state flag in the D register.

In step S1-26, it is determined whether or not the setting change condition is satisfied, and if it is determined that the setting change condition is satisfied (Yes), the process proceeds to step S1-27, and if it is determined that the setting change condition is not satisfied (No), the process proceeds to step S1-28.
The "setting change condition" is established when the RAM clear switch 207 is turned on, the setting key switch 208 is turned on, and the inner frame open sensor 108 is turned on.
Here, as described above, when both the setting key switch 208 and the inner frame open sensor 108 are in the on state, a value indicating that the setting key switch 208 is in the on state is saved as the switch information. On the other hand, when at least one of the setting key switch 208 and the inner frame open sensor 108 is not turned on, a value indicating that the setting key switch 208 is not turned on is stored as the switch information of the setting key switch 208.
Therefore, in step 1-26, based on the switch information of the RAM clear switch 207 and the switch information of the setting key switch 208 saved in step S1-1, it is determined whether or not the setting change condition is established.
At this time, when the switch information of the RAM clear switch 207 and the switch information of the setting key switch 208 both store a value indicating that the ON state is generated, it is determined that the setting change condition is satisfied. On the other hand, when at least one of the switch information of the RAM clear switch 207 and the switch information of the setting key switch 208 stores a value indicating that the ON state has not occurred, it is determined that the setting change condition is not satisfied.

In step S1-27, a setting change state setting process is executed, and the process proceeds to step S1-28. In the setting change state setting process, a value corresponding to the setting change state is set as the gaming machine state flag in the D register.
At step S1-28, a gaming machine state flag saving process is executed, and the process proceeds to step S1-29. In the gaming machine status flag saving process, the gaming machine status flag set in the D register is saved in the gaming machine status flag area of the RAM 230 .
At step S1-29, a RAM clear subcommand transmission process is executed, and the process proceeds to step S1-30. In the RAM clearing subcommand transmission process, a subcommand (RAM clearing designation command) designating that RAM clearing has been executed is stored in the subcommand output request buffer of the RAM 230 .
At step S1-30, the RAM clear initialization process is executed, and the process proceeds to step S1-31. In the RAM clear initialization process, the range set in step S1-9 or step S1-20 in the use area M1 of the RAM 230 is cleared (initialized).
In step S1-31, a payout command transmission process when RAM is cleared is executed, and the process proceeds to step S1-32. In the payout command transmission process at the time of RAM clearing, a payout command specifying that the RAM clearing has been executed is stored in the payout command output request buffer of the RAM 230 .

In step S1-32, a subcommand setting process is executed, and the process proceeds to step S1-33. In the subcommand setting process, a power-on gaming machine state designation command designating the current gaming machine state is stored in the subcommand output request buffer of the RAM 230 .
Specifically, in the subcommand setting process, a power-on game machine state designation command for designating the game machine state flag (game machine state) stored in the game machine state flag area of the RAM 230 is stored in the subcommand output request buffer of the RAM 230.
In step S1-33, a subcommand group setting process is executed, and the process proceeds to step S1-34. In the subcommand group setting process, the subcommand group is stored in the subcommand output request buffer of RAM 230 .
Here, the subcommand group includes a subcommand that specifies the power return phase, a subcommand that specifies the game state (game state offset value), a subcommand that specifies the firing position, a subcommand that specifies the stop pattern of the first special symbol, a subcommand that specifies the stop symbol of the second special symbol, a subcommand that specifies the number of special figures 1 reserved, a subcommand that specifies the number of special figures 2 reserved, a subcommand that specifies the value of the time saving counter, and a setting value stored in the setting value area of the RAM 230. It includes setting value specification commands and the like.

At step S1-34, an initial display time setting process is executed, and the process proceeds to step S1-35. In the initial display time setting process, the initial display time of the performance display device 206 is set in the initial display timer.
At step S1-35, an interrupt setting process is executed, and the process proceeds to the main loop process (step S2-1). In the interrupt setting process, initial setting of a CTC (counter/timer circuit), which is a peripheral device, is performed.
Specifically, in the interrupt setting process, an interrupt vector register is set, and an interrupt count value (4.0 [ms] in this embodiment) is set in the CTC.

(main loop processing)
Next, main loop processing executed by the CPU 210 will be described.
FIG. 8 is a flowchart showing main loop processing.
After completing the CPU initialization process (step S1-35) shown in FIG. 7, the CPU 210 starts the main loop process shown in FIG. The main loop processing is processing based on a program for controlling the progress of the game. That is, the main loop processing is processing based on the program stored in the use area m1 (program area) of the ROM 220 .
When the main loop process is started, first, the process moves to step S2-1.
In step S2-1, interrupt prohibition processing is executed, and the process proceeds to step S2-2. In the interrupt prohibition process, an interrupt prohibition state is set to prohibit interrupts of other processes. As a result, during the period in which the interrupt prohibition state is set, execution of save processing at power-off, timer interrupt processing, and the like, which will be described later, is prohibited.
In step S2-2, an initial value random number update process is executed, and the process proceeds to step S2-3. In the initial value random number update process, the value of the loop counter for generating the initial value random number is updated.
Here, "initial value random number" is a random number for determining the initial value and end value of soft random numbers (hit pattern random numbers, reach mode random numbers, variation pattern random numbers, etc.) that are random numbers generated on the program.
That is, the value of the loop counter that generates soft random numbers is updated within a preset range from the initial value to the end value. The initial value and end value of the loop counter that generates soft random numbers are changed each time the value of the loop counter reaches the end value. At this time, the initial value and end value of the loop counter are determined based on the initial value random number.

At step S2-3, main command analysis processing is executed, and the process proceeds to step S2-4. In the main command analysis process, the main command received from the payout control board 400 (the control command transmitted from the payout control board 400 to the main control board 200) is analyzed, and the process according to the analysis result is executed.
In step S2-4, subcommand transmission processing is executed, and the process proceeds to step S2-5. In the subcommand transmission process, the subcommand stored in the subcommand output request buffer of the RAM 230 is output to the transmission data register of the output port 205 (command output port 1).
As a result, the subcommand input to the transmission data register is stored (stored) in the FIFO buffer. Then, the subcommands stored in the FIFO buffer are transmitted to the effect control board 300 in a predetermined order by the transmission shift register.
At step S2-5, an interrupt permission process is executed, and the process proceeds to step S2-6. In the interrupt permission processing, the interrupt disabled state is released. As a result, the period from the execution of the interrupt permission process of step S2-5 to the execution of the interrupt prohibition process of step S2-1 becomes an interrupt permission period in which the execution of the saving process at power-off, the timer interrupt process, etc. is permitted.
In step S2-6, another random number update process is executed, and the process proceeds to step S2-1. In the other random number update process, the software random numbers excluding the hit pattern random numbers (specifically, reach mode random numbers, variation pattern random numbers, etc.) are updated.

(Save processing when power is cut off)
Next, the power-off save process executed by the CPU 210 will be described.
FIG. 9 is a flowchart showing the saving process at power-off.
The main control board 200 includes a power cutoff detection circuit (not shown). The power cutoff detection circuit monitors the power supply voltage supplied from the power supply board 600 and outputs a power cutoff notice signal to the input port 204 when the value of the power supply voltage falls below a predetermined reference value.
When the CPU 210 receives the power-off notice signal, the CPU 210 starts the power-off saving process shown in FIG. 9 during the interrupt permission period of the main loop process. The power-off save process is a process based on a program for controlling the progress of the game. That is, the saving process at power-off is a process based on a program stored in the use area m1 (program area) of the ROM 220 .

When the power-off saving process is started, first, the process proceeds to step S3-1.
In step S3-1, register save processing is executed, and the process proceeds to step S3-2. In the register saving process, the values of the registers used during execution of the main loop process are saved in the saving area of the RAM 230 .
In step S3-2, power-off notice signal read processing is executed, and the process proceeds to step S3-3. In the power cut-off notice signal reading process, the power cut-off notice signal is read from the power cut-off detection circuit.
Specifically, in the power-off notice signal reading process, the value (“1” or “0”) set in the reception storage area corresponding to the power-off notice signal of the input port 204 is read.
In step S3-3, based on the value read in step S3-2 (the value set in the reception storage area corresponding to the power cutoff notice signal), it is determined whether or not the power cutoff notice signal is input from the power cutoff detection circuit. If it is determined that the power cutoff notice signal is input (Yes), the process proceeds to step S3-4, and if it is determined that the power cutoff notice signal is not input (No), the process proceeds to step S3-13.

In step S3-4, output port stop processing is executed, and the process proceeds to step S3-5. In the output port stop processing, output of control signals and control commands by the output ports 205 (output port 0 to output port 4) is stopped.
Specifically, in the output port stop processing, the values of all bits included in the port registers of the output ports 205 (output port 0 to output port 4) are initialized. This stops the output of control signals and control commands from the output ports 205 (output port 0 to output port 4).
In step S3-5, a backup effective flag setting process is executed, and the process proceeds to step S3-6. In the backup valid flag setting process, a predetermined valid value is stored (saved) in the backup valid flag area of the RAM 230 .

In step S3-6, checksum storage processing is executed, and the process proceeds to step S3-7. In the checksum storage process, a checksum is calculated and stored.
Specifically, in the checksum storage process, first, the checksum is calculated based on the information stored in the use area M1 (F000H to F1FFH) of the RAM 230 . Then, the calculated checksum value is stored in the checksum area of the RAM 230 .
Next, based on the information stored in the non-use area M2 (F300H to F3FFH) of RAM 230, a checksum is calculated. Then, the calculated checksum value is stored in the checksum area.
In step S3-7, RAM access prohibition processing is executed, and the process proceeds to step S3-8. In the RAM access prohibition processing, processing for prohibiting access to the RAM 230 is executed.
Specifically, in the RAM access prohibition process, a value corresponding to access prohibition is stored as a RAM protection value in the RAM access protection area of the RAM 230 . As a result, access to the RAM 230 by the CPU 210 is prohibited.

At step S3-8, a loop counter setting process is executed, and the process proceeds to step S3-9. In the loop counter setting process, a predetermined number of power-off notice signal reading times is set as the value of the return determination loop counter.
In step S3-9, power-off notice signal reading processing is executed, and the process proceeds to step S3-10. In the power cut-off notice signal reading process, the power cut-off notice signal is read from the power cut-off detection circuit.
Specifically, in the power-off notice signal reading process, the value (“1” or “0”) set in the reception storage area corresponding to the power-off notice signal of the input port 204 is read.
In step S3-10, based on the value read in step S3-9 (the value set in the reception storage area corresponding to the power cutoff notice signal), it is determined whether or not the power cutoff notice signal is input from the power cutoff detection circuit. If it is determined that the power cutoff notice signal is not input (No), the process proceeds to step S3-11, and if it is determined that the power cutoff notice signal is input (Yes), the process proceeds to step S3-8.

In step S3-11, loop counter update processing is executed, and the process proceeds to step S3-12. In the loop counter update process, "1" is subtracted from the value set in the return determination loop counter.
In step S3-12, it is determined whether or not the value of the loop counter for return determination is "0". If it is determined that the value of the loop counter for return determination is "0" (Yes), the process proceeds to CPU initialization processing (step S1-1).
In step S3-13, a register return process is executed, a series of processes is terminated, and the original process is returned to. In the register restoration process, the value of the register saved in step S3-1 is restored. After the register return processing is completed, the program returns to the main loop processing (the program address indicated by the stack pointer).

(timer interrupt processing)
Next, timer interrupt processing executed by the CPU 210 will be described.
FIG. 10 is a flowchart showing timer interrupt processing.
The clock generation circuit 202 generates an interrupt request signal every predetermined interrupt cycle (4.0 [ms] in this embodiment).
In response to the generation of the interrupt request signal, the CPU 210 starts timer interrupt processing shown in FIG. 10 during the interrupt permission period of the main loop processing. The main loop processing is processing based on a program for controlling the progress of the game. That is, the main loop processing is processing based on the program stored in the use area m1 (program area) of the ROM 220 .

When the timer interrupt process is started, first, the process moves to step S4-1.
In step S4-1, register save processing is executed, and the process proceeds to step S4-2. In the register save process, the values of all registers used during execution of the main loop process are saved in the save area of the RAM 230 .
In step S4-2, interrupt permission processing is executed, and the process proceeds to step S4-3. In the interrupt permission processing, interrupts are permitted.
In step S4-3, dynamic port output processing is executed, and the process proceeds to step S4-4. Dynamic port output processing will be described later.

In step S4-4, port input processing is executed, and the process proceeds to step S4-5. In port input processing, the state of each switch sensor (each signal) is acquired.
The RAM 230 is provided with an input information storage area corresponding to each switch sensor (each signal input to the input port 204) connected to the input port 204 (input port 0 to input port 3), and an ON state storage area corresponding to each switch sensor (each signal input to the input port 204) connected to the input port 204 (input port 0 to input port 3).
In the port input process, first, for each switch/sensor connected to the input port 204 (input port 0 to input port 3), information set in the reception storage area corresponding to the switch/sensor is acquired, and the acquired information is saved (stored) in the input information storage area corresponding to the switch/sensor.
As a result, for each switch sensor, when the detection signal from the switch sensor is input (high level), "1" is stored in the input information storage area corresponding to the switch sensor, and when the detection signal from the switch sensor is not input (low level), "0" is stored in the input storage area corresponding to the switch sensor.

Next, it is determined whether or not each switch sensor connected to the input port 204 (input port 0 to input port 3) is turned on. At this time, it is determined whether or not each switch/sensor is turned on based on the value saved in the input information storage area in the previous port input process and the value saved in the input information storage area in the current port input process.
The “on state” refers to a state in which a state (low level) in which no detection signal is input has changed to a state (high level) in which a detection signal is input.
When it is determined that each switch/sensor is in the ON state, "1" is set in the ON state storage area corresponding to the switch/sensor. On the other hand, when it is determined that the ON state has not occurred for each switch/sensor, "0" is set in the ON state storage area corresponding to the switch/sensor.
In the following description, the value stored in the ON state storage area corresponding to each switch/sensor is referred to as the "switch bit data" of the switch/sensor.
In particular, the input port 1 is provided with a reception storage area corresponding to the handle detection signal input from the firing enable condition detection section 422 . In the port input process, the information set in the reception storage area corresponding to the steering wheel detection signal of input port 1 is acquired, and the acquired information is saved (stored) in the input information storage area corresponding to the steering wheel detection signal.

At step S4-5, a gaming machine state flag acquisition process is executed, and the process proceeds to step S4-6. In the gaming machine status flag acquisition process, the gaming machine status flag stored in the gaming machine status flag area of the RAM 230 is acquired.
In step S4-6, it is determined whether or not a playable state has been generated (set), and if it is determined that the gameable state has not been generated (No), the process proceeds to step S4-7, and if it is determined that the gameable state has been generated (Yes), the process proceeds to step S4-9.
Here, based on the gaming machine state flag obtained in step S4-5, it is determined whether or not the game ready state has occurred. At this time, when the obtained game machine state flag is a value corresponding to the game possible state, it is determined that the game possible state is generated, and when it is not a value corresponding to the game possible state, it is determined that the game possible state is not generated.

In step S4-7, it is determined whether or not an abnormal state has occurred (set), and if it is determined that an abnormal state has not occurred (No), the process proceeds to step S4-8, and if it is determined that an abnormal state has occurred (Yes), the process proceeds to step S4-19.
Here, based on the gaming machine state flag obtained in step S4-5, it is determined whether or not an abnormal state has occurred. At this time, if the obtained gaming machine state flag is a value corresponding to any one of the setting abnormal state, the RAM abnormal state, and the backup abnormal state, it is determined that an abnormal state has occurred. If the obtained gaming machine state flag does not correspond to any one of the setting abnormal state, the RAM abnormal state, and the backup abnormal state, it is determined that the abnormal state has not occurred.

In step S4-8, setting-related processing is executed, and the process proceeds to step S4-19. The setting-related processing will be described later.
In step S4-9, timer update processing is executed, and the process proceeds to step S4-10. In the timer update process, various timers are updated.
Specifically, in the timer update process, the value of various timer counters (special game timer, normal game timer, security timer, etc.) is updated.
In step S4-10, an initial value random number update process is executed, and the process proceeds to step S4-11. The initial value random number update process in step S4-10 is the same process as the initial value random number update process in step S2-2.
Specifically, in the initial value random number update process, the value of the loop counter for generating the initial value random number is updated.
In step S4-11, a hit symbol random number update process is executed, and the process proceeds to step S4-12. In the winning symbol random number update process, the value of the loop counter for generating the winning symbol random number among the soft random numbers is updated.
In step S4-12, switch management processing is executed, and the process proceeds to step S4-13. In the switch management processing, processing (acquisition of various random numbers, etc.) is executed according to the state of each switch 101, 102, 104 (whether or not an ON state is detected). The switch management processing will be described later.

At step S4-13, a special game management process is executed, and the process proceeds to step S4-14. In the special game management process, the operation of the special figure display device and the operation of the special electric accessory 53a are managed. Special game management processing will be described later.
In step S4-14, normal game management processing is executed, and the process proceeds to step S4-15. The normal game management process manages the operation of the normal diagram display device and the operation of the normal electric accessory 52a. The normal game management process will be described later.

At step S4-15, a state management process is executed, and the process proceeds to step S4-16. The state management process monitors the occurrence and release of various errors (abnormal states). Then, various settings (setting of subcommands, etc.) are executed at the time of detection of occurrence/cancellation of various errors.
Also, in the state management process, based on the values saved in the input information storage area corresponding to the steering wheel detection signal (the value saved in the previous timer interrupt process and the value saved in the current timer interrupt process), it is determined whether or not the state in which the steering wheel detection signal has not been input has changed to the state in which the steering wheel detection signal has been input. When it is determined that the steering wheel detection signal is changed from the non-input state to the input state, a game situation designating command for designating the generation of a shooting ready state is stored in a sub-command output request buffer of a RAM 230. - 特許庁
Further, in the state management process, based on the values stored in the input information storage area corresponding to the steering wheel detection signal (the value stored in the previous timer interrupt process and the value stored in the current timer interrupt process), it is determined whether or not the state in which the steering wheel detection signal has been input has changed to the state in which the steering wheel detection signal has not been input. When it is determined that the handle detection signal is changed from the input state to the non-input state, a game situation designation command for designating cancellation of the firing ready state is stored in a sub-command output request buffer of a RAM 230. - 特許庁
At step S4-16, a winning opening switch process is executed, and the process proceeds to step S4-17. In the prize-winning switch process, processes (such as updating various counters) are executed according to the states of the switches 101 to 103, 105, and 106 (whether or not the ON state is detected).

In step S4-17, a payout control management process is executed, and the process proceeds to step S4-18. In the payout control management process, a payout command is generated based on the value of the prize ball control counter set in step S4-16, and the generated payout command is transmitted.
In this embodiment, as prize ball control counters, a prize ball control counter 1 that stores the number of ball game balls that have entered the big prize opening 53, a prize ball control counter 2 that stores the number of ball game balls that have entered the right and other prize openings 54, a prize ball control counter 3 that stores the number of ball game balls that have entered the upper left, middle left, and lower left other prize openings 55 to 57, a prize ball control counter 4 that stores the number of ball game balls that have entered the first start opening 51, and a second start opening. A prize ball control counter 5 in which the number of ball game balls that have entered is stored in 52 is set.
Then, in the payout control management process, first, it is determined whether or not the value of the prize ball control counter 1 is "1" or more. When it is determined that the value of the prize ball control counter 1 is '1' or more, a payout command designating the payout of a predetermined number (15 [balls] in this embodiment) of prize balls is generated, and the generated payout command is stored in a payout command output request buffer of a RAM 230. - 特許庁As a result, a payout command designating the payout of a predetermined number of prize balls is transmitted to the payout control board 400 . Thereafter, when the game ball payout device 440 completes the payout of the prize balls, the payout control board 400 transmits a main command designating the completion of the payout to the main control board 200 . Then, "1" is subtracted from the value of the prize ball control counter 1 in accordance with the reception of the main command designating the completion of the payout.

Next, it is determined whether or not the value of the prize ball control counter 2 is "1" or more. Then, when it is determined that the value of the prize ball control counter 2 is '1' or more, a payout command designating the payout of a predetermined number (10 [balls] in this embodiment) of prize balls is generated, and the generated payout command is stored in a payout command output request buffer of a RAM 230. - 特許庁As a result, a payout command designating the payout of a predetermined number of prize balls is transmitted to the payout control board 400 . After that, "1" is subtracted from the value of the prize ball control counter 2 in response to receiving the main command designating the completion of the payout.
Next, it is determined whether or not the value of the prize ball control counter 3 is "1" or more. When it is determined that the value of the prize ball control counter 3 is '1' or more, a payout command designating the payout of a predetermined number (10 [balls] in this embodiment) of prize balls is generated, and the generated payout command is stored in a payout command output request buffer of a RAM 230. - 特許庁As a result, a payout command designating the payout of a predetermined number of prize balls is transmitted to the payout control board 400 . After that, "1" is subtracted from the value of the prize ball control counter 3 in response to the reception of the main command designating the completion of the payout.

Next, it is determined whether or not the value of the prize ball control counter 4 is "1" or more. When it is determined that the value of the prize ball control counter 4 is '1' or more, a payout command designating the payout of a predetermined number (three [balls] in this embodiment) of prize balls is generated, and the generated payout command is stored in a payout command output request buffer of a RAM 230. - 特許庁As a result, a payout command designating the payout of a predetermined number of prize balls is transmitted to the payout control board 400 . After that, "1" is subtracted from the value of the prize ball control counter 4 in response to the reception of the main command designating the completion of the payout.
Next, it is determined whether or not the value of the prize ball control counter 5 is "1" or more. When it is determined that the value of the prize ball control counter 5 is '1' or more, a payout command designating the payout of a predetermined number (in this embodiment, 1 [ball]) of prize balls is generated, and the generated payout command is stored in a payout command output request buffer of a RAM 230. - 特許庁As a result, a payout command designating the payout of a predetermined number of prize balls is transmitted to the payout control board 400 . After that, "1" is subtracted from the value of the prize ball control counter 5 in response to the reception of the main command designating the completion of the payout.

In step S4-18, a firing position designation management process is executed, and the process proceeds to step S4-19. In the firing position designation management process, processing related to designation of the firing position is executed.
Specifically, in the shooting position specification management process, when the state of specifying the launch of the game ball to the left path is changed to the status of specifying the launch of the game ball to the right path (at the start of the jackpot game state, etc.), "1" is set in the shooting position specification flag area of the RAM 230, and a subcommand specifying the launch of the game ball to the right path is stored in the subcommand output request buffer of the RAM 230. As a result, a subcommand designating the launch of the game ball to the right path is transmitted to the effect control board 300 .
On the other hand, when the state of designating the launch of the game ball to the right path is changed to the state of designating the launch of the game ball to the left path (at the end of time-saving control, etc.), "0" is set in the launch position specification flag area of the RAM 230. - 特許庁

At step S4-19, an external information management process is executed, and the process proceeds to step S4-20. In the external information management process, external information (external signal) to be output to the hall computer (or data display device) is set.
In this embodiment, as external information output from the pachinko machine 1 to an external device (an electronic device such as a hall computer, a data display device, etc.), pattern confirmation number information, start opening information, jackpot information, security information, out exit payout number information, error occurrence information, etc. are defined.
The "symbol determination frequency information" is external information regarding the number of executions of the special symbol lottery (variation display and stop display of special symbols). The CPU 210 outputs an external signal corresponding to the symbol determination frequency information to the hall computer (or the data display device) every time the number of executions of the stop display of the special symbols reaches a predetermined number.

The “starting opening information” is external information regarding the entry of game balls into the starting openings 51 and 52 . The CPU 210 outputs an external signal corresponding to the starting port information to the hall computer (or data display device) each time the ON state of the detection signal input from the starting port switches 101 and 102 is detected.
The "jackpot information" is external information about the occurrence of the jackpot gaming state. The main control board 200 outputs an external signal corresponding to the jackpot information to the hall computer (or data display device) each time a jackpot game state is generated.
The "outlet payout information" is external information regarding the number of game balls ejected from the ejection path (or the number of game balls ejected from the outlet 58). The CPU 210 outputs an external signal corresponding to the out-out slot payout number information to the hall computer every time the value of the out-ball number counter for external information reaches a predetermined value.
The "security information" is external information indicating that a setting change state is occurring, a setting confirmation state is occurring, or various errors (abnormalities) are occurring. CPU 210 outputs an external signal corresponding to the security information to the hole computer when the value of the security timer is "1" or more.

In the external information management process, it is determined whether or not the value of the external information determination counter has reached a predetermined value (1 [times] in this embodiment). When it is determined that the value of the external information fixed number counter has reached a predetermined value, the pattern fixed number information (external signal) is stored in the port output request buffer of the RAM 230 . After that, a predetermined value (1 [times] in this embodiment) is subtracted from the value of the external information fixed number counter. As a result, pattern determination frequency information (external signal) is output to the hall computer.
Further, in the external information management process, it is determined whether or not the value of the external information starting entrance ball entry number counter has reached a predetermined value (1 [time] in the present embodiment). Then, when it is determined that the value of the external information starting hole entry number counter has reached a predetermined value, the starting hole information (external signal) is stored in the port output request buffer of the RAM 230 . After that, a predetermined value (in this embodiment, 1 [time]) is subtracted from the value of the external information starting entrance number of times counter. As a result, starting point information (external signal) is output to the hall computer.

Also, in the external information management process, it is determined whether or not the value of the external information jackpot frequency counter has reached a predetermined value (1 [times] in this embodiment). When it is determined that the value of the external information jackpot frequency counter has reached a predetermined value, the jackpot information (external signal) is stored in the port output request buffer of the RAM 230 . After that, a predetermined value (1 [times] in this embodiment) is subtracted from the value of the external information jackpot number counter. As a result, jackpot information (external signal) is output to the hall computer.
In the external information management process, it is determined whether or not the value of the external information out-ball number counter has reached a predetermined value (10 [balls] in this embodiment). When it is determined that the value of the external information out ball number counter has reached a predetermined value, the out outlet payout information (external signal) is stored in the port output request buffer of the RAM 230 . After that, a predetermined value (10 [balls] in this embodiment) is subtracted from the value of the external information out-ball number counter. As a result, out-port payout information (external signal) is output to the hall computer.

Also, in the external information management process, it is determined whether or not the value (gaming machine status flag) stored in the gaming machine status flag area of the RAM 230 is a value corresponding to the game ready status.
When it is determined that the value stored in the game machine state flag area is not a value corresponding to a playable state (determined to be a value corresponding to a setting change state, a setting confirmation state, a setting abnormality state, a RAM abnormality state, or a backup abnormality state), security information is stored in a port output request buffer of a RAM 230. - 特許庁As a result, security information (external signal) is output to the hole computer.
Furthermore, in the external information management process, it is determined whether or not the value of the security timer is "1" or more. Then, when it is determined that the value of the security timer is equal to or greater than "1", the security information is stored in the port output request buffer of the RAM 230. FIG. As a result, security information (external signal) is output to the hole computer.

At step S4-20, an LED display setting process is executed, and the process proceeds to step S4-21. In the LED display setting process, display data to be output to the main display device 60 or the performance display device 206 is set.
The RAM 230 is provided with a common 0 output request buffer (8 bits), a common 1 output request buffer (8 bits), a common 2 output request buffer (8 bits), and a common 3 output request buffer (8 bits).
In the LED display setting process, first, the common 2 output request buffer is cleared (initialized), and the common 3 output request buffer is cleared (initialized). Specifically, each bit value of the common 2 output request buffer is set to "0", and each bit value of the common 3 output request buffer is set to "0".

Next, the gaming machine status flag stored in the gaming machine status flag area of the RAM 230 is obtained.
Then, when the obtained gaming machine state flag is a value corresponding to the game ready state, the normal display data setting process described later is executed. On the other hand, if the acquired gaming machine state flag is a value corresponding to the setting change state, a display data setting process at the time of setting change, which will be described later, is executed. On the other hand, if the acquired gaming machine state flag is a value corresponding to the setting confirmation state, a display data setting process at the time of setting confirmation, which will be described later, is executed. On the other hand, if the acquired gaming machine state flag is a value corresponding to an abnormal state (setting abnormal state, RAM abnormal state, or backup abnormal state), an abnormality display data setting process, which will be described later, is executed.

In the normal display data setting process, first, the value of the special figure 1 display pattern counter is acquired, and the display data (8 bits) corresponding to the value of the acquired special figure 1 display pattern counter is set in the common 0 output request buffer.
As a result, the first special symbol is displayed by the LED1 to LED8 among the light emitting elements forming the main display device 60. FIG.
Next, the value of the special figure 2 display pattern counter is acquired, and the display data (8 bits) corresponding to the value of the acquired special figure 2 display pattern counter is set in the common 1 output request buffer.
As a result, the second special symbol is displayed by the LEDs 9 to 16 among the light emitting elements forming the main display device 60 .
Next, the value of the general-purpose map display symbol counter is acquired, and the display data corresponding to the acquired value of the general-purpose map display symbol counter is set as the output data a.

Next, it is determined whether or not the value set in the special game phase flag area of the RAM 230 is a value designating any special game phase out of ``state before opening the big prize winning opening'', ``control state for opening the big winning prize'', ``effective state of closing the big winning prize'' and ``wait state for finishing the opening of the big winning prize''.
Then, when it is determined that the value set in the special game phase flag area is a value that designates one of the special game phases of the "pre-opening state of the big winning opening", the "controlled state of opening the big winning opening", the "effective state of closing the big winning opening" and the "waiting state for ending the opening of the big winning opening", the value set in the special symbol determination flag area of the RAM 230 (the value corresponding to the type of the big winning symbol) is acquired, and the display data corresponding to the acquired value is output as the output data b. set.
On the other hand, when it is determined that the value set in the special game phase flag area is not a value designating any one of the special game phases of the ``pre-opening state of the big winning gate'', the ``controlled state of opening the big winning gate'', the effective state of closing the big winning gate, and the wait state for ending the opening of the big winning gate, the output data b is not set.

Next, the value set in the firing position designation flag area of the RAM 230 is acquired, and the display data corresponding to the acquired value is set as the output data c.
Next, the display data (8 bits) obtained by ORing the output data a to output data c is set in the common 2 output request buffer.
As a result, normal patterns are displayed by LEDs 17 and 18 among the light-emitting elements constituting the main display device 60, the number of round games executed during the big win game state (type of the big win game state) is displayed by the LEDs 19 to 23, and the path (left side path or right side path) for hitting the game ball is displayed by the LED 24.例文帳に追加
Next, the value of the special figure 1 pending number counter is acquired, and the display data corresponding to the acquired value is set as the output data d.
Next, the value of the special figure 2 pending number counter is acquired, and the display data corresponding to the acquired value is set as the output data e.
Next, the value of the normal figure reservation number counter is acquired, and the display data corresponding to the acquired value is set as the output data f.
Next, it is determined whether or not the power supply is restored.
Then, when it is determined that the power is restored, the value set in the special figure high probability state flag area is acquired, and the display data corresponding to the acquired value is set as the output data g.
On the other hand, if it is determined that the power is not restored, the output data g is not set.
Next, the value set in the time saving control flag area of the RAM 230 is acquired, and the display data corresponding to the acquired value is set as the output data h.
Next, display data (8 bits) obtained by ORing output data d to output data h is set in the common 3 output request buffer.
As a result, among the light-emitting elements constituting the main display device 60, the LEDs 25 and 26 display the special figure 1 reserved number, the LEDs 27 and 28 display the special figure 2 reserved number, the LEDs 29 and 30 display the normal figure reserved number, the LED 31 displays the game state at the time of power return (during the occurrence of the special figure high probability state or the occurrence of the special figure low probability state), and the LED 32 displays the current game state (during execution or suspension of time saving control). is displayed.

In the setting change display data setting process, information indicating that a setting change state is occurring is set in the common 0 output request buffer to the common 2 output request buffer, and information indicating the set value stored in the set value area of the RAM 230 is set in the common 3 output request buffer.
Specifically, the display data of "r" (8 bits) is set in the common 0 output request buffer, the display data of "n." (8 bits) is set in the common 1 output request buffer, the display data of "-" (8 bits) is set in the common 2 output request buffer, and the display data corresponding to the set value stored in the set value area of the RAM 230 is set in the common 3 output request buffer.
As a result, among the light-emitting elements constituting the performance display device 206, the LEDs 33 to 40 display the character "r", the LEDs 41 to 48 display the character "n."

In the setting confirmation display data setting process, information indicating that the setting confirmation state is occurring is set in the common 0 output request buffer to the common 2 output request buffer, and information indicating the set value stored in the set value area of the RAM 230 is set in the common 3 output request buffer.
Specifically, the display data of "r" (8 bits) is set in the common 0 output request buffer, the display data of "n." (8 bits) is set in the common 1 output request buffer, and the display data corresponding to the set value stored in the set value area of the RAM 230 is set in the common 3 output request buffer. No display data is set for the common 2 output request buffer (clear value remains).
As a result, of the light-emitting elements constituting the performance display device 206, the LEDs 33 to 40 display the character "r", the LEDs 41 to 48 display the character "n." Note that the LEDs 49 to 56 are turned off.

In the abnormal display data setting process, information indicating that an abnormal state (setting abnormal state, RAM abnormal state, or backup abnormal state) is occurring is set in the common 0 output request buffer to the common 2 output request buffer, and an error code corresponding to the generated abnormality is set in the common 3 output request buffer.
More specifically, the display data (8 bits) of "E" is set in the common 0 output request buffer, the display data (8 bits) of "r." No display data is set for the common 2 output request buffer (clear value remains).
As a result, among the light-emitting elements constituting the performance display device 206, the LEDs 33 to 40 display the character "E", the LEDs 41 to 48 display the character "r.", and the LEDs 57 to 64 display the numbers indicating the error codes. Note that the LEDs 49 to 56 are turned off.

At step S4-21, a solenoid data setting process is executed, and the process proceeds to step S4-22. In the solenoid data setting process, control data (driving data) to be output to the solenoids 64 and 65 are stored (set) in the port output request buffer of the RAM 230 .
In step S4-22, port output processing is executed, and the process proceeds to step S4-23. In port output processing, various signals are output to the hall computer, solenoids 64 and 65, and the like.
Specifically, in the port output process, various information (external signal, control signal, etc.) set in the port output request buffer is output to the output ports 205 (output port 2, output port 3). As a result, the external signal set in the port output request buffer is output to the hall computer. Further, each solenoid 64, 65 is driven and controlled based on the drive signal set in the port output request buffer.
In step S4-23, interrupt prohibition processing is executed, and the process proceeds to step S4-24. In the interrupt prohibition process, an interrupt prohibition state is set to prohibit interrupts of other processes. As a result, during the period in which the interrupt prohibition state is set, execution of save processing at power-off, timer interrupt processing, and the like, which will be described later, is prohibited.

In step S4-24, test signal output processing is executed, and the process proceeds to step S4-25. In the test signal output process, test information (test signal) is set.
The test signal output process is a process based on a program for executing a test-related process defined by gaming machine regulations. That is, the test signal output processing is processing based on the program stored in the unused area m2 (program area) of the ROM 220 . The test signal tube is invoked during execution of timer interrupt processing.
Specifically, in the test signal output process, test information (test signal) indicating an internal state (jackpot game state, time saving control execution state, special symbol lottery probability state, etc.) is stored in the port output request buffer of the RAM 230.
In step S4-25, performance display device control processing is executed, and the process proceeds to step S4-26. The performance display device control processing will be described later.
In step S4-26, register return processing is executed, a series of processing is completed, and the original processing is returned to. In the register restoration process, the value of the register saved in step S4-1 is restored. After the register return processing is completed, the program returns to the main loop processing (the program address indicated by the stack pointer).

(Dynamic port output processing)
Next, the dynamic port output processing in step S4-3 will be described.
FIG. 11 is a flowchart showing dynamic port output processing.
When the dynamic port output process is executed in step S4-3, as shown in FIG. 11, the process first proceeds to step S29-1.
In step S29-1, output data clear processing is executed, and the process proceeds to step S29-2. In the output data clear process, the A register is cleared (initialized). Specifically, "0" is set as each bit value of the A register.
In step S29-2, main display device data output processing is executed, and the process proceeds to step S29-3. In the main display device data output process, the value of the A register (the value cleared in step S29-1) is output to output port 0. FIG. As a result, the output port 0 is cleared (initialized), and each data signal (“SEGDATA0” to “SEGDATA7”) for controlling lighting of the main display device 60 becomes low level.

In step S29-3, performance display device data output processing is executed, and the process proceeds to step S29-4. In the performance display device data output process, the value of the A register (the value cleared in step S29-1) is output to the output port 4. FIG. As a result, the output port 4 is cleared (initialized), and each data signal (“7SEGDATA0” to “7SEGDATA7”) for controlling lighting of the performance display device 206 becomes low level.
In step S29-4, common selection processing is executed, and the process proceeds to step S29-5. In the common selection process, the value of the common counter is updated.
Specifically, in the common selection process, it is determined whether or not the value of the common counter has reached the upper limit (“3” in this embodiment). Then, when it is determined that the value of the common counter has not reached the upper limit value, "1" is added to the value of the common counter. On the other hand, when it is determined that the value of the common counter has reached the upper limit, a predetermined initial value (“0” in this embodiment) is set as the value of the common counter.

In step S29-5, common output processing is executed, and the process proceeds to step S29-6.
In common output processing, output data corresponding to the value of the common counter is output to output port 1 .
That is, when the value of the common counter is "0", output data is output to the output port 1 with "COM0" set to high level and "COM1", "COM2", and "COM3" set to low level. As a result, "COM0" is selected (output) from among "COM0" to "COM3".
On the other hand, when the value of the common counter=“1”, output data is output to the output port 1 with “COM1” set to high level and “COM0”, “COM2”, and “COM3” set to low level. As a result, "COM1" is selected (output) from among "COM0" to "COM3".
On the other hand, when the value of the common counter=“2”, output data is output to the output port 1 with “COM2” set to high level and “COM0”, “COM1”, and “COM3” set to low level. As a result, "COM2" is selected (output) from among "COM0" to "COM3".
On the other hand, when the value of the common counter=“3”, output data is output to the output port 1 with “COM3” set to high level and “COM0”, “COM1” and “COM2” set to low level. As a result, "COM3" is selected (output) from among "COM0" to "COM3".

Also, in the common output process, the output data of the launch permission signal is output to the output port 1 .
That is, first, it is determined whether or not a playable state has occurred (set).
Then, when it is determined that the game ready state has occurred, it outputs to the output port 1 output data for setting the launch permission signal to a high level. As a result, a launch enable signal is output.
On the other hand, if it is determined that the playable state has not occurred, output data for setting the launch permission signal to low level is output to the output port 1 . This stops the output of the launch permission signal.
Here, based on the value (gaming machine status flag) stored in the gaming machine status flag area of the RAM 230, it is determined whether or not the game ready status has occurred. At this time, when the value stored in the game machine state flag area is a value corresponding to the game possible state, it is determined that the game possible state is generated, and when it is not a value corresponding to the game possible state, it is determined that the game possible state is not generated.
In this embodiment, the output of the launch permission signal is set only when it is determined in the common output process that the playable state has occurred. As a result, the launch permission signal is output only while the game-enabled state is occurring (during setting). However, in the common output process, regardless of the state of the gaming machine, the output of the launch permission signal may be set. With such a configuration, it is possible to have a configuration in which the firing enable signal is always output while the main control board 200 is powered on.

In step S29-6, it is determined whether or not a playable state has occurred (set), and if it is determined that a playable state has occurred (Yes), the process proceeds to step S29-7, and if it is determined that the gameable state has not occurred (No), the process proceeds to step S29-11.
Here, based on the value (gaming machine status flag) stored in the gaming machine status flag area of the RAM 230, it is determined whether or not the game ready status has occurred. At this time, when the value stored in the game machine state flag area is a value corresponding to the game possible state, it is determined that the game possible state is generated, and when it is not a value corresponding to the game possible state, it is determined that the game possible state is not generated.

In step S29-7, main display device data acquisition processing is executed, and the process proceeds to step S29-8. In the main display device data acquisition process, display data for the main display device 60 is acquired and the acquired display data is set in the A register.
Specifically, in the main display device data acquisition process, first, the value of the common counter is checked. Then, among the common 0 to common 3 output request buffers of the RAM 230, the display data set in the output request buffer corresponding to the confirmed common counter value is acquired, and the acquired display data is set in the A register.
At this time, if the value of the common counter is "0", the display data set in the common 0 output request buffer is acquired, and the acquired display data is set in the A register.
On the other hand, when the value of the common counter=“1”, the display data set in the common 1 output request buffer is acquired, and the acquired display data is set in the A register.
On the other hand, when the value of the common counter=“2”, the display data set in the common 2 output request buffer is acquired, and the acquired display data is set in the A register.
On the other hand, when the value of the common counter=“3”, the display data set in the common 3 output request buffer is acquired, and the acquired display data is set in the A register.
Here, the display data acquired in the main display device data acquisition process is the display data set in the common 0 output request buffer to the common 3 output request buffer in the LED display setting process (specifically, normal display data setting process) of step S4-20 included in the previous timer interrupt process.

In step S29-8, main display device data output processing is executed, and the process proceeds to step S29-9. In the main display device data output process, the display data set in the A register in step S29-7 is output to output port 0. FIG.
As a result, data signals (“SEGDATA0” to “SEGDATA7”) based on the display data set in the output request buffer (one of the common 0 output request buffer to common 3 output request buffer) are output to the source driver 250a.
That is, the display on the main display device 60 is controlled based on the display data set in the output request buffer (one of the common 0 output request buffer to the common 3 output request buffer).

In step S29-9, interrupt prohibition processing is executed, and the process proceeds to step S29-10. In the interrupt prohibition process, an interrupt prohibition state is set to prohibit interrupts of other processes. As a result, during the period in which the interrupt prohibition state is set, execution of save processing at power-off, timer interrupt processing, and the like, which will be described later, is prohibited.
In step S29-10, performance display device output processing is executed, a series of processing ends, and the next processing (step S4-4) is performed. Performance display device output processing will be described later.

In step S29-11, performance display device data acquisition processing is executed, and the process proceeds to step S29-12. In the performance display device data acquisition process, display data for the performance display device 206 is acquired and the acquired display data is set in the A register.
Specifically, in the performance display device data acquisition process, first, the value of the common counter is checked. Then, among the common 0 to common 3 output request buffers of the RAM 230, the display data set in the output request buffer corresponding to the confirmed common counter value is acquired, and the acquired display data is set in the A register.
At this time, if the value of the common counter is "0", the display data set in the common 0 output request buffer is acquired, and the acquired display data is set in the A register.
On the other hand, when the value of the common counter=“1”, the display data set in the common 1 output request buffer is acquired, and the acquired display data is set in the A register.
On the other hand, when the value of the common counter=“2”, the display data set in the common 2 output request buffer is acquired, and the acquired display data is set in the A register.
On the other hand, when the value of the common counter=“3”, the display data set in the common 3 output request buffer is acquired, and the acquired display data is set in the A register.
Here, the display data acquired in the performance display device data acquisition process is the display data set in the common 0 output request buffer to the common 3 output request buffer in the LED display setting process (specifically, the setting change display data setting process, the setting confirmation display data setting process, or the abnormal display data setting process) of step S4-20 included in the previous timer interrupt process.

In step S29-12, a performance display device data output process is executed, a series of processes is completed, and the process proceeds to the next process (step S4-4). In the performance display device data output process, the display data set in the A register in step S29-11 is output to the output port 4. FIG.
As a result, data signals (“7SEGDATA0” to “7SEGDATA7”) based on the display data set in the output request buffer (one of the common 0 output request buffer to common 3 output request buffer) are output to the source driver 250b.
That is, the display of the performance display device 206 is controlled based on the display data set in the output request buffer (one of the common 0 output request buffer to the common 3 output request buffer).

(Performance display device output processing)
Next, the performance display device output process in step S29-10 will be described.
FIG. 12 is a flowchart showing performance display device output processing.
Performance display device output processing is processing based on a program for controlling the display of the performance display device 206 . That is, the performance display device output processing is processing based on a program stored in the non-use area m2 (program area) of the ROM 220 . Performance display device output processing is called during execution of dynamic port output processing.
When the performance display device output process is called in step S29-10, as shown in FIG. 12, the process first proceeds to step S30-1.
In step S30-1, register save processing is executed, and the process proceeds to step S30-2. In the register saving process, the values of all the registers used during execution of the process based on the program stored in the use area m1 are saved to the saving area of the RAM. Also, the values of all stack pointers used during the execution of the process based on the program stored in the use area m1 are saved in the save area of the RAM.

In step S30-2, performance display device data acquisition processing is executed, and the process proceeds to step S30-3. In the performance display device data acquisition process, display data for the performance display device 206 is acquired and the acquired display data is set in the A register.
Specifically, in the performance display device data acquisition process, first, the value of the common counter is checked. Then, the display data set in the area corresponding to the value of the confirmed common counter is acquired from the identification segment output request buffer and the ratio segment output request buffer of the RAM 230, and the acquired display data is set in the A register.
At this time, when the value of the common counter is "0", the display data set in the high-order 8 bits of the identification segment output request buffer is acquired, and the acquired display data is set in the A register.
On the other hand, when the value of the common counter=“1”, the display data set in the lower 8 bits of the identification segment output request buffer is acquired, and the acquired display data is set in the A register.
On the other hand, when the value of the common counter=“2”, the display data set in the high-order 8 bits of the ratio segment output request buffer is acquired, and the acquired display data is set in the A register.
On the other hand, when the value of the common counter=“3”, the display data set in the lower 8 bits of the ratio segment output request buffer is acquired, and the acquired display data is set in the A register.
Here, the display data acquired in the performance display device data acquisition process is the display data set in the identification segment output request buffer or the ratio segment output request buffer in the performance display device control process of step S4-25 included in the previous timer interrupt process.

In step S30-3, performance display device data output processing is executed, and the process proceeds to step S30-4. In the performance display device data output process, the display data set in the A register in step S30-2 is output to the output port 4. FIG.
As a result, data signals (“7SEGDATA0” to “7SEGDATA7”) based on the display data set in the output request buffer (identification segment output request buffer or ratio segment output request buffer) are output to the source driver 250b.
That is, the display of the performance display device 206 is controlled based on the display data set in the output request buffer (the identification segment output request buffer or the ratio segment output request buffer).

In step S30-4, register restoration processing is executed, and the process proceeds to step S30-5. In the register restoration process, the value of the register saved in step S30-1 (the value of the register used during the execution of the process based on the program stored in the use area m1) and the value of the stack pointer saved in step S30-1 (the value of the stack pointer used during the execution of the process based on the program stored in the use area m1) are restored.
In step S30-5, interrupt permission processing is executed, a series of processing ends, and the next processing (step S4-4) is performed. In the interrupt permission processing, the interrupt disabled state is canceled. As a result, execution of save processing at power-off, timer interrupt processing, and the like is permitted.

(Setting-related processing)
Next, the setting-related processing in step S4-8 will be described.
FIG. 13 is a flowchart showing setting-related processing.
When the setting-related process is executed in step S4-8, as shown in FIG. 13, the process first proceeds to step S37-1.
In step S37-1, it is determined whether or not a setting change state has occurred (set), and if it is determined that the setting change state has occurred (Yes), the process proceeds to step S37-2, and if it is determined that the setting change state has not occurred (No), the process proceeds to step S37-8.
Here, based on the value (gaming machine status flag) stored in the gaming machine status flag area of the RAM 230, it is determined whether or not the setting change status has occurred. At this time, when the value stored in the game machine state flag area is a value corresponding to the setting change state, it is determined that the setting change state is generated, and when it is not a value corresponding to the setting change state, it is determined that the setting change state is not generated.

In step S37-2, set value acquisition processing is executed, and the process proceeds to step S30-3. In the setting value acquisition process, the setting values stored in the setting value area of the RAM 230 are acquired (loaded), and the acquired setting values are stored in the register.
In step S37-3, it is determined whether or not the RAM clear switch 207 has been pressed. If it is determined that the RAM clear switch 207 has been pressed (Yes), the process proceeds to step S37-4, and if it is determined that the RAM clear switch 207 has not been pressed (No), the process proceeds to step S37-5.
When the ON state of the RAM clear switch 207 has occurred, it is determined that the RAM clear switch 207 has been pressed, and when the ON state has not occurred, it is determined that the RAM clear switch 207 has not been pressed.
In step S37-4, set value update processing is executed, and the process proceeds to step S37-5. In the set value update process, "1" is added to the set value stored in the register.

In step S37-5, it is determined whether or not the set value stored in the register is less than a predetermined set comparison value ("6" in this embodiment). If it is determined that the set value stored in the register is not less than the predetermined set comparison value (the set value is equal to or greater than the predetermined set comparison value) (No), the process proceeds to step S37-6, and if it is determined that the set value stored in the register is less than the predetermined set comparison value (Yes), the process proceeds to step S37-7. .
In step S37-6, set value initialization processing is executed, and the process proceeds to step S37-7. In the setting value initialization process, the setting value stored in the register is overwritten with a predetermined initial value (“0” in this embodiment).
In step S37-7, set value saving processing is executed, and the process proceeds to step S37-8. In the setting value saving process, the setting value stored in the register is saved in the setting value area of the RAM 230 .

In step S37-8, it is determined whether or not the setting key switch 208 is in the ON state. If it is determined that the setting key switch 208 is not in the ON state (it is in the OFF state) (No), the process proceeds to step S37-9.
When the ON state of the setting key switch 208 is generated, it is determined that the setting key switch 208 is ON, and when the ON state is not generated, it is determined that the setting key switch 208 is not ON.
In step S37-9, a subcommand setting process is executed, and the process proceeds to step S37-10. In the subcommand setting process, a setting-related end specifying command (subcommand) is stored in the subcommand output request buffer of the RAM 230 .

In step S37-10, a subcommand group setting process is executed, and the process proceeds to step S37-11. In the subcommand group setting process, the subcommand group is stored in the subcommand output request buffer of RAM 230 .
Here, the subcommand group includes a subcommand that specifies the game state (game state offset value), a subcommand that specifies the firing position, a subcommand that specifies the stop pattern of the first special symbol, a subcommand that specifies the stop symbol of the second special symbol, a subcommand that specifies the special figure 1 reserved number, a subcommand that specifies the special figure 2 reserved number, a subcommand that specifies the value of the time saving counter, a set value specification command that specifies the set value stored in the set value area of the RAM 230, and the like.
At step S37-11, the RAM set process is executed, the series of processes is completed, and the next process (step S4-19) is performed. In the RAM set process, a playable state is set as the gaming machine state.
Specifically, a value corresponding to the playable state is stored (saved) as a value (gaming machine state flag) in the gaming machine state flag area of the RAM 230 .

(switch management processing)
Next, the switch management processing of step S4-12 will be described.
FIG. 14 is a flowchart showing switch management processing.
When the switch management process is executed in step S4-12, as shown in FIG. 14, the process first proceeds to step S5-1.
In step S5-1, it is determined whether or not the ON state of the gate switch 104 has been detected. If it is determined that the ON state of the gate switch 104 has been detected (Yes), the process proceeds to step S5-2, and if it is determined that the ON state of the gate switch 104 has not been detected (No), the process proceeds to step S5-3.
In step S5-2, normal figure starting ball detection processing is executed, and the process proceeds to step S5-3. Normal figure starting ball detection processing will be described later.
In addition, in the normal figure starting ball detection process, it is determined whether or not it is during the right hitting period. Then, if it is determined that the ball is not in the right-handed period (it is in the left-handed period), "1" is added to the value of the right-handed error counter.
In the present embodiment, the period during which one of the game states during the execution of the jackpot game state and the time-saving control is the right-handed period. On the other hand, the period in which the normal game state (the game state in which the jackpot game state is not occurring and the time saving control is stopped) is the left-handed period.

In step S5-3, it is determined whether or not the ON state of the special figure 1 starter switch 101 is detected, and when it is determined that the on state of the special figure 1 starter switch 101 is detected (Yes), the process proceeds to step S5-4, and when it is determined that the on state of the special figure 1 starter switch 101 is not detected (No), the process proceeds to step S5-5.
In step S5-4, a special figure 1 starting ball detection process is executed, and the process proceeds to step S5-5. The special figure 1 starting ball detection processing will be described later.
In step S5-5, it is determined whether or not the on state of the special figure 2 starter switch 102 is detected, and if it is determined that the on state of the special figure 2 starter switch 102 is detected (Yes), the process proceeds to step S5-6, and when it is determined that the on state of the special figure 2 starter switch 102 is not detected (No), the series of processes is terminated and the next process (step S4-13).
In step S5-6, a special figure 2 starting ball detection process is executed, a series of processes is terminated, and the process proceeds to the next process (step S4-13). The special figure 2 starting ball detection processing will be described later.

(normal figure starting ball detection processing)
Next, normal figure starting ball detection processing in step S5-2 will be described.
FIG. 15 is a flow chart showing normal/normal starting ball detection processing.
When the normal chart starting ball detection process is executed in step S5-2, as shown in FIG. 15, first, the process proceeds to step S6-1.
In step S6-1, normal figure random number acquisition processing is executed, and the process proceeds to step S6-2. In the general pattern random number acquisition process, the winning random number (random value) is acquired (loaded) from the loop counter corresponding to the normal symbol lottery.
In step S6-2, it is determined whether the value of the normal figure reservation number counter is the upper limit value ("4" in this embodiment), and if it is determined that the value of the normal figure reservation number counter is not the upper limit value (No), the process proceeds to step S6-3.
In step S6-3, normal figure pending number counter update processing is executed, and the process proceeds to step S6-4. In the general pattern reservation number counter update process, the value obtained by adding "1" to the value set in the general pattern reservation number counter is newly set to the general pattern reservation number counter.

In step S6-4, the general pattern random number storage process is executed, a series of processes is completed, and the process proceeds to the next process (step S5-3). In the general pattern random number storage process, the hit random number obtained in step S6-1 is stored in the general pattern game information storage area of the RAM 230 as the general pattern game information.
The RAM 230 includes a storage area 0 for storing general pattern game information during execution of a game, and a general pattern game information storage area for storing general pattern game information for which normal pattern hit/loss determination is suspended.
The general pattern game information storage area is configured to include a storage area 1 to a storage area 4 as a storage area capable of storing general pattern game information.
The priority of each storage area is defined to be storage area 1, storage area 2, storage area 3, and storage area 4 (higher to lower) in descending order of priority. Then, the general-purpose game information stored in the general-purpose game information storage area is executed in order from the one stored in the storage area with the higher priority order.
In the general pattern random number storage process, the hit random number obtained in step S6-1 is stored in the general pattern game information storage area as the general pattern game information. At this time, the general pattern game information is stored in the storage area with the highest priority among the vacant storage areas.
In other words, if the current general pattern pending number counter value = "1", the random number obtained in step S6-1 is stored in the storage area 1. If the current general pattern pending number counter value = "2", the random number obtained in step S6-1 is stored in the storage area 2. If the current general pattern pending number counter value = "3", the random number obtained in step S6-1 is stored in the storage area 3. If the current general pattern pending number counter value = "4", the random number obtained in step S6-1 is stored in the storage area 4.

(Special figure 1 starting ball detection process)
Next, the special figure 1 starting ball detection process of step S5-4 will be described.
FIG. 16 is a flowchart showing the special figure 1 starting ball detection process.
When the special figure 1 starting ball detection process is executed in step S5-4, as shown in FIG. 16, the process first proceeds to step S7-1.
In step S7-1, a special symbol identification value setting process is executed, and the process proceeds to step S7-2. In the special symbol identification value setting process, in the special symbol identification value setting area of the RAM 230, a special symbol identification value corresponding to the first special symbol lottery is set. In addition, "1" is added to the value of the external information starting entrance ball entry count counter.
Also, in the special symbol identification value setting process, it is determined whether or not it is during the period of hitting to the right. When it is determined that the ball is not in the right-handed period (it is in the left-handed period), the value of the right-handed error counter is reset (the value of the right-handed error counter is set to "0").
In step S7-2, a pending number counter address setting process is executed, and the process proceeds to step S7-3. In the pending number counter address setting process, in the pending number counter address setting area of the RAM 230, the address of the special figure 1 pending number counter is set.
In step S7-3, a special symbol random number acquisition process is executed, a series of processes is terminated, and the process proceeds to the next process (step S5-5). The special symbol random number acquisition process will be described later.

(Special figure 2 starting ball detection process)
Next, the special figure 2 starting ball detection process of step S5-6 will be described.
FIG. 17 is a flowchart showing the special figure 2 starting ball detection process.
When the special figure 2 starting ball detection process is executed in step S5-6, as shown in FIG. 17, the process first proceeds to step S8-1.
In step S8-1, a special symbol identification value setting process is executed, and the process proceeds to step S8-2. In the special symbol identification value setting process, a special symbol identification value corresponding to the second special symbol lottery is set in the special symbol identification value setting area of the RAM 230 . In addition, "1" is added to the value of the external information starting entrance ball entry count counter.
Also, in the special symbol identification value setting process, it is determined whether or not it is during the period of hitting to the right. When it is determined that the ball is not in the right-handed period (it is in the left-handed period), "1" is added to the value of the right-handed error counter.
In step S8-2, a pending number counter address setting process is executed, and the process proceeds to step S8-3. In the pending number counter address setting process, in the pending number counter address area of the RAM 230, the address of the special figure 2 pending number counter is set.
In step S8-3, a special symbol random number acquisition process is executed, a series of processes is completed, and the process proceeds to the next process (step S4-13). The special symbol random number acquisition process will be described later.

(Special symbol random number acquisition process)
Next, the special symbol random number acquisition process of steps S7-3 and S8-3 will be described.
FIG. 18 is a flow chart showing a special symbol random number acquisition process.
When the special symbol random number acquisition process is executed in steps S7-3 and S8-3, as shown in FIG. 18, the process first proceeds to step S9-1.
In step S9-1, a special symbol identification value acquisition process is executed, and the process proceeds to step S9-2. In the special symbol identification value acquisition process, the special symbol identification value set in the special symbol identification value setting area of the RAM 230 is acquired (loaded).
In step S9-2, a special figure pending number acquisition process is executed, and the process proceeds to step S9-3. In the special figure reservation number acquisition process, the value of the special figure reservation number counter (special figure 1 reservation number counter or special figure 2 reservation number counter) specified by the address set in the reservation number counter address area (special figure 1 reservation number or special figure 2 reservation number) is acquired (loaded).

In step S9-3, a special random number acquisition process is executed, and the process proceeds to step S9-4. In the special random number acquisition process, various random numbers (random numbers) such as jackpot random numbers, winning pattern random numbers, reach group random numbers, reach mode random numbers, and variation pattern random numbers are acquired (loaded) from loop counters corresponding to each lottery. At this time, a corresponding loop counter is selected based on the special symbol identification value acquired in step S9-1.
In step S9-4, it is determined whether or not the special figure reservation number (special figure 1 reservation number or special figure 2 reservation number) acquired in step S9-2 is the upper limit value ("4" in this embodiment), and if it is determined that the special figure reservation number is not the upper limit value (No), the process proceeds to step S9-5, and if it is determined that the special figure reservation number is the upper limit value (Yes), the series of processes is terminated and the next process (step S4-13 or S5-5). do.
In step S9-5, a special figure pending number counter update process is executed, and the process proceeds to step S9-6. In the special figure reservation number counter update process, the value set in the special figure reservation number counter (special figure 1 reservation number counter or special figure 2 reservation number counter) specified by the address set in the reservation number counter address area The value obtained by adding "1" is newly set to the special figure reservation number counter.

In step S9-6, a special random number saving process is executed, and the process proceeds to step S9-7. In the special figure random number saving process, the various random numbers obtained in step S9-3 are stored in the special figure game information storage area (special figure 1 game information storage area or special figure 2 game information storage area) of the RAM 230 as special figure game information (special figure 1 game information or special figure 2 game information).
The RAM 230 includes a storage area 0 for storing special figure game information during game execution, a special figure 1 game information storage area for storing special figure 1 game information for which start determination is suspended, and a special figure 2 game information storage area for which start determination is suspended.
The special figure 1 game information storage area is configured including a storage area 1 to a storage area 4 as a storage area capable of storing the special figure 1 game information.
The priority of each storage area is defined to be storage area 1, storage area 2, storage area 3, and storage area 4 (higher to lower) in descending order of priority. Then, for the special figure 1 game information stored in the special figure 1 game information storage area, starting determination is executed in order from the one stored in the storage area with the higher priority.
The special figure 2 game information storage area is configured including a storage area 1 to a storage area 4 as a storage area capable of storing the special figure 2 game information.
The priority of each storage area is defined to be storage area 1, storage area 2, storage area 3, and storage area 4 (higher to lower) in descending order of priority. Then, for the special figure 2 game information stored in the special figure 2 game information storage area, starting determination is executed in order from the one stored in the storage area with the higher priority.

In the special figure random number storage process, when the special symbol identification value acquired in step S9-1 is a value corresponding to the first special symbol lottery, various random numbers acquired in step S9-3 are stored as special figure 1 game information in the special figure 1 game information storage area. At this time, the various random numbers obtained in step S9-3 are stored in the memory area with the highest priority among the free memory areas.
That is, when the value of the current special figure 1 pending number counter = "1", various random numbers obtained in step S9-3 are stored in the storage area 1. If the value of the current special figure 1 pending number counter = "2", the various random numbers obtained in step S9-3 are stored in the storage area 2. If the value of the current special figure 1 pending number counter = "3", various random numbers obtained in step S9-3 are stored in the storage area 3. If the value of the current special figure 1 pending number counter = "4", the various random numbers obtained in step S9-3 are stored in the storage area 4.
On the other hand, when the special symbol identification value acquired in step S9-1 is a value corresponding to the second special symbol lottery, various random numbers acquired in step S9-3 are stored as special figure 2 game information in the special figure 2 game information storage area. At this time, the various random numbers obtained in step S9-3 are stored in the memory area with the highest priority among the free memory areas.
That is, when the value of the current special figure 2 pending number counter = "1", various random numbers obtained in step S9-3 are stored in the storage area 1. If the value of the current special figure 2 pending number counter = "2", the various random numbers obtained in step S9-3 are stored in the storage area 2. If the value of the current special figure 2 pending number counter = "3", the various random numbers obtained in step S9-3 are stored in the storage area 3. If the value of the current special figure 2 pending number counter = "4", the various random numbers obtained in step S9-3 are stored in the storage area 4.

In step S9-7, a hold number designation command setting process is executed, and the process proceeds to step S9-8. In the pending number specification command setting process, a pending number specifying command specifying that the special figure pending number (special figure 1 pending number or special figure 2 pending number) has increased by "1" is stored in the subcommand output request buffer of the RAM 230. At this time, when the special symbol identification value acquired in step S9-1 is a value corresponding to the first special symbol lottery, a reserved number designation command specifying that the special figure 1 reserved number has increased by "1" is stored in the sub-command output request buffer of the RAM 230. If the value corresponds to the second special symbol lottery, a reserved number designation command specifying that the special figure 2 reserved number has increased by "1" is stored in the sub-command output request buffer of the RAM 230.

In step S9-8, a preliminary determination process is executed, a series of processes is terminated, and the process proceeds to the next process (step S4-13 or S5-5). In the pre-determination process, the game information (special figure 1 game information or special figure 2 game information) stored (stored) in the special figure game information storage area (special figure 1 game information storage area or special figure 2 game information storage area) in step S9-6.
In this embodiment, for all game information (special figure 1 game information and special figure 2 game information), prior determination of various lottery results is executed.
In addition, regarding the game information acquired (stored) during the occurrence of the jackpot game state, the configuration may be such that the pre-determination of various lottery results is not executed. In addition, for the special figure 2 game information acquired (stored) while the time saving control is stopped, the preliminary determination of various lottery results is not executed, and the special figure 1 game information acquired (stored) during the execution of the time saving control.

In the prior determination process, first, the prior special figure per determination process is executed.
In the preliminary special figure hit determination process, the result of the special symbol lottery ("big hit" or "loss") is determined (preliminary special figure hit determination).
The ROM 220 stores a special symbol lottery table in which the jackpot values of the special symbol lottery are registered. In addition, as a special figure winning/losing lottery table, a special figure winning/losing lottery table corresponding to each combination of a set value ("1" to "6") and a game state ("special figure low probability state" or "special figure high probability state") is stored.
Specifically, as the special figure hit-drop lottery table, "Set value 1 low probability special figure hit-drop lottery table", "Set value 1 high probability special figure hit-drop lottery table", "Set value 2 low probability special figure hit-drop lottery table", "Set value 2 high probability special figure hit-drop lottery table", "Set value 3 low probability special figure hit-drop lottery table", "Set value 3 high probability special figure hit-drop lottery table", "Set value 4 low probability special figure hit-drop lottery table" , ``set value 4 high probability special figure win-loss lottery table'', ``set value 5 low probability special figure win-loss lottery table'', ``set value 5 high probability special figure win-loss lottery table'', ``set value 6 low probability special figure win-loss lottery table'', and ``set value 6 high probability special figure win-loss lottery table'' are stored.

The ``set value 0 low probability special figure winning lottery table'' is selected when the set value = ``0'' and ``0'' is set in the special figure high probability state flag area ("special figure low probability state" is occurring). And, in the "setting value 0 low probability special figure winning lottery table", "0" to "204" among the big winning random numbers "0" to "65535" are registered as big winning values.
The ``set value 0 high probability special figure winning lottery table'' is selected when the set value = ``0'' and ``1'' is set in the special figure high probability state flag area ("special figure high probability state" is occurring). And, in the "set value 0 high probability special figure win-lose lottery table", "0" to "2039" among the jackpot random numbers "0" to "65535" are registered as jackpot values.
The ``set value 1 low probability special figure winning lottery table'' is selected when the set value = ``1'' and ``0'' is set in the special figure high probability state flag area ("special figure low probability state" is occurring). And, in the "setting value 1 low-probability special drawing lottery table", "0" to "209" among the jackpot random numbers "0" to "65535" are registered as jackpot values.
The ``set value 1 high probability special figure winning lottery table'' is selected when the set value = ``1'' and ``1'' is set in the special figure high probability state flag area ("special figure high probability state" is occurring). And, in the "setting value 1 high probability special figure win-lose lottery table", "0" to "2089" among the jackpot random numbers "0" to "65535" are registered as jackpot values.
The ``set value 2 low probability special figure winning lottery table'' is selected when the set value = ``2'' and ``0'' is set in the special figure high probability state flag area ("special figure low probability state" is occurring). Then, in the "setting value 2 low probability special figure win-lose lottery table", "0" to "214" among the jackpot random numbers "0" to "65535" are registered as jackpot values.
The ``set value 2 high probability special figure winning lottery table'' is selected when the set value = ``2'' and ``1'' is set in the special figure high probability state flag area ("special figure high probability state" is occurring). Then, in the "setting value 2 high probability special figure win-lose lottery table", "0" to "2139" among the jackpot random numbers "0" to "65535" are registered as jackpot values.

The ``set value 3 low probability special figure winning lottery table'' is selected when the set value = ``3'' and ``0'' is set in the special figure high probability state flag area ("special figure low probability state" is occurring). Then, in the "setting value 3 low probability special figure win-lose lottery table", "0" to "219" among the jackpot random numbers "0" to "65535" are registered as jackpot values.
The ``set value 3 high probability special figure winning lottery table'' is selected when the set value = ``3'' and ``1'' is set in the special figure high probability state flag area ("special figure high probability state" is occurring). And, in the "set value 3 high probability special figure win-lose lottery table", "0" to "2189" among the big hit random numbers "0" to "65535" are registered as big hit values.
The ``set value 4 low probability special figure winning lottery table'' is selected when the set value = ``4'' and ``0'' is set in the special figure high probability state flag area ("special figure low probability state" is occurring). And, in the "set value 4 low-probability special figure win-lose lottery table", "0" to "224" among the jackpot random numbers "0" to "65535" are registered as jackpot values.
The ``set value 4 high probability special figure winning lottery table'' is selected when the set value = ``4'' and ``1'' is set in the special figure high probability state flag area ("special figure high probability state" is occurring). And, in the "setting value 4 high probability special figure winning lottery table", among the big hit random numbers "0" to "65535", "0" to "2239" are registered as big hit values.
The ``set value 5 low probability special figure winning lottery table'' is selected when the set value = ``5'' and ``0'' is set in the special figure high probability state flag area ("special figure low probability state" is occurring). And, in the "setting value 5 low-probability special figure win-lose lottery table", "0" to "229" among the jackpot random numbers "0" to "65535" are registered as jackpot values.
The ``set value 5 high probability special figure winning lottery table'' is selected when the set value = ``5'' and ``1'' is set in the special figure high probability state flag area ("special figure high probability state" is occurring). And, in the "set value 5 high probability special figure win-lose lottery table", "0" to "2289" among the jackpot random numbers "0" to "65535" are registered as jackpot values.

In the pre-special figure winning determination processing, the value (set value) set in the set value area and the current game state ("special figure high probability state" or "special figure low probability state") are confirmed, and a special figure winning lottery table corresponding to the confirmation result is read.
Then, the result of the special pattern lottery ("big hit" or "loss") is determined (preliminary special symbol hit determination) based on the big hit random number included in the game information to be determined in advance and the read special symbol winning lottery table.
Specifically, when the value of the jackpot random number included in the game information to be pre-determined coincides with the jackpot value registered in the read-out special-pattern win-loss lottery table, the result of the special pattern lottery is determined as a ``big win'' (winning).
On the other hand, when the value of the jackpot random number included in the game information to be pre-determined does not match with the jackpot value registered in the read-out special win-lose lottery table (when it matches with the outlier value), the result of the special pattern lottery is determined as ``losing'' (loss).

In advance determination processing, next, advance special symbol design determination processing is executed. In the prior special symbol determination process, the type of the stop symbol of the special symbol is determined (preliminary special symbol determination).
In the pre-special figure design determination process, when it is determined as a "big hit" (winning) by the pre-special figure per determination, the type of "big hit design" is determined (preliminary special figure design determination).
The ROM 220 stores a jackpot symbol lottery table in which the correspondence between the jackpot symbol random number and the type of "big hit symbol" is registered. In addition, as the jackpot pattern lottery tables, a first jackpot pattern lottery table corresponding to the first special pattern lottery and a second jackpot pattern lottery table corresponding to the second special pattern lottery are stored.
In the first big-hit symbol lottery table, "big-hit 1 symbol" and "big-hit 2 symbols" are registered as types of "big-hit symbols". On the other hand, in the second big-hit symbol lottery table, "big-hit 3 symbols" to "big-hit 6 symbols" are registered as types of "big-hit symbols".
Then, when the pre-determination target game information is the special figure 1 game information, the first big hit symbol lottery table is read. Then, based on the winning symbol random number included in the pre-determination target game information and the read first big winning symbol lottery table, the type of the big winning symbol is determined.
On the other hand, when the pre-determination target game information is the special figure 2 game information, the second big hit symbol lottery table is read. Then, based on the winning symbol random number included in the pre-determination target game information and the read second big winning symbol lottery table, the type of the big winning symbol is determined.
On the other hand, in the preliminary special figure design determination processing, when it is determined as "lost" (defeated) by preliminary special figure hit determination, "lost design" is determined as the type of the stop design (preliminary special figure design determination).

In the advance determination process, next, a first prefetch designation command setting process is executed.
In the first look-ahead specification command setting process, the sub-command output request buffer of the RAM 230 stores a first look-ahead specification command that specifies the type of the stop symbol determined by the pre-special symbol symbol determination.

In advance determination processing, next, advance special figure variation mode determination processing is executed.
At this time, if it is determined to be "lost" (lost) by the pre-special figure per determination, the pre-special figure variation determination process at the time of defeat, which will be described later, is executed. On the other hand, when it is determined as a "jackpot" (winning) by the prior special figure hit determination, a prior special figure variation mode determination process at the time of winning, which will be described later, is executed.

In the preliminary special figure variation mode determination process at the time of defeat, first, preliminary random number type determination is performed.
In the preliminary random number type determination, it is determined whether the reach group random number included in the preliminary determination target game information is an "indefinite value" or a "fixed value".
Here, when the reach group random number included in the pre-determination target game information is an “undefined value”, when acquiring (storing) the game information (special figure 1 game information or special figure 2 game information), the variation mode number (primary variation mode number) and the variation pattern number are not determined.
On the other hand, when the reach group random number included in the pre-determination target game information is a "fixed value", when acquiring (storing) the game information (special figure 1 game information or special figure 2 game information) (step S9-8), the variation mode number (primary variation mode number) and the variation pattern number are determined.
In this embodiment, the reach group random number value is updated within the range of "0" to "10006". Among "0" to "10006", "0" to "8499" are set as "indefinite values", and "8500" to "10006" are set as "fixed values".
Therefore, in the pre-random number type determination, if the value of the reach group random number included in the pre-determination target game information is less than "8500", it is determined as "indefinite value", and if the value of the reach group random number included in the pre-determination target game information is "8500" or more, it is determined as "fixed value".

In the preliminary special figure variation mode determination processing at the time of defeat, when it is determined as a "fixed value" by preliminary random number type determination, further, prior reach group determination, prior variation mode determination at the time of failure, and prior variation pattern determination at the time of failure are performed.
In addition, in the preliminary special figure variation mode determination processing at the time of defeat, when it is determined as "indefinite value" by prior random number type determination, prior reach group determination, prior variation mode determination at the time of defeat, and variation pattern determination at the time of defeat are not executed.

In prior reach group determination, reach group number (type of reach group) is determined.
The ROM 220 stores a reach group determination table in which correspondence between reach group random numbers and reach group numbers (types of reach groups) is registered.
In addition, as a reach group determination table, a reach group determination table corresponding to each combination of a reservation type (special figure 1 game information or special figure 2 game information), a number of reservations (“0” to “3”), and a game state (low probability state, time saving state, probability variable state, or latent probability state) is stored.
Here, in the present embodiment, as the gaming state, a low probability state, a time saving state, a variable probability state, and a latent probability state are defined.
The "low probability state" is a game state during the occurrence of the special figure low probability state and during the stop of the time saving control. "Working time saving state" is a game state in which the special figure low probability state is occurring and working time saving control is being executed. "Variable probability state" is a game state during the occurrence of a special figure high probability state and during execution of time saving control. "Potential state" is a game state in which the special figure high probability state is occurring and the time saving control is stopped.
In the preliminary reach group determination, first, the reservation type (type of game information targeted for preliminary determination (special figure 1 game information or special figure 2 game information), the number of reservations, and the game state are confirmed, and the reach group determination table corresponding to the confirmation result is read.At this time, the number of reservations is assumed to be "0".
Then, the reach group number is determined based on the reach group random number included in the pre-determination target game information and the read reach group determination table.

In the preliminary fluctuation mode determination at the time of defeat, the fluctuation mode number (variation mode type) is judged.
The ROM 220 stores a variation mode determination table in which correspondences between reach mode random numbers and variation mode numbers (variation mode types) are registered.
In addition, as the variation mode determination table, a losing variation mode determination table and a winning variation mode determination table are stored.
Further, as a failure change mode determination table, a failure change mode determination table corresponding to each reach group number (type of reach group) is stored.
In particular, in each variation mode determination table, each reach mode random number is associated with a variation mode number (type of variation mode) and a variation pattern determination table (information specifying a variation pattern determination table). Thereby, the variation mode number (type of variation mode) and the variation pattern determination table are simultaneously selected based on each variation mode determination table.
In the preliminary fluctuation mode determination at the time of failure, first, the reach group number determined by the preliminary reach group determination is confirmed, and the fluctuation mode determination table at the time of failure corresponding to the confirmation result is read.
Then, the variation mode number (type of variation mode) and the variation pattern determination table are determined based on the ready-to-win mode random number included in the pre-determination target game information and the read loss-time variation mode determination table.

In the preliminary fluctuation pattern determination at the time of defeat, the fluctuation pattern number (variation pattern type) is judged.
The ROM 220 stores a variation pattern determination table in which correspondences between variation pattern random numbers and variation pattern numbers (variation pattern types) are registered.
Also, a plurality of variation pattern determination tables having different contents are stored as variation pattern determination tables.
In the prior variation pattern determination at the time of failure, first, the variation pattern determination table determined by the preliminary variation mode determination at the time of failure is read.
Then, the variation pattern number (variation pattern type) is determined based on the variation pattern random number included in the pre-determination target game information and the read variation pattern determination table.

On the other hand, in the prior special figure variation mode determination processing at the time of winning, first, prior variation mode determination at the time of winning is executed.
In the prior variation mode determination at the time of winning, the variation mode number (type of variation mode) is determined.
In the winning-time prior variation mode determination, first, the winning-time variation mode determination table is read.
Then, the variation mode number (variation mode type) and the variation pattern determination table are determined based on the ready-to-win mode random number included in the pre-determination target game information and the read winning variation mode determination table.

In the prior special figure variation mode determination process at the time of winning, next, prior variation pattern determination at the time of winning is executed.
In the prior variation pattern determination at the time of winning, the variation pattern number (variation pattern type) is determined.
In the winning-time prior variation pattern determination, first, the variation pattern determination table determined by the winning-time prior variation mode determination is read.
Then, the variation pattern number (variation pattern type) is determined based on the variation pattern random number included in the pre-determination target game information and the read variation pattern determination table.

In the advance determination process, next, second and third look-ahead designation command setting processes are executed.
In the second and third look-ahead specification command setting processing, when it is determined as "lost" (lost) by the preliminary special prize hit determination and "fixed value" by the preliminary random number type determination, the second look-ahead specification command for specifying the variation mode number determined by the prior variation mode determination at the time of defeat and the third look-ahead specification command for designating the variation pattern number determined by the prior variation pattern determination at the time of failure are stored in the subcommand output request buffer of the RAM 230.
On the other hand, when it is determined as ``missing'' (failed) by preliminary special hit determination and ``undefined value'' by preliminary random number type determination, a second look-ahead designation command designating an ``undefined value'' and a third look-ahead designation command designating an ''undefined value'' are stored in a subcommand output request buffer of a RAM 230. - 特許庁
On the other hand, when it is determined as a ``big hit'' (winning) by preliminary special prize determination, a second look-ahead designation command designating a variation mode number determined by preliminary variation mode determination at winning and a third look-ahead designation command designating a variation pattern number determined by prior variation pattern determination at winning are stored in a subcommand output request buffer of RAM 230. - 特許庁

As described above, when the value of the reach group random number included in the game information to be pre-determined is a "fixed value", the variation mode number and the variation pattern number are determined, and the second and third look-ahead designation commands for designating the determined variation mode number and variation pattern number are transmitted to the performance control board 300.
On the other hand, when the value of the reach group random number included in the game information to be pre-determined is an "undefined value", the variation mode number and the variation pattern number are not determined, and the second and third look-ahead designation commands designating the "undefined value" are transmitted to the performance control board 300.例文帳に追加

(Special game management processing)
Next, the special game management process of step S4-13 will be explained.
FIG. 19 is a flowchart showing special game management processing.
In this embodiment, seven phases and stages (hereinafter referred to as "special game phases") of a game (hereinafter referred to as "special game") executed based on the special symbol lottery are defined as "special figure fluctuation waiting state", "special figure fluctuation state", "special figure stop symbol display state", "state before large winning opening open", "large winning opening opening control state", "large winning opening closing valid state" and "large winning opening opening end wait state".
Then, in the special game phase flag area of the RAM 230, a value (special game phase flag) corresponding to one of the seven special game phases is set.
Also, the ROM 220 stores a special game control module corresponding to each special game phase as a special game control module (program) for controlling (executing) the special game.
Then, in the special game management process, a special game control module corresponding to the value set in the special game phase flag area of the RAM 230 is selected, and a process based on the selected special game control module is executed.

Specifically, when the special game management process is executed in step S4-13, as shown in FIG. 19, the process first proceeds to step S10-1.
In step S10-1, special game phase acquisition processing is executed, and the process proceeds to step S10-2. In the special game phase acquisition process, the value (special game phase) set in the special game phase flag area of the RAM 230 is acquired (loaded).
In step S10-2, a special game control module acquisition process is executed, and the process proceeds to step S10-3. In the special game control module acquisition process, the special game control module corresponding to the value (special game phase) acquired in step S10-1 is read.
In step S10-3, a special game control module execution process is executed, a series of processes is terminated, and the process proceeds to the next process (step S4-14). In the special game control module execution process, the process based on the special game control module read in step S10-2 is started.
Specifically, if the value obtained in step S10-1 is a value corresponding to the "special figure fluctuation waiting state", the special figure fluctuation waiting process described later is started, if the value corresponds to the "special figure fluctuation state", the special figure fluctuation process that will be described later is started, and if the value corresponds to the "special figure stop symbol display state", the special figure stop process that will be described later is started. When the value corresponds to the "large winning opening open control state", the large winning opening opening control process described later is started, and when the value corresponds to the "large winning opening closing valid state", the large winning opening closing effective processing described later is started, and when the value corresponds to the "big winning opening opening end wait state", the big winning opening opening end waiting process described later is started.

(Special figure fluctuation waiting process)
Next, the special figure variation waiting process executed in step S10-3 will be described.
FIG. 20 is a flowchart showing the special figure variation waiting process.
When the special figure variation waiting process is executed in step S10-3, as shown in FIG. 20, the process first proceeds to step S11-1.
In step S11-1, it is determined whether the value of the special figure 2 reservation number counter is "1" or more, and if it is determined that the value of the special figure 2 reservation number counter is not "1" or more (No), the process moves to step S11-2, and if it is determined that the value of the special figure 2 reservation number counter is "1" or more (Yes), the process proceeds to step S11-3.
In step S11-2, it is determined whether or not the value of the special figure 1 reserved number counter is "1" or more, and if it is determined that the value of the special figure 1 reserved number counter is "1" or more (Yes), the process moves to step S11-3, and if it is determined that the value of the special figure 1 reserved number counter is not "1" or more (No), the process moves to step S11-16.

In step S11-3, a special figure pending number update process is executed, and the process proceeds to step S11-4. In the special figure reservation number update process, the special figure reservation number (special figure 1 reservation number or special figure 2 reservation number) is updated.
Specifically, in the special figure reservation number update process, first, it is determined whether or not the value of the special figure 2 reservation number counter is "1" or more.
Then, when the value of the special figure 2 reserved number counter is "1" or more, a value ("1" in this embodiment) specifying a game based on the special figure 2 game information is set as the special symbol discrimination flag set value, and "1" is subtracted from the value of the special figure 2 reserved number counter.
On the other hand, if it is determined that the value of the special figure 2 reserved number counter is not "1" or more (the value of the special figure 2 reserved number counter is "0"), a value ("0" in this embodiment) that designates a game based on the special figure 1 game information is set as the special symbol determination flag setting value, and "1" is subtracted from the value of the special figure 1 reserved number counter.
In step S11-4, a hold number designation command setting process is executed, and the process proceeds to step S11-5. In the pending number designation command setting process, a pending number designation command specifying that the special figure pending number has decreased by "1" is stored in the subcommand output request buffer of the RAM230.
Concretely, when the special symbol discrimination flag setting value = "1", the reserved number designation command specifying that the special figure 2 reserved number has decreased by "1" is stored in the subcommand output request buffer of the RAM230.
On the other hand, if the special symbol discrimination flag set value = "0", a reserved number designation command specifying that the special figure 1 reserved number has decreased by "1" is stored in the sub-command output request buffer of the RAM 230.

In step S11-5, a special pattern storage area shift process is executed, and the process proceeds to step S11-6. In the special symbol storage area shift process, the storage area in which the game information is stored is shifted.
Concretely, when the special symbol discrimination flag setting value=“1”, the storage contents of the storage area 1 of the special figure 2 game information storage area are shifted (moved) to the storage area 0. Next, the storage contents of the storage area 2 of the special figure 2 game information storage area are shifted to the storage area 1 of the special figure 2 game information storage area. Next, the storage contents of the storage area 3 of the special figure 2 game information storage area are shifted to the storage area 2 of the special figure 2 game information storage area. Next, the storage contents of the storage area 4 of the special figure 2 game information storage area are shifted to the storage area 3 of the special figure 2 game information storage area. Next, clear (initialize) the storage contents of the storage area 4 of the special figure 2 game information storage area.
On the other hand, if the set value of the special symbol discrimination flag=“0”, the contents stored in the storage area 1 of the special figure 1 game information storage area are shifted (moved) to the storage area 0. Next, the storage contents of the storage area 2 of the special figure 1 game information storage area are shifted to the storage area 1 of the special figure 1 game information storage area. Next, the storage contents of the storage area 3 of the special figure 1 game information storage area are shifted to the storage area 2 of the special figure 1 game information storage area. Next, the storage contents of the storage area 4 of the special figure 1 game information storage area are shifted to the storage area 3 of the special figure 1 game information storage area. Next, clear (initialize) the storage contents of the storage area 4 of the special figure 1 game information storage area.

In step S11-6, setting abnormality determination processing is executed, and the process proceeds to step S11-7. In the setting error determination process, occurrence of setting error is monitored.
Specifically, in the setting abnormality determination process, first, the setting value stored in the setting value area of the RAM 230 is obtained. Next, it is determined whether or not the acquired setting value is less than a predetermined setting comparison value (“6” in this embodiment).
When it is determined that the acquired set value is not less than a predetermined set comparison value (is greater than or equal to a predetermined set comparison value), the value corresponding to the set abnormal state is saved as the value of the game machine state flag area (game machine state flag) of the RAM 230. Also, a subcommand specifying the occurrence of a setting error is stored in the subcommand output request buffer. Then, the process proceeds to the next process (step S11-7).
On the other hand, if it is determined that the obtained setting value is less than the predetermined setting comparison value, the next process (step S11-7) is performed.

In step S11-7, a special figure hit determination process is executed, and the process proceeds to step S11-8. In the special figure hit determination process, the result of the special symbol lottery is determined (special figure hit determination).
In the special figure winning judgment processing, first, the set value stored in the set value area of the RAM 230 and the current game state ("special figure high probability state" or "special figure low probability state") are confirmed, and a special figure winning lottery table corresponding to the confirmation result is read.
Based on the big win random number included in the game information stored in the storage area 0 and the read special symbol winning lottery table, it is determined whether or not the result of the special symbol lottery is "big win" (special symbol winning determination).
Specifically, when the value of the jackpot random number included in the game information stored in the storage area 0 coincides with the jackpot value registered in the read-out special win-lost lottery table, the result of the special pattern lottery is determined as "big hit" (winning).
On the other hand, when the value of the jackpot random number included in the game information stored in the storage area 0 does not match the jackpot value registered in the read-out special symbol win/lose lottery table (when it agrees with the loss value), the result of the special pattern lottery is determined as ``losing'' (loss).

In step S11-8, a special symbol determination process is executed, and the process proceeds to step S11-9. In the special symbol determination process, the type of the stop symbol of the special symbol is determined (special symbol determination).
Concretely, in the special figure design determination processing, first, it is determined whether or not it is determined as a "big hit" (election) by special figure hit determination.
Then, when it is determined as a "big hit" (winning) by special figure hit determination, the type of "big hit design" is determined.
For this, when the set value of the special symbol discrimination flag=“0”, the first big hit symbol lottery table is read. Then, based on the winning symbol random number included in the game information stored in the storage area 0 and the read first big winning symbol lottery table, the type of the big winning symbol is determined.
On the other hand, when the set value of the special symbol discrimination flag=“1”, the second big hit symbol lottery table is read. Then, based on the winning symbol random number included in the game information stored in the storage area 0 and the read second big winning symbol lottery table, the type of the big winning symbol is determined.
On the other hand, when it is determined to be "lost" (lost) by the special figure hit determination, "missing design" is determined as the type of the stop design.
Next, a value corresponding to the determined stop symbol type is set in the special symbol determination flag area of the RAM 230 .
In step S11-9, a pattern type designation command setting process is executed, and the process proceeds to step S11-10. In the symbol type designation command setting process, the symbol type designation command designating the type of the stop symbol determined in step S11-8 is stored in the subcommand output request buffer.

In step S11-10, a special figure stop pattern number determination process is executed, and the process proceeds to step S11-11. In the special figure stop design number determination process, the stop design number of the special design is determined.
The ROM 220 stores a stop symbol number lottery table in which correspondences between winning symbol random numbers and stop symbol numbers (segment data) are registered.
Also, as a stop pattern number lottery table, a stop pattern number lottery table at the time of winning corresponding to the case of winning the special pattern lottery (first special pattern lottery or second special pattern lottery) and a stop pattern number lottery table at the time of losing corresponding to the case of losing the special pattern lottery (first special pattern lottery or second special pattern lottery) are stored.
Further, as winning stop pattern number lottery tables, a winning stop pattern number lottery table corresponding to the first special symbol lottery and a winning stop pattern number lottery table corresponding to the second special symbol lottery are stored.
In the special figure stop pattern number determination process, first, the result of the special figure hit determination is confirmed.
Then, when it is determined as a "big hit" (winning) by the special symbol winning determination, the setting value of the special symbol discrimination flag is confirmed, and the stop symbol number lottery table corresponding to the confirmation result is read. Then, the stop symbol number is determined based on the winning symbol random number included in the game information stored in the storage area 0 and the read winning stop symbol number lottery table.
On the other hand, when it is determined to be "lost" (lost) by the special figure per determination, the stop design number lottery table is read when losing. Then, the stop symbol number is determined based on the winning symbol random number included in the game information stored in the storage area 0 and the read stop symbol number lottery table upon losing.
Next, the determined stop symbol number is stored in the stop symbol number storage area of the RAM 230 .

In step S11-11, a special figure variation pattern determination process is executed, and the process proceeds to step S11-12. In the special figure variation pattern determination process, the variation mode of the special symbol (variation mode type and variation pattern type) is determined.
Specifically, in the special figure variation pattern determination process, first, the result of the special figure per determination is confirmed. And, if the result of the special figure hit determination is "missing" (lost), the special figure fluctuation state determination processing at the time of defeat, which will be described later, is executed. On the other hand, when the result of the special figure hit determination is "big hit" (winning), the special figure variation mode determination process at the time of winning, which will be described later, is executed.

In the special figure variation mode determination process at the time of defeat, reach group determination is first performed.
In the reach group determination, the reach group number (type of reach group) is determined.
In the reach group determination, first, the reservation type (the type of game information stored in the storage area 0 (special figure 1 game information or special figure 2 game information), the number of reservations, and the game state are confirmed, and the reach group determination table corresponding to the confirmation result is read.
Then, the reach group type is determined based on the reach group random number included in the game information stored in the storage area 0 and the read reach group determination table.
In the special figure variation mode determination process at the time of losing, next, the variation mode determination at the time of losing is executed.
In the determination of the fluctuation mode at the time of failure, the fluctuation mode number (type of fluctuation mode) and the fluctuation pattern judgment table are judged.
In the determination of fluctuation mode when losing, first, the reach group number determined by the reach group determination is confirmed, and the fluctuation mode determination table when losing is read corresponding to the confirmation result.
Then, a variation mode number (type of variation mode) and a variation pattern determination table are determined based on the ready-to-win mode random number included in the game information stored in the storage area 0 and the read-out variation mode determination table at loss.
In the special figure variation mode determination process at the time of losing, next, at the time of losing the variation pattern determination is executed.
In the determination of the fluctuation pattern at the time of defeat, the fluctuation pattern number (variation pattern type) is judged.
In the determination of variation pattern at the time of failure, first, the variation pattern determination table determined by the determination of the variation mode at the time of failure is read.
Then, the variation pattern number (type of variation pattern) is determined based on the variation pattern random number included in the game information stored in the storage area 0 and the read variation pattern determination table.

On the other hand, in the special figure variation mode determination process at the time of winning, first, variation mode determination at the time of winning is executed.
In the winning variation mode determination, a variation mode number (variation mode type) and a variation pattern table are determined.
In the winning variation mode determination, first, the winning variation mode determination table is read.
Then, a variation mode number (type of variation mode) and a variation pattern determination table are determined based on the ready-to-win mode random number included in the game information stored in the storage area 0 and the read winning variation mode determination table.
In the special figure variation mode determination process at the time of winning, next, variation pattern determination at the time of winning is executed.
In winning variation pattern determination, a variation pattern number (variation pattern type) is determined.
In the winning variation pattern determination, first, the variation pattern determination table determined by the winning variation mode determination is read.
Then, the variation pattern number (type of variation pattern) is determined based on the variation pattern random number included in the game information stored in the storage area 0 and the read variation pattern determination table.

In step S11-12, a variation pattern command setting process is executed, and the process proceeds to step S11-13. In the variation pattern command setting process, a variation mode designation command specifying the variation mode number (type of variation mode) determined in step S11-11 is stored in the subcommand output request buffer.
Also, a variation pattern designation command designating the variation pattern number (type of variation pattern) determined in step S11-11 is stored in the subcommand output request buffer.
In step S11-13, a special figure fluctuation time setting process is executed, and the process proceeds to step S11-14. In the special figure fluctuation time setting process, the time for the special symbol fluctuation display is set.
Specifically, in the special figure fluctuation time setting process, first, the fluctuation time corresponding to the fluctuation mode number determined in step S11-11 (hereinafter referred to as "variation time 1") is acquired.
Also, the variation time corresponding to the variation pattern number determined in step S11-11 (hereinafter referred to as "variation time 2") is obtained.
Then, the total time of the acquired variable time 1 and variable time 2 is calculated, and the calculated total time is set in the special game timer.

In step S11-14, a special figure variation display data setting process is executed, and the process proceeds to step S11-15. In the special figure fluctuation display data setting process, data for controlling the fluctuation display of the special figure display device is set.
Specifically, in the special figure fluctuation display data setting process, first, a predetermined display time is set to the special figure display timer.
Next, when the special symbol discrimination flag setting value = "0", a predetermined initial value is set to the special figure 1 display symbol counter. With this, lighting control of the segment corresponding to the value of the special figure 1 display symbol counter is performed among the predetermined number of segments that constitute the special figure 1 display device.
On the other hand, when the special symbol discrimination flag set value = "1", a predetermined initial value is set to the special figure 2 display symbol counter. By this, lighting control of the segment corresponding to the value of the special figure 2 display pattern counter is performed among the predetermined number of segments constituting the special figure 2 display device.

In step S11-15, a special game phase update process is executed, a series of processes is completed, and the process proceeds to the next process (step S4-14). In the special game phase update process, in the special game phase flag area of the RAM 230, a value corresponding to the "special figure fluctuating state" is set.
In step S11-16, a customer waiting setting process is executed, a series of processes is completed, and the process proceeds to the next process (step S4-14). In the customer waiting setting process, the demonstration designation command is stored in the subcommand output request buffer of the RAM 230 .

(Processing during special figure fluctuation)
Next, the processing during special figure fluctuation executed in step S10-3 will be described.
FIG. 21 is a flowchart showing processing during special figure fluctuation.
When the special figure fluctuation process is executed in step S10-3, as shown in FIG. 21, the process first proceeds to step S12-1.
In step S12-1, it is determined whether or not the value of the special game timer is "0", and when it is determined that the value of the special game timer is not "0" (No), the process proceeds to step S12-2, and when the value of the special game timer is determined to be "0" (Yes), the process proceeds to step S12-4.
In step S12-2, it is determined whether or not the value of the special figure display timer is "0", and when it is determined that the value of the special figure display timer is "0" (Yes), the process proceeds to step S12-3, and when it is determined that the value of the special figure display timer is not "0" (No), a series of processes is terminated and the process proceeds to the next process (step S4-14).
In step S12-3, a special figure variation display data update process is executed, a series of processes is terminated, and the process proceeds to the next process (step S4-14). In the special figure fluctuation display data update process, the data for controlling the fluctuation display of the special figure display device is updated.
Specifically, in the special figure variation display data update process, when the variation display of the first special symbol is being executed, "1" is added to the value of the special figure 1 display symbol counter. On the other hand, when the variable display of the second special symbol is being executed, "1" is added to the value of the special figure 2 display symbol counter.

In step S12-4, a special figure stop display data setting process is executed, and the process proceeds to step S12-5. In the special figure stop display data setting process, data for controlling the stop display of the special figure display device is set.
Specifically, in the special figure stop display data setting process, the stop design number stored in the stop design number storage area of the RAM 230 is acquired.
Next, when the special symbol discrimination flag setting value = "0", the acquired stop symbol number (data corresponding to the stop symbol number) is set as the value of the special figure 1 display symbol counter. Thereby, lighting control (stop display) is performed for the segment corresponding to the set stop design number among the predetermined number of segments constituting the special figure 1 display device.
On the other hand, when the special symbol discrimination flag setting value = "1", the acquired stop symbol number (data corresponding to the stop symbol number) is set as the value of the special figure 2 display symbol counter. Thereby, lighting control (stop display) is performed for the segment corresponding to the set stop design number among the predetermined number of segments constituting the special figure 2 display device.

In step S12-5, a special figure stop time setting process is executed, and the process proceeds to step S12-6. In the special figure stop time setting process, a predetermined stop time is set in the special game timer.
In step S12-6, a stop designation command setting process is executed, and the process proceeds to step S12-7. In the stop designation command setting process, the stop designation command is stored in the subcommand output request buffer. Also, a predetermined number (1 [times] in the present embodiment) is added to the value of the external information fixed number counter.
In step S12-7, a special game phase update process is executed, a series of processes is terminated, and the process proceeds to the next process (step S4-14). In the special game phase update process, in the special game phase flag area of the RAM 230, a value corresponding to the "special figure stop symbol display state" is set.

(Processing during special stoppage)
Next, the special figure stopping process executed in step S10-3 will be described.
FIG. 22 is a flowchart showing processing during special figure stop.
When the special figure stopping process is executed in step S10-3, as shown in FIG. 22, the process first proceeds to step S13-1.
In step S13-1, it is determined whether or not the value of the special game timer is "0", and when it is determined that the value of the special game timer is "0" (Yes), the process proceeds to step S13-2, and when it is determined that the value of the special game timer is not "0" (No), a series of processes is terminated and the process proceeds to the next process (step S4-14).
In step S13-2, it is determined whether or not the type of the stopped design is a "big hit design", and if it is determined that the type of the stopped design is not a "big hit design" (No), the process proceeds to step S13-3, and if it is determined that the type of the stopped design is a "big hit design" (Yes), the process proceeds to step S13-6.
In step S13-3, it is determined whether or not the time reduction control is being executed, and if it is determined that the time reduction control is being executed (Yes), the process proceeds to step S13-4, and if it is determined that the time reduction control is not being performed (No), the process proceeds to step S13-5.
Here, when "1" is set in the time saving control flag area of the RAM 230, it is determined that the time saving control is being performed, and when "0" is set, it is determined that the time saving control is not being performed.

In step S13-4, a time saving control management process is executed, and the process proceeds to step S13-5. In the time saving control management process, it is determined whether or not to end the time saving control.
Specifically, in the time saving control management process, first, the value obtained by subtracting "1" from the value of the time saving counter is newly set as the value of the time saving counter.
Next, it is determined whether or not the value of the time saving counter is "0".
And when it determines with the value of a time saving counter being "0", "0" is set to the time saving control flag area|region of RAM230 (time saving control is stopped).
On the other hand, when it is determined that the value of the time saving counter is not "0", the state in which "1" is set in the time saving control flag area of the RAM 230 is maintained (the state in which the time saving control is being executed is maintained).
In step S13-5, a special game phase update process is executed, a series of processes is completed, and the process proceeds to the next process (step S4-14). In the special game phase update process, in the special game phase flag area of the RAM 230, a value corresponding to the "special figure variation waiting state" is set.
At step S13-6, game state update processing is executed, and the process proceeds to step S13-7. In the game state update process, the game state is updated.
Specifically, in the game state update process, "0" is set to the special figure high probability state flag area of the RAM230. Moreover, "0" is set to the time saving control flag area|region of RAM230.

In step S13-7, a special electric service control data setting process is executed, and the process proceeds to step S13-8. In the special electric role control data setting process, control data for controlling the opening and closing of the special electric role item 53a is set.
The ROM 220 stores a special electric role control table corresponding to each type of "jackpot symbol". In each special electric role control table, the effective time for closing the large winning opening, the closing time for the large winning opening, the number of round games, the number of opening/closing switching times corresponding to each round game, control data (solenoid control data, control time data) corresponding to each opening/closing switching, etc. are defined.
In the special electric role control data setting process, the special electric role control table corresponding to the type of "jackpot symbol" determined in step S11-8 is read, and the read special electric role control table is set in the special electric role control table area of the RAM 230.
Next, "0" is set in the counter for the number of times the special electric service has been continuously operated.

At step S13-8, an opening time setting process is executed, and the process proceeds to step S13-9. In the opening time setting process, the special electric role control table set in the special electric role control table area of the RAM 230 is referred to, and a predetermined opening time is set in the special game timer.
In step S13-9, an opening designation command setting process is executed, and the process proceeds to step S13-10. In the opening designation command setting process, the opening designation command designating the type of "jackpot pattern" determined in step S11-8 is stored in the subcommand output request buffer. Also, a predetermined number (1 [times] in this embodiment) is added to the value of the external information jackpot number counter.
In step S13-10, a special game phase update process is executed, a series of processes is terminated, and the process proceeds to the next process (step S4-14). In the special game phase update process, in the special game phase flag area of the RAM 230, a value corresponding to the "state before opening the big winning opening" is set.

(Pre-processing to open the big prize pool)
Next, the big winning opening pre-opening process executed in step S10-3 will be described.
FIG. 23 is a flow chart showing the pre-opening processing for the big winning opening.
When the big winning opening pre-opening process is executed in step S10-3, as shown in FIG. 23, the process first proceeds to step S14-1.
In step S14-1, it is determined whether or not the value of the special game timer is "0", and when it is determined that the value of the special game timer is "0" (Yes), the process proceeds to step S14-2, and when it is determined that the value of the special game timer is not "0" (No), a series of processes is terminated and the process proceeds to the next process (step S4-14).
In step S14-2, special electric service continuous operation number counter update processing is executed, and the process proceeds to step S14-3. In the special electric service continuous operation number counter update process, a value obtained by adding "1" to the value set in the special electric service continuous operation number counter is newly set in the special electric service continuous operation number counter.
In step S14-3, a round start specifying command setting process is executed, and the process proceeds to step S14-4. In the round start designation command setting process, the round start designation command is stored in the subcommand output request buffer.

In step S14-4, a process for setting the number of opening/closing switching times for special electric power is executed, and the process proceeds to step S14-5. In the special electric service opening/closing switching number setting process, the special electric service control table set in the special service control table area of the RAM 230 is referred to, and the opening/closing switching number corresponding to the value of the special service continuous operation counter is read. Then, the opening/closing switching frequency read out is set in the special electric service opening/closing switching frequency counter.
Next, "0" is set as the value of the special electric winning number counter.
In step S14-5, a special electric power opening/closing switching process is executed, and the process proceeds to step S14-6. The special electric service open/close switching process will be described later.
In step S14-6, a special game phase update process is executed, a series of processes is completed, and the process proceeds to the next process (step S4-14). In the special game phase update process, in the special game phase flag area of the RAM 230, a value corresponding to the "large winning opening opening control state" is set.

(Special electric service opening/closing switching processing)
Next, the special electric power opening/closing switching processing in steps S14-5 and S16-3 will be described.
FIG. 24 is a flow chart showing the special electric service open/close switching process.
When the special electric power opening/closing switching process is executed in steps S14-5 and S16-3, as shown in FIG. 24, the process first proceeds to step S15-1.
In step S15-1, it is determined whether or not the value of the opening/closing switching number counter for special electric power is "0". If it is determined that the value of the opening/closing switching number counter for special electric power is not "0" (No), the process proceeds to step S15-2.

In step S15-2, a special electric service control data setting process is executed, and the process proceeds to step S15-3. In the special electric role control data setting process, control data for controlling the special electric accessory 53a to be in an open state or a closed state is set.
Specifically, in the special electric role control data setting process, the special electric role control table set in the special electric role control table area of the RAM 230 is referred to, and the solenoid control data corresponding to the value of the special electric role switching number counter is read. Then, the read solenoid control data (control data specifying energization or energization stop) is set in a predetermined area of the RAM 230 . As a result, the control of the special electric accessory solenoid 65 based on the set solenoid data is started, and the special electric accessory 53a is controlled to the open state or the closed state.

In step S15-3, a special electric service control time setting process is executed, and the process proceeds to step S15-4. In the special electric service control time setting process, a control time for continuing control based on the solenoid control data set in step S15-2 is set.
Specifically, in the special electric service control time setting process, the special electric service control table set in the special service control table area of the RAM 230 is referred to, and the control time corresponding to the value of the special service switching number counter is read. Then, the read control time is set to the special game timer.
In step S15-4, a special electric power opening/closing switching frequency counter update process is executed, a series of processes is completed, and the process proceeds to the next process (step S14-6 or S16-4). In the special electric service opening/closing switching number counter update process, a value obtained by subtracting "1" from the value set in the special electric service opening/closing switching number counter is newly set in the special electric service opening/closing switching number counter.

(Grand prize opening control process)
Next, the big winning opening opening control process executed in step S10-3 will be described.
FIG. 25 is a flowchart showing the big winning opening opening control process.
When the big winning hole opening control process is executed in step S10-3, as shown in FIG. 25, the process first proceeds to step S16-1.
In step S16-1, it is determined whether or not the value of the special game timer is "0", and when it is determined that the value of the special game timer is "0" (Yes), the process proceeds to step S16-2, and when it is determined that the value of the special game timer is not "0" (No), the process proceeds to step S16-4.
In step S16-2, it is determined whether or not the value of the opening/closing switching number counter for special electric power is "0". If it is determined that the value of the opening/closing switching number counter for special electric power is not "0" (No), the process proceeds to step S16-3.
In step S16-3, a special electric power opening/closing switching process (see FIG. 24) is executed, and the process proceeds to step S16-4.
In step S16-4, it is determined whether or not the value of the special electric role winning number counter has reached a predetermined upper limit value (10 [balls] in this embodiment). If it is determined that the value of the special electric role winning number counter has reached the predetermined upper limit value (Yes), the process proceeds to step S16-5. 4).

In step S16-5, a special winning opening control end process is executed, and the process proceeds to step S16-6. In the big winning opening opening control end process, solenoid control data specifying de-energization is set in a predetermined area of the RAM 230 . As a result, the special electric accessory 53a is controlled to the closed state.
In step S16-6, a special winning opening closing effective time setting process is executed, and the process proceeds to step S16-7. In the large winning opening closing effective time setting process, a special electric role control table set in a special electric role control table area of the RAM 230 is referred to, and a predetermined large winning opening closing valid time (interval time) is set in a special game timer.
In step S16-7, a round end designation command setting process is executed, and the process proceeds to step S16-8. In the round end designation command setting process, the round end designation command is stored in the subcommand output request buffer.
In step S16-8, a special game phase update process is executed, a series of processes is terminated, and the process proceeds to the next process (step S4-14). In the special game phase update process, in the special game phase flag area of the RAM 230, a value corresponding to the "large winning opening closed valid state" is set.

(Large winning mouth closing effective processing)
Next, a description will be given of the big winning opening closing valid process executed in step S10-3.
FIG. 26 is a flow chart showing the big winning opening closing effective process.
When the big winning opening closing effective process is executed in step S10-3, as shown in FIG. 26, the process first proceeds to step S17-1.
In step S17-1, it is determined whether or not the value of the special game timer is "0", and when it is determined that the value of the special game timer is "0" (Yes), the process proceeds to step S17-2, and when it is determined that the value of the special game timer is not "0" (No), a series of processes is terminated and the process proceeds to the next process (step S4-14).

In step S17-2, it is determined whether or not the value of the special electric service continuous operation number counter has reached the specified value. If it is determined that the value of the special electric service continuous operation number counter has not reached the specified value (No), the process proceeds to step S17-3, and if it is determined that the value of the special electric service continuous operation number counter has reached the specified value (Yes), the process proceeds to step S17-5.
Here, the special electric role control table set in the special electric role control table area of the RAM 230 is referred to, and the number of round games defined in the special electric role control table is obtained as a specified value for determination.
In step S17-3, a big winning opening closing time setting process is executed, and the process proceeds to step S17-4. In the big winning opening closing time setting process, the special electric role control table set in the special electric role control table area of the RAM 230 is referred to, and a predetermined big winning opening closing time is set in the special game timer.
In step S17-4, a special game phase update process is executed, a series of processes is completed, and the process proceeds to the next process (step S4-14). In the special game phase update process, in the special game phase flag area of the RAM 230, a value corresponding to the "state before opening the big winning opening" is set.

In step S17-5, ending time setting processing is executed, and the process proceeds to step S17-6. In the ending time setting process, the special electric role control table set in the special electric role control table area of the RAM 230 is referred to, and a predetermined ending time is set in the special game timer.
In step S17-6, an ending designation command setting process is executed, and the process proceeds to step S17-7. In the ending specifying command setting process, the ending specifying command is stored in the subcommand output request buffer.
In step S17-7, a special game phase update process is executed, a series of processes is terminated, and the process proceeds to the next process (step S4-14). In the special game phase update process, in the special game phase flag area of the RAM 230, a value corresponding to the "big winning opening opening end wait state" is set.

(Wait processing for end of big winning opening opening)
Next, the wait process for ending the opening of the big winning opening executed in step S10-3 will be described.
FIG. 27 is a flow chart showing the waiting process for ending the opening of the big winning opening.
When the big winning opening end wait process is executed in step S10-3, as shown in FIG. 27, the process first proceeds to step S18-1.
In step S18-1, it is determined whether or not the value of the special game timer is "0", and when it is determined that the value of the special game timer is "0" (Yes), the process proceeds to step S18-2, and when it is determined that the value of the special game timer is not "0" (No), a series of processes is terminated and the process proceeds to the next process (step S4-14).

At step S18-2, game state setting processing is executed, and the process proceeds to step S18-3. In the game state setting process, the game state is set.
Specifically, in the game state setting process, the value of the special figure high probability state flag of the RAM 230 is set according to the type of the stop symbol (jackpot symbol).
At this time, when the type of the stopped symbol is "1 big win" or "3 big wins" to "5 big wins", "1" is set in the special-symbol high-probability state flag area of the RAM230. On the other hand, when the type of the stopped symbol is "big hit 2 symbols" or "big hit 6 symbols", "0" is set in the special symbol high probability state flag area of the RAM230.
Next, a predetermined number of times of time saving is set in the time saving counter. At this time, when the type of the stop symbol is "big hit 2 symbols" or "big hit 6 symbols", 100 [times] is set as the predetermined number of times of time saving. On the other hand, when the type of the stop symbol is "big hit 1 symbol" or "big hit 3 symbols" to "big hit 5 symbols", 10000 [times] is set as the predetermined number of times of time saving. Moreover, "1" is set to the time saving control flag area|region of RAM230.
Next, a value corresponding to the type of the big-hit symbol is set in the last-time big-hit symbol flag area of the RAM 230 .
In step S18-3, a special game phase update process is executed, a series of processes is completed, and the process proceeds to the next process (step S4-14). In the special game phase update process, in the special game phase flag area of the RAM 230, a value corresponding to the "special figure variation waiting state" is set.

(Normal game management processing)
Next, the normal game management process of step S4-14 will be explained.
FIG. 28 is a flow chart showing normal game management processing.
Here, in the present embodiment, seven phases and stages (hereinafter referred to as "normal game phases") of the game (hereinafter referred to as "normal game") executed based on the normal symbol lottery are defined as "normal figure fluctuation waiting state", "normal figure fluctuation state", "normal figure stop symbol display state", "normal figure electric role object open state before opening", "normal figure electric role object open control state", "normal figure electric role object closing valid state" and "normal figure electric role object open end wait state". are
Then, in the normal game phase flag area of the RAM 230, a value (normal game phase flag) corresponding to one of the seven normal game phases is set.
Also, the ROM 220 stores a normal game control module corresponding to each normal game phase as a normal game control module (program) for controlling (executing) the normal game.
Then, in the normal game management process, the normal game control module corresponding to the value set in the normal game phase flag area of the RAM 230 is selected, and the process based on the selected normal game control module is executed.

Specifically, when the normal game management process is executed in step S4-14, as shown in FIG. 28, the process first proceeds to step S19-1.
In step S19-1, normal game phase acquisition processing is executed, and the process proceeds to step S19-2. In the normal game phase acquisition process, the value (normal game phase) set in the normal game phase flag area of the RAM 230 is acquired (loaded).
In step S19-2, normal game control module acquisition processing is executed, and the process proceeds to step S19-3. In the normal game control module acquisition process, the normal game control module corresponding to the value (normal game phase) acquired in step S19-1 is read.

In step S19-3, a normal game control module execution process is executed, a series of processes is completed, and the process proceeds to the next process (step S4-15). In the normal game control module execution process, the process based on the normal game control module read in step S19-2 is started.
Specifically, if the value acquired in step S19-1 is a value corresponding to the "normal pattern fluctuation waiting state", the normal pattern fluctuation waiting process described later is started, and if the value corresponds to the "normal pattern fluctuation state", the normal pattern fluctuation process that will be described later is started, and if the value corresponds to the "normal pattern stop symbol display state", the normal pattern stop processing that will be described later is started. If the value corresponds to the "normal electric role product open control state", the normal electric role product opening control process described later is started, and if the value corresponds to the "normal electric role product closed valid state", the normal electric role product closing effective process described later is started, and if the value corresponds to the "normal electric role product open end wait state", the normal electric role product open end wait process described later is started.

(Normal pattern change waiting process)
Next, the general pattern fluctuation waiting process executed in step S19-3 will be described.
FIG. 29 is a flowchart showing normal pattern change waiting processing.
When normal figure fluctuation waiting processing is executed in step S19-3, as shown in FIG. 29, the process first proceeds to step S20-1.
In step S20-1, it is determined whether the value of the normal pattern reservation number counter is "1" or more, and if it is determined that the value of the normal pattern reservation number counter is "1" or more (Yes), the process proceeds to step S20-2.

In step S20-2, normal figure pending number update processing is executed, and the process proceeds to step S20-3. In the general pattern reservation number update process, the general pattern reservation number is updated.
Concretely, in the general pattern reservation number update process, first, "1" is subtracted from the value of the general pattern reservation number counter.
Next, shift the storage area where the normal game information is stored. Concretely, the storage contents of the storage area 1 of the normal game information storage area are shifted (moved) to the storage area 0. Next, the storage contents of the storage area 2 of the general-purpose game information storage area are shifted to the storage area 1 of the general-purpose game information storage area. Next, the storage contents of the storage area 3 of the general-purpose game information storage area are shifted to the storage area 2 of the general-purpose game information storage area. Next, the storage contents of the storage area 4 of the general-purpose game information storage area are shifted to the storage area 3 of the general-purpose game information storage area. Next, clear (initialize) the storage contents of the storage area 4 of the normal game information storage area.

In step S20-3, normal figure hit-lose determination processing is executed, and the process proceeds to step S20-4. In the normal pattern lottery determination process, the result of the normal pattern lottery is determined (normal pattern hit/loss determination).
The ROM 220 stores a normal symbol lottery table in which the winning values of the normal symbol lottery are registered. In addition, as the normal figure win-lose lottery table, the normal figure win-lose lottery table corresponding to the execution of the time saving control and the normal figure win-lose lottery table corresponding to the stop of the time saving control are stored.
In the normal figure winning lottery table corresponding to the stop of the time saving control, the winning value is registered so that the winning probability is the first probability (1/99 in this embodiment). On the other hand, in the normal figure winning/losing lottery table corresponding to the execution of the time saving control, the winning value is registered so that the winning probability becomes a second probability (1/1 in this embodiment) higher than the first probability.
In the normal game win-lose determination processing, the normal game win-lose determination is executed based on the win random number included in the game information stored in the storage area 0 and the normal game win-lose lottery table corresponding to the current execution status (during execution or suspension) of the time saving control.
Specifically, when the value of the winning random number included in the game information stored in the storage area 0 matches the winning value, the result of the normal symbol lottery is determined as "winning" (winning).
On the other hand, when the value of the winning random number included in the game information stored in the storage area 0 does not match the winning value, the result of the normal symbol lottery is determined as "loss" (loss).

In step S20-4, normal pattern stop symbol determination processing is executed, and the process proceeds to step S20-5. In the normal pattern stop symbol determination process, the type of the normal pattern stop symbol (stop symbol number) is determined (normal pattern stop symbol determination).
Specifically, in the normal pattern stop pattern determination process, when it is determined as ``hit'' (winning) by the normal pattern win-lose determination, the ``normal pattern winning pattern'' is determined as the type of the stop pattern (stop pattern number).
On the other hand, when it is determined to be "lost" (lost) by the normal figure winning/losing determination, "missing symbol" is determined as the type of stop symbol (stop symbol number).
Next, the determined stop symbol type (stop symbol number) is stored in the stop symbol storage area of the RAM 230 .
In step S20-5, normal figure fluctuation pattern determination processing is executed, and the process proceeds to step S20-6. In the general pattern variation pattern determination process, the type of variation pattern (variation pattern number) in the normal pattern is determined (normal pattern variation pattern determination).
Specifically, in the normal figure fluctuation pattern determination process, when the time saving control is stopped, the first type (in the present embodiment, 2.0 [s] The type corresponding to the fluctuation time) is determined as the type (variation pattern number) of the normal figure fluctuation pattern.
On the other hand, when the time saving control is being executed, the second type (in the present embodiment, the type corresponding to the fluctuation time of 0.5 [s]) is determined as the type of normal figure fluctuation pattern (variation pattern number).

In step S20-6, normal figure fluctuation time setting processing is executed, and the process proceeds to step S20-7. In the general pattern fluctuation time setting process, the fluctuation time corresponding to the type of general pattern fluctuation pattern (variation pattern number) determined in step S20-6 is obtained. And, the acquired fluctuation time is set to the normal game timer.
In step S20-7, normal figure fluctuation display data setting processing is executed, and the process proceeds to step S20-8. In the general pattern fluctuation display data setting process, data for controlling the fluctuation display of the general pattern display device is set.
Specifically, in the normal pattern fluctuation display data setting process, first, a predetermined display time is set in the normal pattern display timer.
Next, a predetermined initial value is set in the general pattern display symbol counter. As a result, the segment corresponding to the value of the normal pattern display symbol counter among the predetermined number of segments constituting the normal pattern display device is controlled to be lit.
Next, predetermined segment data is set as segment data corresponding to the normal map display device. As a result, lighting of the segment corresponding to the set segment data is controlled among the predetermined number of segments that constitute the normal map display device.
In step S20-8, normal game phase update processing is executed, a series of processing ends, and the next processing (step S4-15) is performed. In the normal game phase update process, in the normal game phase flag area of the RAM 230, a value corresponding to the "normal figure fluctuating state" is set.

(Normal map fluctuation process)
Next, the process during normal figure fluctuation executed in step S19-3 will be described.
FIG. 30 is a flow chart showing processing during normal pattern fluctuation.
When the normal figure fluctuation process is executed in step S19-3, as shown in FIG. 30, first, the process proceeds to step S21-1.
In step S21-1, it is determined whether or not the value of the normal game timer is "0", and when it is determined that the value of the normal game timer is not "0" (No), the process proceeds to step S21-2, and when the value of the normal game timer is determined to be "0" (Yes), the process proceeds to step S21-4.
In step S21-2, it is determined whether the value of the normal diagram display timer is "0", and if it is determined that the value of the normal diagram display timer is "0" (Yes), the process proceeds to step S21-3.
In step S21-3, normal figure fluctuation display data update processing is executed, a series of processing is completed, and the next processing (step S4-15) is performed. In the normal map fluctuation display data update process, the data for controlling the variable display of the normal map display device is updated.
Specifically, in the general pattern fluctuation display data update process, "1" is added to the value of the general pattern display symbol counter.

In step S21-4, a normal map stop display data setting process is executed, and the process proceeds to step S21-5. In the normal map stop display data setting process, data for controlling the stop display of the normal map display device is set.
Specifically, in the general pattern stop display data setting process, the stop pattern number stored in the stop pattern storage area of the RAM 230 is acquired.
Next, the acquired stop design number is set as the value of the general-purpose diagram display design counter. As a result, of the predetermined number of segments that constitute the normal-symbol display device, the segment corresponding to the value of the normal-symbol display symbol counter is controlled to light up (stopped display).
In step S21-5, normal figure stop time setting processing is executed, and the process proceeds to step S21-6. In the normal figure stop time setting process, the predetermined stop time is set to the normal game timer.
In step S21-6, normal game phase update processing is executed, a series of processing ends, and the next processing (step S4-15) is performed. In the ordinary game phase update process, in the ordinary game phase flag area of the RAM 230, a value corresponding to the "normal figure stop symbol display state" is set.

(Normal map stop processing)
Next, the process during normal figure stop executed in step S19-3 will be described.
FIG. 31 is a flow chart showing processing during normal map stoppage.
When the normal map stop process is executed in step S19-3, as shown in FIG. 31, the process first proceeds to step S22-1.
In step S22-1, it is determined whether or not the value of the normal game timer is "0", and when it is determined that the value of the normal game timer is "0" (Yes), the process proceeds to step S22-2, and when it is determined that the value of the normal game timer is not "0" (No), a series of processes is terminated and the process proceeds to the next process (step S4-15).
In step S22-2, it is determined whether or not the stopped pattern is a ``normal pattern per pattern'', and when it is determined that the stopped pattern is not a ``normal per pattern'' (No), the process proceeds to step S22-3, and when it is determined that the stopped pattern is a ``normal per pattern'' (Yes), the process proceeds to step S22-4.
In step S22-3, normal game phase update processing is executed, a series of processing ends, and the next processing (step S4-15) is performed. In the normal game phase update process, in the normal game phase flag area of the RAM 230, a value corresponding to the "normal figure fluctuation waiting state" is set.
In step S22-4, normal electric service control data setting processing is executed, and the process proceeds to step S22-5. In the ordinary electric role control data setting process, control data for opening and closing the ordinary electric accessory 52a is set.
The ROM 220 stores a normal electric work control table corresponding to the execution status of the time saving control (during execution or during suspension). Each ordinary electric service control table defines the time before opening the ordinary electric service, the effective time for closing the ordinary electric service, the waiting time for the completion of opening, the number of open/close switching times, control data (solenoid control data, control time data) corresponding to each open/close switching, and the like.
In the normal electric service control data setting process, the normal electric service control table corresponding to the execution status (executing or stopped) of the time saving control is read, and the read normal electric service control table is set in the ordinary electric service control table area of the RAM 230.
Next, referring to the ordinary electric work control table set in the ordinary electric work control table area of the RAM 230, the opening/closing switching times are read out. Then, the number of open/close switching times read out is set in the normal electric open/close switching number counter. In addition, "0" is set as the value of the winning number counter for the normal electric role.

At step S22-5, a normal electric service pre-opening time setting process is executed, and the process proceeds to step S22-6. In the ordinary electric role opening time setting process, the ordinary electric role control table set in the ordinary electric role control table area of the RAM 230 is referred to, and a predetermined ordinary electric role opening time before the normal electric role opening is set in the ordinary game timer.
In step S22-6, normal game phase update processing is executed, a series of processing ends, and the next processing (step S4-15) is performed. In the normal game phase update process, in the normal game phase flag area of the RAM 230, a value corresponding to the "normal electric accessary product opening pre-state" is set.

(Normal electric accessory opening preprocessing)
Next, the normal electric accessary product opening preprocessing executed in step S19-3 will be described.
FIG. 32 is a flowchart showing normal electric accessory opening preprocessing.
When the normal electric accessory opening preprocessing is executed in step S19-3, as shown in FIG. 32, the process first proceeds to step S23-1.
In step S23-1, it is determined whether or not the value of the normal game timer is "0", and when it is determined that the value of the normal game timer is "0" (Yes), the process proceeds to step S23-2, and when it is determined that the value of the normal game timer is not "0" (No), a series of processes is terminated and the process proceeds to the next process (step S4-15).
In step S23-2, normal electric open/close switching processing is executed, and the process proceeds to step S23-3. The ordinary electric open/close switching process will be described later.
In step S23-3, normal game phase update processing is executed, a series of processing ends, and the next processing (step S4-15) is performed. In the normal game phase update process, in the normal game phase flag area of the RAM 230, a value corresponding to the "normal electric accessary product opening control state" is set.

(Normal electrical open/close switching process)
Next, the normal electric open/close switching process in steps S23-2 and S25-3 will be described.
FIG. 33 is a flow chart showing normal electric open/close switching processing.
When the ordinary electric open/close switching process is executed in steps S23-2 and S25-3, as shown in FIG. 33, the process first proceeds to step S24-1.
In step S24-1, it is determined whether or not the value of the open/close switching number counter of the normal electric power supply is "0". If it is determined that the value of the open/close switching number counter of the normal electric power supply is not "0" (No), the process proceeds to step S24-2.
In step S24-2, normal electric service control data setting processing is executed, and the process proceeds to step S24-3. In the normal electric role control data setting process, control data for controlling the normal electric accessory 52a to be in an open state or a closed state is set.
Specifically, in the normal electric power control data setting process, the normal electric power control table set in the normal electric power control table area of the RAM 230 is referred to, and the solenoid control data corresponding to the value of the normal electric power open/close switching frequency counter is read. Then, the read solenoid control data (control data specifying energization or energization stop) is set in a predetermined area of the RAM 230 . As a result, control of the normal electric accessory solenoid 64 based on the set solenoid data is started, and the normal electric accessory 52a is controlled to the open state or the closed state.

In step S24-3, normal electric service control time setting processing is executed, and the process proceeds to step S24-4. In the normal electric power control time setting process, a control time for continuing control based on the solenoid control data set in step S24-2 is set.
Specifically, in the normal electric service control time setting process, the normal electric service control table set in the normal service control table area of the RAM 230 is referred to, and the control time corresponding to the value of the normal service switching frequency counter is read. Then, the read control time is set to the normal game timer.
In step S24-4, normal electric switch open/close switching frequency counter update processing is executed, a series of processing ends, and the next processing (step S23-3 or S25-4) is performed. In the normal electric switch opening/closing number counter update process, a value obtained by subtracting "1" from the value set in the normal electric switch opening/closing number counter is newly set in the normal electric opening/closing switching number counter.

(Normal electric accessory opening control process)
Next, the normal electric accessory opening control process executed in step S19-3 will be described.
FIG. 34 is a flowchart showing normal electric accessory opening control processing.
When the ordinary electric accessary product opening control process is executed in step S19-3, as shown in FIG. 34, the process first proceeds to step S25-1.
In step S25-1, it is determined whether or not the value of the normal game timer is "0", and when it is determined that the value of the normal game timer is "0" (Yes), the process proceeds to step S25-2, and when it is determined that the value of the normal game timer is not "0" (No), the process proceeds to step S25-4.
In step S25-2, it is determined whether or not the value of the open/close switching frequency counter for normal electric power is "0". If it is determined that the value of the open/close switching frequency counter for normal electric power is not "0" (No), the process proceeds to step S25-3, and if it is determined that the value of the open/close switching frequency counter for normal power is "0" (Yes), the process proceeds to step S25-5.
In step S25-3, normal electric open/close switching processing (see FIG. 33) is executed, and the process proceeds to step S25-4.
In step S25-4, it is determined whether or not the value of the normal electric winning number counter has reached a predetermined upper limit value (3 [ball] in this embodiment). If it is determined that the normal electric winning winning number counter value has reached the predetermined upper limit value (Yes), the process proceeds to step S25-5. ).

In step S25-5, normal electric power opening control end processing is executed, and the process proceeds to step S25-6. In the normal electric power opening control end process, solenoid control data designating de-energization is set in a predetermined area of the RAM 230 . As a result, the normal electric accessory 52a is controlled to the closed state.
In step S25-6, normal electric service closing effective time setting processing is executed, and the process proceeds to step S25-7. In the ordinary electric role closing effective time setting process, the normal electric role closing valid time is set in the ordinary game timer by referring to the ordinary electric role control table set in the ordinary electric role control table area of the RAM 230 .
In step S25-7, normal game phase update processing is executed, a series of processing ends, and the next processing (step S4-15) is performed. In the normal game phase update process, in the normal game phase flag area of the RAM 230, a value corresponding to the "normal electric accessary product closed valid state" is set.

(Normal electric accessories closing effective processing)
Next, the normal electric accessary product closing valid process executed in step S19-3 will be described.
FIG. 35 is a flowchart showing normal electric accessary product closing valid processing.
When the normal electric accessary product closing valid process is executed in step S19-3, as shown in FIG. 35, the process first proceeds to step S26-1.
In step S26-1, it is determined whether or not the value of the normal game timer is "0", and when it is determined that the value of the normal game timer is "0" (Yes), the process proceeds to step S26-2, and when it is determined that the value of the normal game timer is not "0" (No), a series of processes is terminated and the process proceeds to the next process (step S4-15).
In step S26-2, an opening end wait time setting process is executed, and the process proceeds to step S26-3. In the open end wait time setting process, the normal electric role control table set in the normal electric role control table area of the RAM 230 is referred to, and a predetermined open end wait time is set in the normal game timer.
In step S26-3, normal game phase update processing is executed, a series of processing ends, and the next processing (step S4-15) is performed. In the normal game phase update process, in the normal game phase flag area of the RAM 230, a value corresponding to the "normal electric accessary product open end wait state" is set.

(Normal electric accessory opening end wait process)
Next, the normal electric accessary product opening end wait process executed in step S19-3 will be described.
FIG. 36 is a flowchart showing normal electric accessary product opening end wait processing.
When the normal electric accessary product open end wait process is executed in step S19-3, as shown in FIG. 36, the process first proceeds to step S27-1.
In step S27-1, it is determined whether or not the value of the normal game timer is "0", and when it is determined that the value of the normal game timer is "0" (Yes), the process proceeds to step S27-2, and when it is determined that the value of the normal game timer is not "0" (No), a series of processes is terminated and the process proceeds to the next process (step S4-15).
In step S27-2, normal game phase update processing is executed, a series of processing ends, and the next processing (step S4-15) is performed. In the normal game phase update process, in the normal game phase flag area of the RAM 230, a value corresponding to the "normal figure fluctuation waiting state" is set.

(Performance display device control processing)
Next, the performance display device control process at step S4-25 will be described.
FIG. 37 is a flowchart showing performance display device control processing.
The performance display device control processing is processing based on a program for controlling the display of the performance display device 206 . That is, the performance display device control processing is processing based on a program stored in the non-use area m2 (program area) of the ROM 220 . Performance display device control processing is called during execution of timer interrupt processing.
When the performance display device control process is called in step S4-25, as shown in FIG. 37, the process proceeds to step S38-1.
In step S38-1, register save processing is executed, and the process proceeds to step S38-2. In the register saving process, the values of all the registers used during execution of the process based on the program stored in the use area m1 are saved to the saving area of the RAM. Also, the values of all stack pointers used during the execution of the process based on the program stored in the use area m1 are saved in the save area of the RAM.

In step S38-2, it is determined whether or not a playable state has occurred (set), and if it is determined that a playable state has occurred (Yes), the process proceeds to step S38-3, and if it is determined that the gameable state has not occurred (No), the process proceeds to step S38-11.
Here, based on the value (gaming machine status flag) stored in the gaming machine status flag area of the RAM 230, it is determined whether or not the game ready status has occurred. At this time, when the value stored in the game machine state flag area is a value corresponding to the game possible state, it is determined that the game possible state is generated, and when it is not a value corresponding to the game possible state, it is determined that the game possible state is not generated.
In step S38-3, total out counter addition processing is executed, and the process proceeds to step S38-4.
In the total count counter addition process, it is determined whether or not the ON state of the OUT switch 109 has been detected. Then, when it is determined that the ON state of the out switch 109 is detected, "1" is added to the value of the total out counter. On the other hand, if it is determined that the ON state of the out switch 109 has not been detected, the value of the total out counter is not added.

In step S38-4, it is determined whether or not the predetermined game state is established, and if it is determined that the predetermined game state is established (Yes), the process proceeds to step S38-5, and if it is determined that the game state is not the predetermined game state (No), the process proceeds to step S38-7.
Here, the ``predetermined game state'' is a game state in which a ``special figure low probability state'' is occurring, time reduction control is being stopped, and a jackpot game state is not occurring.
At step S38-5, normal out counter addition processing is executed, and the process proceeds to step S38-6.
In the normal out counter addition process, it is determined whether or not the ON state of the out switch 109 has been detected. When it is determined that the ON state of the OUT switch 109 is detected, "1" is added to the value of the normal OUT counter. On the other hand, if it is determined that the ON state of the OUT switch 109 has not been detected, the value of the normal OUT counter is not added.

In step S38-6, normal prize ball counter addition processing is executed, and the process proceeds to step S38-7.
In the normal prize ball counter addition process, first, it is determined whether or not the ON state of the special figure 1 starting port switch 101 is detected. When it is determined that the ON state of the special figure 1 starting port switch 101 is detected, ``3'', which is the number of prize balls put out according to the entry of game balls into the first starting port 51, is added to the value of the normal prize ball counter. On the other hand, when it is determined that the ON state of the special figure 1 starting port switch 101 is not detected, the value of the normal ball counter is not added.
Next, it is determined whether or not the ON state of the special figure 2 starting port switch 102 is detected. When it is determined that the ON state of the special figure 2 starting port switch 102 is detected, "1", which is the number of prize balls put out according to the entry of game balls into the second starting port 52, is added to the value of the normal prize ball counter. On the other hand, when it is determined that the ON state of the special figure 2 starting port switch 102 is not detected, the value of the normal ball counter is not added.
Next, it is determined whether or not the ON state of the right winning opening switch 105 is detected. When it is determined that the ON state of the right winning hole switch 105 is detected, "10", which is the number of winning balls put out according to the entry of game balls into the right other winning hole 54, is added to the value of the normal winning ball counter. On the other hand, when it is determined that the ON state of the right winning hole switch 105 is not detected, the value of the normal winning ball counter is not added.
Next, it is determined whether or not the ON state of the left winning port switch 106 is detected. When it is determined that the ON state of the left winning hole switch 106 is detected, '10', which is the number of winning balls put out according to the entry of the game balls into the other left winning holes 55 to 57, is added to the value of the normal winning ball counter. On the other hand, when it is determined that the ON state of the left winning hole switch 106 is not detected, the value of the normal winning ball counter is not added.

In step S38-7, it is determined whether or not the value of the total out counter has reached the reference value, and if it is determined that the value of the total out counter has reached the reference value (Yes), the process proceeds to step S38-8, and if it is determined that the value of the total out counter has not reached the standard value (No), the process proceeds to step S38-9.
In this embodiment, the reference value=60000×n (n=integer). "n" is a value indicating the current section, and is set to "1" as an initial value.
In step S38-8, section update processing is executed, and the process proceeds to step S38-9. In the section update process, the section is updated.
In the section update process, first, the base ratio stored in the base value buffer 1 of the RAM 230 is shifted (moved) to the base value buffer 2 of the RAM 230 .
Next, a predetermined initial value ("0" in this embodiment) is set as the value of the normal out counter. Also, a predetermined initial value (“0” in this embodiment) is set as the value of the normal winning ball counter.
Next, "1" is added to the value (n) indicating the current interval. This updates the reference value.
At step S38-9, a base ratio calculation process is executed, and the process proceeds to step S38-10. In the base ratio calculation process, a base ratio is calculated.
Specifically, in the base ratio calculation process, the base ratio is calculated based on the value of the normal out counter and the value of the normal ball counter. Then, the calculated base ratio is stored in the base value buffer 1 of the RAM 230 .
Here, the base ratio is the ratio of the value of the normal winning ball counter to the value of the normal out counter.

At step S38-10, a base ratio display data setting process is executed, and the process proceeds to step S38-11. In the base ratio display data setting process, display data to be output to the performance display device 206 is set.
The RAM 230 is provided with an identification segment output request buffer (16 bits) and a ratio segment output request buffer (16 bits).
In the base ratio display data setting process, first, which base ratio to display is selected from the base ratio of the current section and the base ratio of the previous section.
When the display of the base ratio of the current section is selected, information indicating the base ratio of the current section is set in the identification segment output request buffer, and information indicating the base ratio of the current section is set in the ratio segment output request buffer.
Specifically, the display data of "b" (8 bits) is set in the upper 8 bits of the identification segment output request buffer, the display data of "b" (8 bits) is set in the lower 8 bits of the identification segment output request buffer, the display data corresponding to the tens digit of the base ratio stored in the base value buffer 1 is set to the upper 8 bits of the ratio segment output request buffer, and the display data corresponding to the base ratio stored in the base value buffer 1 is set to the lower 8 bits of the ratio segment output request buffer. do.
As a result, among the light-emitting elements constituting the performance display device 206, the character "b" is displayed by the LEDs 33 to 40, the character "b" is displayed by the LEDs 41 to 48, the number indicating the tens digit of the current base ratio is displayed by the LEDs 49 to 56, and the number indicating the ones digit of the current base ratio is displayed by the LEDs 57 to 64.

On the other hand, when display of the base ratio of the previous section is selected, information indicating the base ratio of the previous section is set in the identification segment output request buffer, and information indicating the base ratio of the previous section is set in the ratio segment output request buffer.
Specifically, the display data of "b" (8 bits) is set in the upper 8 bits of the identification segment output request buffer, the display data of "c" (8 bits) is set in the lower 8 bits of the identification segment output request buffer, the display data corresponding to the tens digit of the base ratio stored in the base value buffer 2 is set to the upper 8 bits of the ratio segment output request buffer, and the display data corresponding to the base ratio stored in the base value buffer 2 is set to the lower 8 bits of the ratio segment output request buffer. do.
As a result, among the light-emitting elements constituting the performance display device 206, LEDs 33 to 40 display the letter "b", LEDs 41 to 48 display the letter "c", LEDs 49 to 56 display the tens digit of the current base ratio, and LEDs 57 to 64 display the digits indicating the ones digit of the current base ratio.

In step S38-11, register restoration processing is executed, and the process proceeds to step S38-12. In the register restoration process, the value of the register saved in step S38-1 (the value of the register used during the execution of the process based on the program stored in the use area m1) and the value of the stack pointer saved in step S38-1 (the value of the stack pointer used during the execution of the process based on the program stored in the use area m1) are restored.
At step S38-12, an interrupt permission process is executed, a series of processes is completed, and the process proceeds to the next process (step S4-26). In the interrupt permission processing, the interrupt disabled state is canceled. As a result, execution of save processing at power-off, timer interrupt processing, and the like is permitted.

(Various productions executed in pachinko machine 1)
Next, various effects executed in the pachinko machine 1 will be described.

(holding performance)
First, the suspension effect (suspension display) executed in the pachinko machine 1 will be described.
In the pachinko machine 1, each game information (special figure 1 game information or special figure 2 game information) stored in the game information storage area (special figure 1 game information storage area and special figure 2 game information storage area) is executed.
The pending performance is a performance that suggests (informs) that the notification display (start determination) of the special symbol based on the game information targeted for the suspension performance (hereinafter referred to as "game information subject to suspension performance") is suspended, or that the notification display of the special symbol based on the game information subject to the suspension performance is being executed.
In the pending effect, the pending symbol h corresponding to the pending effect target game information is displayed in the pending symbol display areas b1 to b3.

Specifically, in the reserved design display area b2, as a display position (display unit) where the reserved design h is displayed, four storage areas (storage area 1 to storage area 4) of the special figure 1 game information storage area Display positions corresponding to each are defined.
In addition, in the reserved design display area b3, as a display position (display unit) where the reserved design h is displayed, four storage areas (storage area 1 to storage area 4) of the special figure 2 game information storage area Display positions corresponding to each are defined.
Then, in the pending effect in which the special figure 1 game information is the target pending effect target game information, the pending pattern h corresponding to the pending effect target game information is displayed in the pending symbol display areas b1 and b2.

That is, during the period in which the reserved performance target game information is stored in the special figure 1 game information storage area (storage area 1 to storage area 4) (after the acquisition of the suspended performance target game information, during the period before execution of start determination based on the suspended performance target game information), the suspended design h corresponding to the suspended performance target game information is displayed in the suspended design display area b2.
At this time, the pending symbol h corresponding to the pending effect target game information is displayed at the display position corresponding to the storage area (storage area 1 to storage area 4) in which the pending effect target game information is stored.
On the other hand, during the period when the reserved performance target game information is stored in the storage area 0 (during the period from execution of start determination based on the reserved performance target game information to completion of notification display of special symbols based on the suspended performance target game information), a suspended pattern h corresponding to the suspended performance target game information is displayed in the reserved pattern display area b1.
On the other hand, in the pending effect with the special figure 2 game information as the pending effect target game information, the pending pattern h corresponding to the pending effect target game information is displayed in the pending symbol display areas b1 and b3.
That is, during the period in which the reserved performance target game information is stored in the special figure 2 game information storage area (storage area 1 to storage area 4) (during the period from the acquisition of the suspended performance target game information to the execution of the start determination based on the suspended performance target game information), the suspended design h corresponding to the suspended performance target game information is displayed in the suspended design display area b3.
At this time, the pending symbol h corresponding to the pending effect target game information is displayed at the display position corresponding to the storage area (storage area 1 to storage area 4) in which the pending effect target game information is stored.
On the other hand, during the period when the reserved performance target game information is stored in the storage area 0 (during the period from execution of start determination based on the reserved performance target game information to completion of notification display of special symbols based on the suspended performance target game information), a suspended pattern h corresponding to the suspended performance target game information is displayed in the reserved pattern display area b1.

For example, the various random numbers acquired in step S9-3 are stored as special figure 1 game information in the storage area 3 of the special figure 1 game information storage area, and when the suspension performance targeting the special figure 1 game information is executed, the suspension design h corresponding to the suspension performance target game information is displayed at the display position corresponding to the storage area 3 of the suspension design display area b2.
After that, the display area of the reserved pattern h corresponding to the reserved performance target game information is shifted from the display position corresponding to the storage area 3 to the display position corresponding to the storage area 2 in accordance with the shift of the storage area for storing the reserved performance target game information from the storage area 3 to the storage area 2. - 特許庁
In addition, when the storage area for storing the game information to be held performance is shifted from the storage area 2 to the storage area 1, the display area of the reserved pattern h corresponding to the game information to be held performance is shifted from the display position corresponding to the storage area 2 to the display position corresponding to the storage area 1. - 特許庁
Further, when the storage area for storing the reserved performance target game information is shifted from the special figure 1 game information storage area (storage area 1) to the storage area 0, the display area of the reserved design h corresponding to the reserved performance target game information is shifted from the reserved design display area b2 (display position corresponding to the storage area 1) to the reserved design display area b1.
Then, according to the end of the notification display of the special pattern based on the reserved performance target game information, the display of the reserved pattern h corresponding to the reserved performance target game information in the reserved pattern display area b1 is ended, whereby the reserved performance is completed.

In this embodiment, a normal pending effect and a pending notice effect are defined as types of the pending effect.
"Normal suspension effect" is a type of suspension effect that does not suggest the result of the preliminary determination (step S9-8) based on the game information for suspension effect.
In the present embodiment, normal suspension and special suspension are defined as types (modes) of the suspended symbol h.
In the normal pending effect, normal pending is displayed as the pending pattern h corresponding to the game information targeted for the pending effect.
The normal holding performance is started when game information (special figure 1 game information or special figure 2 game information) targeted for holding performance is stored in a game information storage area (special figure 1 game information storage area or special figure 2 game information storage area), and ends according to the end of notification display of a special symbol based on the holding performance object game information.

(Holding notice effect)
The "holding notice effect" is a kind of look-ahead notice effect. That is, the pending notice effect is a type of pending effect that indicates the result of preliminary determination (step S9-8) based on predetermined game information by the mode of the pending symbol h corresponding to the game information.
In the following description, the game information targeted for the suspension notice effect is referred to as "suspension notice target game information". Further, the pending symbol h corresponding to the pending notice target game information is referred to as the "notice target pending symbol hy".
In the present embodiment, the pending notice effect is a effect suggesting the result of advance special symbol symbol determination (specifically, the possibility of being a "big hit symbol") based on the pending announcement target game information.
It should be noted that the suspension notice effect may be configured to suggest the result of prior special figure variation pattern determination (specifically, the possibility of being "super reach variation") based on the suspension notice target game information.
In the suspension notice effect, a special suspension is displayed as the notice object suspension pattern hy.
In this embodiment, "blue reservation", "green reservation", "purple reservation", and "red reservation" are defined as special reservation modes (types).
Then, in the holding notice performance, the mode of the notice object holding pattern hy is changed, and the result of preliminary judgment based on the holding notice object game information (specifically, the possibility of generating a big win game state) is suggested by the form of the notice object holding pattern hy finally displayed.
Here, the jackpot expectation levels of each mode of the special reserve are defined to be ``red reserve'', ``purple reserve'', ``green reserve'', and ``blue reserve'' (high jackpot expectation→low jackpot expectation) in descending order of the jackpot expectation.
The “big hit expectation degree” means the possibility (degree) of occurrence of a big hit gaming state when the mode is selected.

When the suspension notice performance is executed, one or a plurality of suspension change opportunities and suspension change contents corresponding to each suspension change opportunity are set. Then, in the pending notice effect, the state of the notice subject pending symbol hy changes according to the content of the pending change corresponding to the pending change opportunity each time the hold change opportunity comes.
The "holding change opportunity" is a trigger for changing the state of the notice target holding symbol hy. Further, the "holding change content" is a content in which the state of the notice subject holding symbol hy is changed.
In this embodiment, as the pending change opportunity, the start of the variable performance corresponding to each preceding pending information, the start of the variable performance corresponding to the pending notice target game information, and the like are defined. Then, when the suspension notice performance is executed, one or a plurality of suspension change opportunities are set from among these suspension change opportunities.
In this embodiment, the pending notice effect is executed for each of the special figure 1 game information and the special figure 2 game information. However, the pending advance notice effect may be configured to be executed for only the special figure 1 game information among the special figure 1 game information and the special figure 2 game information.

(Variation production)
Next, the variation performance executed in the pachinko machine 1 will be described.
In the following description, the first performance symbol z1 displayed in the first performance symbol display area a1 is referred to as the "left symbol", the first performance symbol z1 displayed in the first performance symbol display area a2 is referred to as the "middle symbol", and the first performance symbol z1 displayed in the first performance symbol display area a3 is referred to as the "right symbol".
In the present embodiment, the second effect symbol z2 is always variably displayed in the second effect symbol display area a4 during execution of the variable effect (first half variable effect and second half variable effect).

First, each aspect of the first half variation production will be described.
In the pachinko machine 1, a variation mode number corresponding to ``pseudo continuous variation'', a variation mode number corresponding to ``pseudo continuous 2 variation'', and a variation mode number corresponding to ``pseudo continuous 3 variation'' are defined as variation mode numbers.
In addition, as categories (types) of the first half variable performance, “pseudo continuous non-continuous variable performance”, “pseudo continuous 2nd variable performance”, and “pseudo continuous 3rd variable performance” are defined.
Furthermore, as a pattern (mode) belonging to each category of the first half variable effect, one pattern or a plurality of patterns with different effect contents are defined.
Then, when a variation mode number corresponding to "pseudo continuous variation" is specified by the variation mode specifying command, "pseudo continuous variation performance" is selected as the category of the first half variation performance. On the other hand, when the variation mode number corresponding to "pseudo-continuation 2 variation" is specified by the variation mode designation command, "pseudo-continuation 2 variation performance" is selected as the category of the first half variation performance. On the other hand, when the variation mode number corresponding to the "pseudo continuation 3 variation" is specified by the variation mode specification command, the "pseudo continuation 3 variation presentation" is selected as the category of the first half variation presentation.

The "pseudo consecutive non-variable effect" includes a display effect in which the normal variable display of the first special symbol z1 is executed in each of the three first effect symbol display areas a1 to a3.
"Normal fluctuation display" is a display in which the types of the first performance symbols z1 displayed at the lottery result display positions of the first performance symbol display areas a1 to a3 are sequentially replaced at a constant tempo.
The “lottery result display position” is the position where the first effect symbol z1 is stop-displayed in the stop effect.
Concretely, in the "pseudo consecutive non-fluctuation effect", the normal fluctuation display of each symbol is sequentially started in the order of the left symbol, the middle symbol, and the right symbol.

The ``pseudo-continuous variation performance'' (``pseudo-continuous 2-variation performance'' and ``pseudo-continuous 3-variation performance'') is a performance in which the variable display of the first performance pattern z1 is pseudo-executed a plurality of times during the execution of the variable display of the special pattern once. Specifically, the pseudo-continuous variation effect is configured including a plurality of times of the pseudo-variation effect.
Here, the "pseudo-continuous 2-fluctuation effect" includes two pseudo-fluctuation effects. On the other hand, the "pseudo-continuous 3-fluctuation effect" includes three pseudo-fluctuation effects.
Each pseudo-fluctuation performance includes display performance of execution of temporary stop display of the first performance pattern z1 after normal variation display of the first special pattern z1 is executed in each of the three first performance pattern display areas a1 to a3.
"Temporary stop display" is a pseudo stop display. Concretely, the temporary stop display is a display in which one type of first effect symbol z1 remains in a state of moving in a predetermined manner (swinging, rotating, etc.) at the lottery result display position.
The “stop display” is a display of content in which one type of first effect symbol z1 remains stopped at the lottery result display position.
Concretely, in the pseudo-variation performance of each time, after the normal variation display of each pattern is started in the order of the left pattern, the middle pattern and the right pattern, the temporary stop display of each pattern is executed in the order of the left pattern, the right pattern and the middle pattern.
In particular, in the pseudo-fluctuation performance of each time, the combination of the first performance pattern z1 temporarily stopped and displayed in the three first performance pattern display areas a1 to a3 is any combination of ``missing eye'', ``ready eye'' and ``chance eye''. Here, in the final pseudo-fluctuation effect, the combination of the first effect symbol z1 temporarily stopped and displayed in the three first effect symbol display areas a1 to a3 becomes a "ready-to-win" state, establishing a ready-to-win state.
The ``missing eye'' is a combination not included in the ``jackpot pattern'' (specifically, a combination of different types of left, middle and right symbols) (except for specific combinations described later).
The "ready-to-win" is a combination included in the "jackpot pattern" (specifically, a combination in which the types of the left pattern and the right pattern are the same).
The ``chance eye'' is a specific combination (for example, a regular combination such as ``1, 2, 3'') among the combinations not included in the ``jackpot pattern'' (specifically, the combination of the left pattern, the middle pattern and the right pattern that do not match the types).
The ``reach state'' is a state in which the first performance pattern z1 is temporarily stopped and displayed in two first performance pattern display regions among the three first performance pattern display regions a1 to a3, and the combination of the temporarily stopped first performance patterns z1 is a combination included in the ``jackpot pattern''.

Next, each aspect of the second half variation production will be described.
In the pachinko machine 1, a variation pattern number corresponding to ``non-reach variation'', a variation pattern number corresponding to ``normal reach variation'', and a variation pattern number corresponding to ``super reach variation'' are defined as variation pattern numbers.
In addition, as categories (types) of the second half variable performance, "non-reach variable performance", "normal reach variable performance", and "super reach variable performance" are defined.
Furthermore, as a pattern (mode) belonging to each category of the second half variable effect, one pattern or a plurality of patterns with different effect contents are defined.
Then, when a variation pattern number corresponding to "variation without reach" is specified by the variation pattern specification command, "variation performance without reach" is selected as the category of the second half variation performance. On the other hand, when the variation pattern number corresponding to "normal reach variation" is specified by the variation pattern specification command, "normal reach variation effect" is selected as the category of the second half variation effect. On the other hand, when a variation pattern number corresponding to "super reach variation" is specified by the variation pattern specification command, "super reach variation effect" is selected as the category of the second half variation effect.

The "non-reach fluctuation effect" is an effect that is executed following the "pseudo continuous non-fluctuation effect".
In this embodiment, as the ``variation presentation without reach'', ``variation presentation without reach (lost)'' to be executed when the result of determination of special figure hit is ``loss'' and ``variation presentation without reach (jackpot)'' to be performed when the result of determination of special figure hit is ``big hit'' are defined.
``No-reach variation performance'' (``no-reach variation performance (lost)'' and ``no-reach variation performance (jackpot)'') includes display performance of contents for performing normal variation display of the first special pattern z1 in each of the three first performance pattern display areas a1 to a3.
Concretely, in the ``non-reach fluctuation presentation'', after the normal fluctuation display of the left pattern, the middle pattern and the right pattern is executed, each pattern is temporarily stopped and displayed in the order of the left pattern, the middle pattern and the right pattern.
At this time, in the "non-reach variable effect (loss)", the combination of the first effect symbols z1 temporarily stopped and displayed in the three first effect symbol display areas a1 to a3 becomes the "loss symbol".
On the other hand, in the "non-reach fluctuation effect (big hit)", the combination of the first effect symbols z1 temporarily stopped and displayed in the three first effect symbol display areas a1 to a3 becomes the "big hit symbol".

"Normal reach fluctuation effect" is an effect that is executed following the "pseudo-continuous fluctuation effect"("pseudo-continuous 2-fluctuation effect" and "pseudo-continuous 3-fluctuation effect").
In this embodiment, as the ``normal reach variation presentation'', ``normal reach variation presentation (lost)'' executed when the result of the special figure hit determination is ``losing'' and ``normal reach variation presentation (big hit)'' performed when the result of the special figure hit determination is ``big hit'' are stipulated.
``Normal reach variation performance'' (``normal reach variation performance (lost)'', ``normal reach variation performance (big win)'') is a performance executed during the formation of the ready reach state, and includes a display performance of the contents that the ``big win pattern'' is not established or the ``jackpot pattern'' is established after inciting whether or not the ``jackpot pattern'' is established.
Specifically, in the "normal ready-to-win fluctuation effect", the middle symbol is temporarily stopped and displayed after the ready-to-win effect image is displayed during the period in which the left symbol and the right symbol form the ready-to-win state.
At this time, in the "normal reach fluctuation effect (lost)", the middle symbols of a type different from the left and right symbols are temporarily stopped and displayed (the "jackpot symbol" is not established).
On the other hand, in the "normal reach fluctuation effect (big win)", the middle symbols of the same type as the left and right symbols are temporarily stopped and displayed ("big hit symbol" is established).
The ``ready-to-win effect image'' is a effect image with content that encourages the temporary stop display of middle symbols of the same type as the left and right symbols (the establishment of a ``jackpot symbol''). In this embodiment, as the ready-to-win effect images, an image in which the character included in the medium pattern performs a predetermined action and an image in which the medium pattern is given a predetermined effect are displayed.

The "super reach variation effect" is an effect that is executed following the "pseudo-continuous variation effect"("pseudo-continuous 2-variable effect" and "pseudo-continuous 3-variable effect").
In this embodiment, as ``super reach variation presentation'', ``super reach variation presentation (loss)'' executed when the result of special figure hit determination is ``loss'' and ``super reach variation presentation (big hit)'' performed when the result of special figure hit determination is ``jackpot'' are defined.
``Super reach variation performance'' (``super reach variation performance (lost)'', ``super reach variation performance (big hit)'') is a performance performed during the formation of the reach state, and after arousing whether or not the ``jackpot pattern'' is established, the display of the content that avoids the establishment of the ``jackpot pattern'' is executed, then the fluctuation display of the medium pattern is resumed, and then the content that develops from the ready reach state to the advanced reach state is displayed again. After inciting whether or not the "win pattern" is established, the "big hit pattern" is not established, or the display performance of the content of the establishment of the "big hit pattern" is included.
In the "developed reach state", the two first special symbols z1 forming the reach state are displayed in reduced size. In this embodiment, the developed reach state is formed by reducing the left and right symbols forming the reach state and displaying them at the upper end of the display screen 31a. In addition, during the period in which the developed reach state is formed, the medium symbols are not displayed.
Specifically, in the ``super ready-to-reach fluctuation performance'', after the ready-to-reach performance image is displayed during the period in which the left and right patterns form the ready-to-reach state, the middle symbols of a type different from the left and right symbols are temporarily stopped and displayed, then the variable display of the middle symbols is resumed, the developed ready-to-reach state is formed, and after the developed ready-to-reach performance image is displayed during the period to form the developed ready-to-reach state, the middle symbols are temporarily stopped and displayed.
At this time, in the "super reach variation effect (lost)", the middle symbols of a type different from the left and right symbols are temporarily stopped and displayed (the "jackpot symbol" is not established).
On the other hand, in the "super reach variation effect (big win)", the middle symbols of the same type as the left and right symbols are temporarily stopped and displayed ("big hit symbol" is established).
The "advanced ready-to-win effect image" is a effect image with content that encourages the temporary stop display of middle symbols of the same type as the left and right symbols (establishment of "big hit symbol"). In this embodiment, a predetermined background image is displayed as the developed reach effect image.

In this embodiment, a plurality of types with different big hit expectations are set as the types of "super reach variation performance"("super reach variation performance (loss)" and "super reach variation performance (big hit)"). In particular, the plurality of types include "specific super reach variation effect".
In the "specific super reach variable effect", a "specific developed reach effect image" is displayed as the developed reach effect image.
The “specific developed reach effect image” includes display of an image imitating the shape of the speaker 22 .
In particular, in this embodiment, as the image data (compressed image data) of the "specific developed reach effect image", "specific developed reach effect image data A" corresponding to "decoration unit A", "specific developed reach effect image data B" corresponding to "decoration unit B", "specific developed reach effect image data C" corresponding to "decoration unit C", and "specific developed reach effect image data D" corresponding to "decoration unit D" are stored.
"Specific advanced reach effect image data A" includes display of an image simulating the speaker 22 provided in the "decoration unit A". Further, the "specific advanced reach effect image data B" includes display of an image simulating the speaker 22 provided in the "decoration unit B". Further, the "specific developed reach effect image data C" includes display of an image simulating the speaker 22 provided in the "decoration unit C". Further, the "specific developed reach effect image data D" includes display of an image simulating the speaker 22 provided in the "decoration unit D".

The CPU 310 of the effect control board 300 acquires the first material replacement offset value stored in the first material replacement offset storage area when executing the "specific super reach variable effect". Then, image data corresponding to the acquired first material replacement offset value is set as the image data of the "specific advanced reach effect image".
At this time, when "0" is stored in the first material replacement offset storage area, "specific development reach effect image data A" is set, when "1" is stored in the first material replacement offset storage area, "specific development reach effect image data B" is set, when "2" is stored in the first material replacement offset storage area, "specific development reach effect image data C" is set, and when "3" is stored in the first material replacement offset storage area, " Specific advanced reach effect image data D" is set.
Thus, when the "specific super reach variable performance" is executed, the mode of the "specific developed reach performance image" becomes a mode corresponding to the type of the decoration unit DU attached to the front frame unit 4.例文帳に追加
That is, when the type of the decoration unit DU attached to the front frame unit 4 is the "decoration unit A", an image based on the "specific development reach performance image data A" is displayed as the "specific development reach performance image".
On the other hand, when the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit B", an image based on "specific development reach performance image data B" is displayed as the "specific development reach performance image".
On the other hand, when the type of the decoration unit DU attached to the front frame unit 4 is ``decoration unit C'', an image based on ``specific development reach performance image data C'' is displayed as the ``specific development reach performance image''.
On the other hand, when the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit D", an image based on "specific development reach performance image data D" is displayed as the "specific development reach performance image".
As described above, in the present embodiment, the "specific super reach variation effect" is a common effect for a plurality of different models. That is, the ``specific super reach variation performance'' is performed in common in the model equipped with the ``decoration unit A'', the model equipped with the ``decoration unit B'', the model equipped with the ``decoration unit C'', and the model equipped with the ``decoration unit D''.
In particular, among the performance images constituting the "specific super reach variable performance", a mode corresponding to the type (corresponding model) of the decoration unit DU attached to the front frame unit 4 is set (the performance image is displayed) for the "specific developed reach performance image", and for the other performance images, a common mode is set (the performance image is displayed) for all the types of the decoration units DU (all models) regardless of the type of the decoration unit DU attached to the front frame unit 4.

(main notice production)
Next, the main announcement effect executed in the pachinko machine 1 will be explained.
The ``main notice performance'' is a performance executed during the variable performance, and is a performance suggesting the result of start determination (special figure winning determination, special figure pattern determination, special figure variation pattern determination, etc.) relating to the variable performance.
In this embodiment, the main notice effect suggests the result of the special symbol determination (specifically, the possibility of being a "big hit symbol").
In this embodiment, a plurality of types with different content of effects are defined as the types of the main notice effect. In particular, a plurality of types include "button announcement effect".
An operation valid state is set during execution of the button announcement effect. During the period in which the operation valid state is set, the operation of the operating means (the effect button 5b, etc.) is validated. On the other hand, during the period in which the operation valid state is cancelled, the operation of the operating means is disabled.
In the button announcement effect, an operation valid state is set according to the start. Further, the operation effective state is canceled when one of two conditions is met: that a predetermined operation effective time has elapsed since the setting of the operation effective state, or that the number of times the operation of the operation means is detected reaches a predetermined number. Further, when a predetermined notification time has passed since the operation valid state was canceled, the button announcement effect is terminated.
In the following description, the period from the setting of the operation valid state (start of the button announcement effect) to the release of the operation valid state is referred to as "operation valid period". Also, the period from the release of the operation valid state to the elapse of a predetermined notification time (end of the button announcement effect) is defined as a "result notification period".

In the button announcement effect, a button announcement effect image is displayed on the display screen 31a during the operation valid period.
The "button notice performance image" includes an image (icon) simulating the operation means, a time bar indicating the remaining time until the end of the operation effective period, and information (characters) prompting the operation of the operation means.
In addition, in the button announcement effect, a result notification image is displayed on the display screen 31a during the result notification period.
The "result notification image" is configured to include information suggesting the result of the starting determination (in this embodiment, the special figure per determination).
In particular, in this embodiment, as the image data (compressed image data) of the "button notice effect image", "button notice effect image data A" corresponding to "receiver unit A", "button notice effect image data B" corresponding to "receiver unit B", "button notice effect image data C" corresponding to "receiver unit C", and "button notice effect image data D" corresponding to "receiver unit D" are stored.
The "button notice effect image data A" includes an image that simulates the operation means (for example, the effect button 5b) provided in the "receptacle unit A". Further, the "button notice effect image data B" includes an image simulating an operation means (for example, an operation lever) provided in the "receptacle unit B". Further, the "button notice effect image data C" includes an image simulating an operation means (for example, a trigger of an object resembling a gun) provided in the "receptacle unit C". Further, the "button notice effect image data D" includes an image simulating an operating means (for example, an object that can be pushed) provided in the "receptacle unit D".

The CPU 310 of the effect control board 300 acquires the second material replacement offset value stored in the second material replacement offset storage area when executing the "button advance notice effect". Then, image data corresponding to the acquired second material replacement offset value is set as the image data of the "button preview effect image".
At this time, when "0" is stored in the second material replacement offset storage area, "button notice effect image data A" is set, when "1" is stored in the second material replacement offset storage area, "button notice effect image data B" is set, when "2" is stored in the second material replacement offset storage area, "button notice effect image data C" is set, and when "3" is stored in the second material replacement offset storage area, "button notice effect image data D" is set. ” is set.
Thereby, when the "button notice effect" is executed, the mode of the "button notice effect image") becomes a mode corresponding to the type of the receiving tray unit SU attached to the front frame unit 4. - 特許庁
That is, when the type of the receiving tray unit SU attached to the front frame unit 4 is 'the receiving tray unit A', an image based on the 'button advance notice performance image data A' is displayed as the 'button advance notice performance image'.
On the other hand, when the type of the receiving tray unit SU attached to the front frame unit 4 is 'the receiving tray unit B', an image based on the 'button advance notice performance image data B' is displayed as the 'button advance notice performance image'.
On the other hand, when the type of the receiving tray unit SU attached to the front frame unit 4 is 'the receiving tray unit C', an image based on the 'button advance notice performance image data C' is displayed as the 'button notice performance image'.
On the other hand, when the type of the receiving tray unit SU attached to the front frame unit 4 is 'the receiving tray unit D', an image based on the 'button advance notice performance image data D' is displayed as the 'button advance notice performance image'.
As described above, in the present embodiment, the "button announcement effect" is a common effect for a plurality of different models. That is, the ``button notice effect'' is performed in common in the model equipped with the ``receiver unit A'', the model equipped with the ``receiver unit B'', the model equipped with the ``receiver unit C'', and the model equipped with the ``receiver unit D''.
In particular, among the effect images constituting the "button notice effect", a mode corresponding to the type (applicable model) of the receiving tray unit SU attached to the front frame unit 4 is set (the effect image is displayed) for the 'button notice effect image', and for the other effect images (result notification images), a common mode is set (the effect image is displayed) for all the types of the receiving tray units SU (all models) regardless of the type of the receiving tray unit SU attached to the front frame unit 4.

(stop production)
Next, the stop effect executed in the pachinko machine 1 will be described.
"Stop effect" is a effect that is executed during the stop display of the special symbols.
In the stop performance, the first performance pattern z1 is stop-displayed in each of the three first performance pattern display areas a1 to a3, and the second performance pattern z2 is stop-displayed in the second performance design display area a4.

(big hit)
Next, the jackpot effect executed in the pachinko machine 1 will be described.
The big-hit performance is a performance that is executed while the big-hit game state is occurring.
In the pachinko machine 1, "jackpot presentation 1" to "jackpot presentation 6" are defined as the categories (types) of the jackpot presentation.
Also, one pattern or a plurality of patterns with different content of effects are defined as patterns (modes) belonging to each category of the jackpot effects.
Then, when the stop symbol number corresponding to the "big win 1 symbol" is specified by the opening designation command, "big win effect 1" is selected as the category of the big win effect. On the other hand, when the stop symbol number corresponding to the "big hit 2 symbol" is specified by the opening designation command, the "big win effect 2" is selected as the category of the big win effect. When a stop symbol number corresponding to "big hit 3 symbols" is specified by the opening designation command, "big win effect 3" is selected as the category of the big win effect. When a stop symbol number corresponding to "big hit 4 symbols" is specified by the opening designation command, "big win effect 4" is selected as the category of the big win effect. When a stop symbol number corresponding to "big hit 5 symbols" is specified by the opening designation command, "big win effect 5" is selected as the category of the big win effect. When a stop pattern number corresponding to "6 jackpot patterns" is specified by the opening designation command, "jackpot performance 6" is selected as the category of the jackpot performance.

The jackpot performance includes an opening performance executed during the opening period, an interval performance executed during the interval period, a round performance executed during the round game, an ending performance executed during the ending period, and the like.
The "opening period" is a period from the start of the jackpot gaming state until the opening time elapses.
The "interval period" is the period from the end of the opening period to the start of the first round game, or the period from the end of each round game to the start of the next round game.
The ending period is a period from the end of the interval period after the end of the final round game until the ending time elapses.

(waiting for customers)
Next, the customer waiting state that occurs in the pachinko machine 1 will be explained.
In the pachinko machine 1, a customer waiting state is generated when a predetermined condition is established.
"Customer waiting state" is a state in which the special game (variation display/stop display of special symbols and jackpot game state) is not being executed. In addition, the customer waiting state may be a state in which the special game (variation display/stop display of special symbols and jackpot game state) is not executed and the normal game (variation display/stop display of normal symbols and normal winning game state) is not executed.
Specifically, the customer waiting state is started in response to reception of a demonstration designation command, and terminated in response to reception of a command (symbol type designation command, variation mode designation command, or variation pattern designation command) designating the start of variable display of special symbols.
That is, the customer waiting state is started when the special figure 1 reserved number is ``0'' and the special figure 2 reserved number is ``0'' at the end of the stop display of the special pattern (excluding the case where the big win game state is generated after the stop display of the special pattern is finished).
Further, the customer waiting state is started when the special figure 1 reserved number is "0" and the special figure 2 reserved number is "0" at the end of the jackpot game state.
Then, the customer waiting state is ended in response to the start of the variable display of special symbols (or acquisition of game information).

(Production custom function)
Next, the effect custom function installed in the pachinko machine 1 will be described.
In the pachinko machine 1, it is possible to change (customize) settings relating to effects in accordance with the operation of various operating means by the player.
In this embodiment, a plurality of items including a light amount setting, a volume setting, and a custom effect setting are set as the setting items related to the effect that can be customized.

(Light intensity setting)
"Light intensity setting" is used to set the light intensity (luminance) of various light sources for presentation (specifically, light-emitting elements constituting various lamps 20 and 21, backlights constituting various image display devices 31, etc.).
Specifically, the RAM of the effect control board 300 is provided with a light amount designation information setting area in which light amount designation information is set (stored).
The "light amount designation information" is information for designating the light amount of various light sources for effect. In this embodiment, it is possible to adjust the light amount of various light sources for presentation in five stages. Therefore, as light amount designation information, light amount designation information that designates each of the first (lower) to fifth (higher) stages is defined.
In the light amount designation information setting area, light amount designation information that designates one of the first to fifth stages is set (stored). Then, according to the light amount designation information set in the light amount designation information setting area, the light amounts of various light sources for effect are controlled. At this time, the more light amount designation information that designates a higher stage is set, the more the light amount of various light sources for effect increases (light emission becomes brighter).
In the pachinko machine 1, the third stage is set as the initial value of the setting contents of the light amount setting. That is, when an initial setting process (step S28-1), which will be described later, is executed, a predetermined initial value (in this embodiment, light amount designation information designating the third stage) is set in the light amount designation information setting area.
Then, while the customer waiting state is occurring, it is possible to change the setting contents of the light quantity setting to any one of the first to fifth steps by pressing the light quantity adjustment button only in the first custom state described later. That is, while the customer waiting state is occurring, only during the first custom state, the light amount designation information set in the light amount designation information setting area can be changed to the light amount designation information designating any one of the first to fifth stages by pressing the light amount adjustment button.
On the other hand, while the customer waiting state is not occurring (during the execution of the special game), it is possible to change the setting contents of the light amount setting to any one of the first to fifth stages by pressing the light amount adjustment button only in the third custom state described later. That is, during the non-regular customer waiting state, only during the third custom state, the light amount designation information set in the light amount designation information setting area can be changed to the light amount designation information designating any one of the first to fifth stages by pressing the light amount adjustment button.

(volume setting)
“Volume setting” is used to set the volume of sound (effect sound) output from various speakers 22 . Note that, in the present embodiment, it is not possible to change the volume settings of sounds (warning sounds) output from the various speakers 22 when various errors (abnormal conditions) occur.
Specifically, the RAM of the effect control board 300 is provided with a volume designation information setting area in which volume designation information is set (stored).
“Volume designation information” is information that designates the volume of the sound (effect sound) output from the various speakers 22 . In this embodiment, it is possible to adjust the volume of the sound (effect sound) output from the various speakers 22 in five steps. Therefore, as the volume designation information, volume designation information that designates each of the first (lower) to fifth (upper) stages is defined.
In the volume designation information setting area, volume designation information that designates one of the first to fifth stages is set (stored). The volume of the sound (effect sound) output from the various speakers 22 is controlled according to the volume designation information set in the volume designation information setting area. At this time, the volume of the sound (effect sound) output from the various speakers 22 increases (the sound becomes louder) as the volume designation information that designates a higher stage is set.
In the pachinko machine 1, the third stage is set as the initial value of the setting contents of the volume setting. That is, when an initial setting process (step S28-1), which will be described later, is executed, a predetermined initial value (in this embodiment, volume specifying information specifying the third level) is set in the volume specifying information setting area.
Then, while the customer waiting state is occurring, it is possible to change the setting contents of the volume setting to any one of the first to fifth stages by pressing the volume adjustment button only in the first custom state described later. That is, while the customer waiting state is occurring, only during the first custom state, it is possible to change the volume designation information set in the volume designation information setting area to the volume designation information designating any one of the first to fifth stages by pressing the volume adjustment button.
On the other hand, while the customer waiting state is not occurring (during the execution of the special game), only during the third custom state, it is possible to change the setting content of the volume setting to any one of the first to fifth stages by pressing the volume adjustment button. That is, while the customer waiting state is not occurring, only during the third custom state, the volume designation information set in the volume designation information setting area can be changed to the volume designation information designating any one of the first to fifth stages by pressing the volume adjustment button.

(Production custom setting)
FIG. 76 is a diagram showing effect custom types.
Here, FIG. 76(a) shows the effect custom types in which the custom contents can be changed (customized) during each game state, and FIG. 76(b) shows the custom contents corresponding to each effect custom type.
"Production custom settings" are detailed settings related to production.
As shown in FIG. 76, in the present embodiment, as types of effect custom settings that can be customized (hereinafter referred to as "effect custom types"), "custom initialization", "automatic button push", "treble cut mode ON/OFF", "low probability look-ahead frequency custom", "high probability look-ahead frequency custom", and "premium up custom" are defined.
As shown in FIG. 76(a), among the above-mentioned effect custom types, "custom initialization", "automatic button push", "high tone cut mode ON/OFF" and "premium up custom" are displayed as effect custom items in which the custom content can be changed (customized) in any of the customer waiting state, the special symbol low probability state, the special symbol high probability state, and the jackpot game state. As a result, with respect to ``custom initialization'', ``automatic button PUSH'', ``high tone cut mode ON/OFF'' and ``premium up custom'', it is possible to change the contents of customization in any of the customer waiting state, the special figure low probability state, the special figure high probability state and the jackpot game state.
On the other hand, among the above-mentioned production custom types, the "low-probability look-ahead frequency custom" is displayed as a production custom item whose custom contents can be changed only during the customer waiting state, the special-pattern low probability state, the special-pattern high probability state, and the jackpot game state, only during the customer waiting state and the special-pattern low probability state, and is not displayed as the production custom item whose custom content can be changed during the special-pattern high probability state and the jackpot game state. As a result, as for the ``prefetching frequency custom at low probability'', the custom content can be changed during the customer waiting state and the special figure low probability state, and the custom content cannot be changed during the special figure high probability state and the jackpot game state.
On the other hand, among the above-mentioned production custom types, the "prefetch frequency custom at high probability" is displayed as a production custom item whose custom content can be changed only during the customer waiting state, the special pattern low probability state, the special pattern high probability state, and the jackpot game state, and only during the customer waiting state and the special pattern high probability state, and is not displayed as the production custom item whose custom content can be changed during the special pattern low probability state and the jackpot game state. As a result, with respect to the ``prefetching frequency custom at high probability'', the custom content can be changed during the customer waiting state and the special figure high probability state, and the custom content cannot be changed during the special figure low probability state and the jackpot game state.

"Custom initialization" is a setting related to initialization of custom contents.
As shown in FIG. 76(b), "NO" and "YES" are specified as custom contents for "custom initialization". As a result, it is possible to set (customize) one of "NO" and "YES" as the custom content for "custom initialization".
When 'YES' is set as the custom content of 'custom initialization', it is possible to initialize the custom content (return to the initial state) for all the performance custom types via an initialization confirmation image to be described later. On the other hand, when "NO" is set as the custom content of "custom initialization", the custom content is not initialized.

"Automatic button PUSH" is a setting related to automatic pressing of the effect button 5b.
As shown in FIG. 76(b), "OFF" and "ON" are specified as custom content for "automatic button PUSH". As a result, it is possible to set (customize) one of "OFF" and "ON" as the custom content for the "automatic button PUSH".
When "ON" is set as the custom content of "automatic button push", the button automatic pressing function is enabled (executed). On the other hand, when "OFF" is set as the custom content of "automatic button PUSH", the automatic button pressing function is disabled (stopped).
The ``automatic button pressing function'' is a function of advancing the performance assuming that the pressing operation of the performance button 5b is detected in a pseudo manner even when the pressing operation of the performance button 5b is not detected during the effective period of operation in the ``button advance notice performance''.
Specifically, when the button automatic pressing function is enabled, the effect proceeds assuming that the pressing operation of the effect button 5b is detected at a predetermined timing during the operation valid period.

“High tone cut mode ON/OFF” is a setting related to the frequency band of sounds (effect sounds) output from various speakers 22 .
As shown in FIG. 76B, "OFF" and "ON" are specified as custom content for "high-pitched sound cut mode ON/OFF". As a result, it is possible to set (customize) one of "OFF" and "ON" as custom content for "high-pitched sound cut mode ON/OFF".
When "ON" is set as the custom content of "high-pitched tone cut mode ON/OFF", the high-pitched tone cut function is enabled (executed). On the other hand, when "OFF" is set as the custom content of "high-pitched tone cut mode ON/OFF", the high-pitched tone cut function is disabled (stopped).
The “treble cut function” is a function for cutting (deleting) a frequency band exceeding a predetermined threshold for sounds (effect sounds) output from various speakers 22 .

"Low certainty look-ahead frequency custom" is a setting related to the frequency of appearance of the look-ahead notice effect (suspended notice effect) in the special figure low probability state.
As shown in FIG. 76(b), for the "prefetch frequency custom at low probability", "default", "low appearance frequency", and "high appearance frequency" are defined as custom contents. As a result, it is possible to set (customize) any one of "default", "low frequency of appearance", and "high frequency of appearance" as the custom content for the "low probability prefetch frequency custom".
When ``default'' is set as the custom content of ``low-probability prefetching frequency custom'', the probability of winning the later-described prefetching notice performance lottery (step S33-5) is the first probability for the prefetching notice performance executed during the special low probability state. On the other hand, when ``low frequency of appearance'' is set as the custom content of ``low-probability prefetching frequency custom'', the probability of winning the prefetching foretelling performance lottery is the second probability lower than the first probability for the foretelling foretelling performance executed during the special low probability state. On the other hand, when ``high frequency of appearance'' is set as the custom content of ``low-probability prefetching frequency custom'', the probability of winning the prefetching foretelling performance lottery for the prefetching foretelling performance executed during the special low probability state is the third probability higher than the first probability.

"Prefetching frequency custom at high probability" is a setting related to the frequency of appearance of the prefetching notice effect (holding notice effect) in the special figure high probability state.
As shown in FIG. 76(b), for "prefetch frequency custom at high probability", "default", "low appearance frequency", "medium appearance frequency", and "high appearance frequency" are defined as custom contents. As a result, for the "prefetch frequency custom at high probability", any one of "default", "low appearance frequency", "medium appearance frequency", and "high appearance frequency" can be set (customized) as custom content.
When ``default'' is set as the custom contents of ``prefetching frequency custom at high probability'', the probability of winning the later-described prefetching notice performance lottery (step S33-5) is the first probability for the prefetching notice performance executed during the special figure high probability state. On the other hand, when ``low appearance frequency'' is set as the custom contents of ``prefetching frequency custom at high probability'', the probability of winning the prefetching notice performance lottery for the prefetching notice performance executed during the special figure high probability state is the second probability lower than the first probability. On the other hand, when ``intermediate frequency of appearance'' is set as the custom contents of ``prefetching frequency custom at high probability'', the probability of winning the prefetching notice performance lottery is the third probability higher than the first probability with respect to the prefetching notice performance executed during the special figure high probability state. On the other hand, when 'appearance frequency is high' is set as the custom contents of 'prefetching frequency custom at high probability', the probability of winning the prefetching notice performance lottery is the fourth probability higher than the third probability for the prefetching notice performance executed during the special figure high probability state.

"Premium Up Custom" is a setting related to the appearance frequency of specific premium effects.
In this embodiment, the above-mentioned "specific super reach variable effect"("specific advanced reach effect image") is defined as the specific premium effect.
As shown in FIG. 76(b), "default", "low appearance frequency", "medium appearance frequency", and "high appearance frequency" are defined as custom contents for "premium up custom". As a result, it is possible to set (customize) any one of "default", "low appearance frequency", "medium appearance frequency", and "high appearance frequency" as custom content for "premier up custom".
When "default" is set as the custom content of the "premium up custom", the probability that the "specific super reach variation effect" is selected as the type of the "super reach change effect" is the first probability. On the other hand, when ``low appearance frequency'' is set as the custom contents of ``premier up custom'', the probability of selecting ``specific super reach variation performance'' as the type of ``super reach variation performance'' is a second probability lower than the first probability. On the other hand, when ``intermediate appearance frequency'' is set as the custom content of ``premier up custom'', the probability of selecting ``specific super reach variation performance'' as the type of ``super reach variation performance'' is the third probability higher than the first probability. On the other hand, when ``high appearance frequency'' is set as the custom contents of ``premier up custom'', the probability of selecting ``specific super reach variation performance'' as the type of ``super reach variation performance'' is the fourth probability higher than the third probability.

In the pachinko machine 1, when an initial setting process (step S28-1), which will be described later, is executed, custom content is initialized (initial state is set) for each effect custom type. At this time, "NO" is set as the initial state for "custom initialization", "OFF" is set as the initial state for "automatic button PUSH", "OFF" is set as the initial state for "treble cut mode ON/OFF", "default" is set as the initial state for "low accuracy lookahead frequency custom", "default" is set as the initial state for "high accuracy lookahead frequency custom", and "default" is set as the initial state for "premium up custom". set.
Specifically, the DRAM 304 is provided with a custom information storage area. The custom information storage area includes a first area that stores information specifying the custom content of "custom initialization", a second area that stores information that specifies the custom content of "automatic button PUSH", a third area that stores information that specifies the custom content of "treble cut mode ON/OFF", a fourth area that stores information that specifies the custom content of "prefetching frequency custom at low accuracy", and a fifth area that stores information specifying the custom content of "prefetching frequency custom at high accuracy". and a sixth area in which information designating custom contents of "Premier Up Custom" is stored.
Then, in the initial setting process (step S28-1), of the custom information storage areas, information specifying custom content="NO" is stored (set) in the first area, information specifying custom content="OFF" is stored (set) in the second area, information specifying custom content="OFF" is stored (set) in the third area, information specifying custom content="default" is stored (set) in the fourth area, and information specifying custom content="default" is stored (set) in the fifth area. Information specifying "default" is stored (set), and in the sixth area, information specifying custom content="default" is stored (set).
In particular, during the occurrence of the customer waiting state, it is possible to change (customize) the contents of customization for each effect custom type by pressing the cross key button, the effect button 5b, etc. in the second custom state described later.
On the other hand, during the non-regular state of the customer waiting state (during execution of the special game), it is possible to change (customize) the custom content for each effect custom type by pressing the cross key button, the effect button 5b, etc. in the fourth custom state described later.

(How to change settings related to production)
Next, a method of changing the setting (custom method) regarding the effect will be described.
FIG. 77 is a diagram showing an example of the first custom interface image IF1. FIG. 78 is a diagram showing display transitions during the first custom state. FIG. 79 is a diagram showing display transitions at the end of the first custom state. FIG. 80 is a diagram showing an example of the second custom interface image IF2. FIG. 81 is a diagram showing display transition during the second custom state according to the first example. FIG. 82 is a diagram showing display transition during the second custom state according to the second example. FIG. 83 is a diagram showing an example of the custom change message image cm. FIG. 84 is a diagram showing display transitions at the end of the second custom state. FIG. 85 is a diagram showing transition of display of the custom change message image cm at the end of the second custom state. FIG. 86 is a diagram showing display transitions at the end of the fourth custom state. FIG. 87 is a diagram showing transition of display of the custom change message image cm at the end of the fourth custom state.
In the pachinko machine 1, it is possible to change the light amount setting and volume setting during the first custom state or the third custom state. Further, it is possible to change the effect custom setting during the second custom state or the fourth custom state.

(first custom state)
The first custom state is set while the customer waiting state is occurring.
That is, when the custom starting condition is satisfied while the customer waiting state is occurring, the first custom state is started.
In the present embodiment, the custom start condition is met when either of (1) "a predetermined time (20.0 [s] in this embodiment) has elapsed since the start of the customer waiting state (receipt of the demo designation command)" and (2) "an operation of pressing the effect button 5b is detected" is met.
Note that the custom start condition may be established when any one of (1) ``the duration of a state in which no touch signal is input from the touch sensor 412 to the firing enable condition detection unit 422 has reached a predetermined time (for example, 20.0 [s])'' and (2) ``the operation of pressing the effect button 5b is detected'' is satisfied.

During the first custom state, a first custom interface image IF1 shown in FIG. 77 is displayed on the display screen 31a.
The first custom interface image IF1 is displayed superimposed on the stopped first effect symbol z1. At this time, the first custom interface image IF1 is displayed on a layer higher (on the front side/on the front side) than the first effect symbol z1. As a result, all or part of the stopped-displayed first effect symbol z1 is covered (concealed) by the first custom interface image IF1.
The first custom interface image IF1 includes a light amount setting image im1, a volume setting image im2, and a cross key button explanation image im3.
The light intensity setting image im1 includes display of information indicating the current setting details of the light intensity setting, and display of information notifying that the setting details of the light intensity setting can be changed by pressing the light intensity adjustment button.
The volume setting image im2 includes display of information indicating the current setting contents of the volume setting, and display of information notifying that the setting contents of the volume setting can be changed by pressing the volume adjustment button.
The cross key button explanation image im3 displays information notifying that the shortcut window SW corresponding to "premium up custom" can be displayed by pressing the right key button, displaying information notifying that the shortcut window SW corresponding to "treble cut mode ON/OFF" can be displayed by pressing the left key button, displaying information notifying that the shortcut window SW corresponding to "automatic button PUSH" can be displayed by pressing the up key button, and pressing the down key button. and display of information notifying that the second custom interface image IF2 can be displayed by the pressing operation.

During the first custom state, it is possible to change the setting contents of the light amount setting according to the pressing operation of the light amount adjustment button. Further, during the first custom state, it is possible to change the setting contents of the volume setting according to the pressing operation of the volume adjustment button.
In addition, during the first custom state, it is possible to change the contents of customization for some of the above custom effects types using the shortcut function. In the present embodiment, among the above-mentioned effect custom types, for "automatic button push", "treble cut mode ON/OFF", and "premium up custom", it is possible to change the custom contents using the shortcut function during the first custom state.

Specifically, in response to the start of the first custom state, the first custom interface image IF1 starts to be displayed on the display screen 31a (see FIG. 78(a)).
Then, when the pressing operation of the light amount adjustment button is detected while the first custom interface image IF1 is being displayed, the setting contents of the light amount setting are changed accordingly. Further, when an operation of pressing the volume adjustment button is detected while the first custom interface image IF1 is being displayed, the contents of the volume setting are changed accordingly.
On the other hand, when the pressing operation of the left key button is detected while the first custom interface image IF1 is being displayed, in response to this, a shortcut window SW corresponding to "treble cut mode ON/OFF" is displayed on the display screen 31a instead of the first custom interface image IF1 (see FIGS. 78(a)→(b)).
The shortcut window SW corresponding to "high-pitched tone cut mode ON/OFF" includes display of information notifying that custom content for "high-pitched tone cut mode ON/OFF" can be changed by depressing the left key button and right key button, and display of information indicating custom content set for "high-pitched tone cut mode ON/OFF" (hereinafter referred to as "custom content display").
During the display of the shortcut window SW corresponding to the "treble cut mode ON/OFF", every time the left key button or the right key button is pressed, the custom content indicated by the custom content display is changed in a predetermined order (in this embodiment, "ON"→"OFF"→"ON"→"OFF" .
When the operation of the left key button and the right key button is not detected during the display of the shortcut window SW corresponding to "high-pitched tone cut mode ON/OFF" and the duration time reaches a predetermined time (1.5 [s] in this embodiment), display of the shortcut window SW corresponding to "high-pitched tone cut mode ON/OFF" is ended on the display screen 31a, and the first custom interface image IF1 is displayed again (see FIG. 78(a)).

On the other hand, when an operation of pressing the up key button is detected while the first custom interface image IF1 is being displayed, a shortcut window SW corresponding to "automatic button PUSH" is displayed instead of the first custom interface image IF1 on the display screen 31a (see FIGS. 78(a)→(c)).
The shortcut window SW corresponding to the "automatic button PUSH" includes display of information notifying that the custom content of the "automatic button PUSH" can be changed by pressing the left key button/right key button, and display of information indicating the custom content set for the "automatic button PUSH" (hereinafter referred to as "custom content display").
Then, while the shortcut window SW corresponding to the "automatic button PUSH" is being displayed, the custom content indicated by the custom content display is changed in a predetermined order (in this embodiment, "ON"→"OFF"→"ON"→"OFF" .
When the operation of the left key button and the right key button is not detected while the shortcut window SW corresponding to the "automatic button PUSH" is being displayed reaches a predetermined time (1.5 [s] in this embodiment), the display of the shortcut window SW corresponding to the "automatic button PUSH" is ended on the display screen 31a, and the first custom interface image IF1 is displayed again (see FIG. 78(a)).

On the other hand, when an operation of pressing the right key button is detected while the first custom interface image IF1 is being displayed, a shortcut window SW corresponding to "premium up custom" is displayed instead of the first custom interface image IF1 on the display screen 31a (see FIGS. 78(a)→(d)).
The shortcut window SW corresponding to the "premier up custom" includes display of information notifying that the custom content of the "premier up custom" can be changed by depressing the left key button and the right key button, and display of information indicating the custom content set for the "premier up custom" (hereinafter referred to as "custom content display").
While the shortcut window SW corresponding to "premium up custom" is displayed, the custom content indicated by the custom content display is changed in a predetermined order (in this embodiment, "default"→"low appearance frequency"→"medium appearance frequency"→"high appearance frequency"→"default" .
When the operation of the left key button and the right key button is not detected during the display of the shortcut window SW corresponding to "Premier Up Custom" and the duration reaches a predetermined time (1.5 [s] in this embodiment), display of the shortcut window SW corresponding to "Premier Up Custom" is ended on the display screen 31a, and the first custom interface image IF1 is displayed again (see FIG. 78(a)).

On the other hand, when an operation of pressing the down key button is detected while the first custom interface image IF1 is being displayed, the first custom state ends and the second custom state starts accordingly. In particular, when an operation of pressing the down key button is detected while the first custom interface image IF1 is being displayed, display of the first custom interface image IF1 is terminated and display of the second custom interface image IF2 is started on the display screen 31a (see (a)→(b) in FIG. 79).
Further, when the duration of the no-operation state reaches a predetermined time (10.0 [s] in this embodiment) while the first custom interface image IF1 is being displayed, the first custom state is ended accordingly. At this time, the state returns to the customer waiting state in which the first custom state is not occurring and the second custom state is not occurring. In particular, when the duration of the non-operational state reaches a predetermined time (10.0 [s] in this embodiment) while the first custom interface image IF1 is being displayed, the display of the second custom interface image IF2 is ended accordingly, and the image corresponding to the customer waiting state is restored (see FIGS. 79(a)→(c)).
The "no operation state" is a state in which no operation is detected for any of the effect button 5b, the light amount adjustment button, the volume adjustment button, and the cross key button.
Furthermore, when the special symbol starts to change while the first custom interface image IF1 is being displayed (in this embodiment, when any one of the symbol type specifying command, the variation mode specifying command, and the variation pattern specifying command is received), the first custom state is ended accordingly. At this time, the process shifts to the execution of the special game (during the variable display of the special symbols). In particular, when the special symbol starts to change while the first custom interface image IF1 is being displayed (in this embodiment, when any one of the symbol type designation command, the variation mode designation command, and the variation pattern designation command is received), the display of the first custom interface image IF1 is ended in response to this, and the variable display of the effect symbols z1 and z2 is started (see FIGS. 79(a)→(d)).
Further, when a specific display end condition is established during display of the first custom interface image IF1, the display of the first custom interface image IF1 is ended according to the establishment of the specific display condition, and display of an image notifying the occurrence of a specific abnormal state is started.
In this embodiment, as the "specific display end condition", it is defined that the occurrence of a specific abnormal state (vibration error, magnetic error, radio wave error, right-handed error, illegal winning error, decoration unit error, etc.) has been detected.
A “vibration error” is determined to occur when a predetermined vibration is detected by the vibration detection sensor 113 . A “radio wave error” is determined to occur when a predetermined radio wave is detected by the radio wave detection sensor 114 . A “magnetic error” is determined to occur when a predetermined magnetism (magnetic force) is detected by the magnetism detection sensor 115 . A "right-handed error" is determined to occur when the value of the right-handed error counter reaches a predetermined value. The occurrence of the ``unauthorized prize winning error'' is determined when the number of game balls entering the role ball entrance (the second start hole 52, the big winning hole 53, etc.) reaches a predetermined number during the period when it is impossible (difficult) to enter the ball into the role ball entrance. A "decoration unit error" is determined to occur when it is determined that the decoration unit DU is not attached to the front frame unit 4 (the attachment of the decoration unit DU to the front frame unit 4 is incomplete).
As the specific display end condition, in addition to the detection of the occurrence of the specific abnormal state, or in place of the detection of the occurrence of the specific abnormal state, the start of a specific pre-reading advance notice performance, the detection of the passage of the game ball through the performance gate, etc. may be specified.
A “performance gate” is provided in the game area 30 . Then, a predetermined effect is executed in response to detection of passage of the game ball through the effect gate.

(Second custom state)
A second custom state is set while the customer waiting state is occurring.
As described above, when the operation of pressing the down key button is detected while the first custom interface image IF1 is being displayed, the second custom state is started.
During the second custom state, a second custom interface image IF2 shown in FIG. 80 is displayed on the display screen 31a.
The second custom interface image IF2 is displayed superimposed on the stopped first effect symbol z1. At this time, the second custom interface image IF2 is displayed on a layer higher (on the front side/on the front side) than the first effect symbol z1. As a result, all or part of the stopped-displayed first effect symbol z1 is covered (concealed) by the second custom interface image IF2.
The second custom interface image IF2 includes a performance custom type display portion dp1, a custom content explanation display portion dp2, and a custom content display portion dp3.
The selected effect custom type is displayed in the effect custom type display portion dp1.
The custom content description display portion dp2 displays the description of the custom content that allows the custom effect type displayed in the custom effect type display portion dp1 to be changed.
The custom content display portion dp3 displays the custom content selected for the custom effect type displayed in the custom effect type display portion dp1.

In the second custom state, it is possible to change the custom content for all of the above-mentioned effect custom types.
Specifically, in response to the start of the second custom state, the display of the second custom interface image IF2 is started on the display screen 31a (see FIG. 81(a)).
Then, each time the pressing operation of the down key button is detected while the second custom interface image IF2 is being displayed, the effect custom type displayed in the effect custom type display section dp1 is changed in a predetermined order (in the present embodiment, "custom initialization"→"automatic button PUSH"→"high tone cut mode ON/OFF"→"prefetching frequency custom at low probability"→"prefetching frequency custom at high probability"→"premier up custom"→"custom initialization"...) (Fig. 81(a)→(b)). reference). At this time, along with the change of the performance custom type displayed in the performance custom type display part dp1, the explanation of the custom content displayed in the custom content explanation display part dp2 and the custom content displayed in the custom content display part dp3 are also changed to contents corresponding to the performance custom type displayed in the performance custom type display part dp1.
On the other hand, each time the pressing operation of the upper key button is detected while the second custom interface image IF2 is being displayed, the effect custom type displayed in the effect custom type display portion dp1 is changed in an order opposite to the predetermined order (in this embodiment, "custom initialization" → "premier up custom" → "high probability prefetch frequency custom" → "low probability prefetch frequency custom" → "high tone cut mode ON/OFF" → "auto button push" → "custom initialization"...) (Fig. 81). (a)→(c) reference). At this time, along with the change of the performance custom type displayed in the performance custom type display part dp1, the explanation of the custom content displayed in the custom content explanation display part dp2 and the custom content displayed in the custom content display part dp3 are also changed to contents corresponding to the performance custom type displayed in the performance custom type display part dp1.
At this time, during the second custom state, it is possible to select all effect custom types ("custom initialization", "automatic button PUSH", "treble cut mode ON/OFF", "low accuracy look-ahead frequency custom", "high accuracy look-ahead frequency custom" and "premium up custom") by pressing the upper key button or the lower key button.

Further, each time the pressing operation of the right key button is detected while the second custom interface image IF2 is being displayed, the custom content displayed in the custom content display portion dp3 is changed in a predetermined order.
On the other hand, every time the pressing operation of the left key button is detected while the second custom interface image IF2 is being displayed, the custom content displayed in the custom content display section dp3 is changed in the order opposite to the predetermined order.
At this time, during the second custom state, it is possible to select all the custom contents specified for the selected effect custom type (the effect custom type displayed in the effect custom type display section dp1) by pressing the right key button or the left key button.
For example, when “custom look-ahead frequency at low probability” is selected (when “custom look-ahead frequency at low probability” is displayed in the effect custom type display section dp1), the custom content displayed in the custom content display section dp3 is changed in a predetermined order (in this embodiment, “default” → “low appearance frequency” → “high appearance frequency” → “default” .
On the other hand, if "low -accuracy -in -read frequency custom" is selected (when the "low -accuracy time reading frequency custom" is displayed in the production custom type display part DP1), the custom content displayed in the custom contents display part DP3 is the above every time the left key button is detected. It is changed by the opposite order (in this embodiment, "default" → "high appearance frequency" → "low appearance frequency" → "default" ...) (see Fig. 82 (A) → (C)).

As described above, while the second custom interface image IF2 is being displayed, by pressing the cross key button, it is possible to select the custom contents of each effect custom type for all the effect custom types ("custom initialization", "automatic button PUSH", "treble cut mode ON/OFF", "low probability lookahead frequency custom", "high probability lookahead frequency custom" and "premium up custom").
Here, in the present embodiment, even if custom contents are selected for each effect custom type by pressing the cross key button, the selected custom contents are not confirmed and the selected custom contents are not reflected in the custom information storage area unless the pressing operation of the effect button 5b is detected.
That is, when the pressing operation of the effect button 5b is detected during the display of the second custom interface image IF2, the display of the second custom interface image IF2 is ended on the display screen 31a, and the second custom state is ended.
Further, when a pressing operation of the production button 5b is detected while the second custom interface image IF2 is being displayed, it is determined whether or not the custom contents (internally set custom contents) indicated by the information stored in the custom information storage area match the custom contents selected in the second custom interface image IF2 for all the production custom types.
Then, when it is determined that the custom content selected in the second custom interface image IF2 is different from the custom content (internally set custom content) indicated by the information stored in the custom information storage region for at least one effect custom type, the custom information storage region update process is executed, and the display of the custom change message image cm shown in FIG.
In the following description, the effect custom type for which it is determined that the custom content selected in the second custom interface image IF2 is different from the custom content indicated by the information stored in the custom information storage area (internally set custom content) will be referred to as a "changed effect custom type".

In the custom information storage area update process, the information stored in the custom information storage area is changed (overwritten) for each modified effect custom type. Specifically, for each changed effect custom type, the information stored in the area (first area to sixth area) corresponding to the changed effect custom type among the custom information storage areas is changed (overwritten) to the information specifying the custom content corresponding to the changed effect custom type among the custom contents selected in the second custom interface image IF2.
The custom change message image cm includes display of information indicating that the custom contents have been changed for at least one effect custom type.
On the other hand, if it is determined that the custom content selected in the second custom interface image IF2 is not different from the custom content (internally set custom content) indicated by the information stored in the custom information storage region for all the performance custom types, the custom information storage region update processing is not executed. That is, when there is no effect custom type with change, the custom information storage area update process is not executed. In this case, the display of the second custom interface image IF2 is terminated (the second custom state is terminated) on the display screen 31a in response to the detection of the pressing operation of the effect button 5b, and the custom change message image cm is not displayed.

Specifically, when the pressing operation of the effect button 5b is detected while the second custom interface image IF2 is being displayed (when there is a changed effect custom type), the second custom state is terminated accordingly. At this time, the process shifts to a customer waiting state in which the first custom state is not occurring and the second custom state is not occurring. In particular, when the pressing operation of the effect button 5b is detected during the display of the second custom interface image IF2 (if there is a custom effect type with change), the display of the second custom interface image IF2 is ended and the display of the custom message image cm is started on the display screen 31a (see (a)→(b) in FIG. 84).
On the other hand, when the pressing operation of the effect button 5b is detected while the second custom interface image IF2 is being displayed (when there is no changed effect custom type), the second custom state is terminated accordingly. At this time, the process shifts to a customer waiting state in which the first custom state is not occurring and the second custom state is not occurring. In particular, when the pressing operation of the effect button 5b is detected during the display of the second custom interface image IF2 (when there is no changeable effect custom type), the display of the second custom interface image IF2 is ended on the display screen 31a accordingly, and the display of the image corresponding to the customer waiting state is restored (not shown).
Further, when the duration of the no-operation state reaches a predetermined time (10.0 [s] in this embodiment) while the second custom interface image IF2 is being displayed, the second custom state is terminated accordingly. At this time, the process shifts to a customer waiting state in which the first custom state is not occurring and the second custom state is not occurring. When the duration of the non-operating state reaches a predetermined time (10.0 [s] in this embodiment) while the second custom interface image IF2 is being displayed, the display of the second custom interface image IF2 is terminated accordingly, and the display of the image corresponding to the customer waiting state is restored (see FIGS. 84(a)→(c)).
Furthermore, when the special symbol starts to change while the second custom interface image IF2 is being displayed (in this embodiment, when any one of the symbol type designation command, the variation mode designation command, and the variation pattern designation command is received), the second custom state is terminated accordingly. At this time, the process shifts to the execution of the special game (during the variable display of the special symbols). In particular, when the special symbol starts to change while the second custom interface image IF2 is being displayed (in this embodiment, when any one of the symbol type designating command, the variation mode designating command, and the variation pattern designating command is received), the display of the second custom interface image IF2 ends accordingly, and the variable display of the performance symbols z1 and z2 starts (see (a) to (d) of FIG. 84).
Further, when the specific display end condition is established during the display of the second custom interface image IF2, the display of the second custom interface image IF2 is ended in accordance with the establishment of the specific display condition, and the display of the image notifying the occurrence of the specific abnormal state is started.

The display of the custom change message image cm ends when a predetermined time (10.0 [s] in this embodiment) elapses from its start. In particular, the display of the custom change message image cm is continued until a predetermined time elapses without being terminated in accordance with this, even when the special pattern starts to fluctuate during its display (in this embodiment, when any one of the pattern type designation command, the fluctuation mode designation command, and the fluctuation pattern designation command is received).
Specifically, when a predetermined time (10.0 [s] in this embodiment) elapses from the start of display of the custom change message image cm, the display of the custom change message image cm ends accordingly (see FIG. 85(a)→(b)). At this time, when the display of the custom change message image cm ends, the display of the image corresponding to the customer waiting state is resumed.
On the other hand, the display of the custom change message image cm is not terminated in response to the start of the variation of the special symbols (in this embodiment, when any one of the symbol type designation command, the variation mode designation command, and the variation pattern designation command is received) before a predetermined time (10.0 [s] in this embodiment) elapses from the start (see FIG. 85(a)→(c)). In this case, the display of the custom change message image cm is continued even during the variable display of the performance symbols z1 and z2 (during the variable display of the special symbols). When a predetermined time (10.0 [s] in this embodiment) elapses from the start of the display of the custom change message image cm, the display of the custom change message image cm ends accordingly (see FIG. 85(c)→(d)). At this time, the production patterns z1 and z2 are changed according to the end of the display of the custom change message image cm.
Here, in the present embodiment, if the specific display end condition is satisfied during a period from the start of the display of the custom change message image cm to the elapse of a predetermined time (10.0 [s] in the present embodiment), the display of the custom change message image cm is ended in response to the establishment of the specific display end condition, and the display of the image notifying the occurrence of the specific abnormal state is started.

(Third custom state)
A third custom state is set during execution of a special game.
In this embodiment, the third custom state is always set during execution of the special game. That is, the third custom state is always set during the period during which the notification display (variable display and stop display) of the special symbols is executed and during the period during which the big win game state is generated.
During the third custom state, it is possible to change the setting contents of the light amount setting according to the pressing operation of the light amount adjustment button. Further, during the third custom state, it is possible to change the setting contents of the volume setting according to the pressing operation of the volume adjustment button.
In addition, during the third custom state, it is possible to change the contents of customization for some of the above custom effects types by using the shortcut function. In the present embodiment, among the above-mentioned effect custom types, it is possible to change the custom content for "automatic button push", "treble cut mode ON/OFF" and "premium up custom" using the shortcut function in the third custom state.

Specifically, during the third custom state, display of the light amount setting image im1 is started in response to detection of the pressing operation of the light amount adjustment button. Then, when an operation of pressing the light amount adjustment button is detected while the light amount setting image im1 is being displayed, the setting contents of the light amount setting are changed accordingly.
Further, during the third custom state, the display of the volume setting image im2 is started in response to detection of pressing operation of the volume adjustment button. Then, when the pressing operation of the volume adjustment button is detected while the volume setting image im2 is being displayed, the setting contents of the volume setting are changed accordingly.

Further, when a pressing operation of the left key button is detected during the third custom state, a shortcut window SW corresponding to "treble cut mode ON/OFF" is displayed on the display screen 31a accordingly.
During the display of the shortcut window SW corresponding to the "treble cut mode ON/OFF", every time the left key button or the right key button is pressed, the custom content indicated by the custom content display is changed in a predetermined order (in this embodiment, "ON"→"OFF"→"ON"→"OFF" .
When the duration of a state in which no operation of the left key button or the right key button is detected reaches a predetermined time (1.5 [s] in this embodiment) while the shortcut window SW corresponding to "high tone cut mode ON/OFF" is being displayed, display of the shortcut window SW corresponding to "high tone cut mode ON/OFF" is ended on the display screen 31a accordingly.

On the other hand, when an operation of pressing the upper key button is detected during the third custom state, a shortcut window SW corresponding to "automatic button PUSH" is displayed on the display screen 31a accordingly.
Then, while the shortcut window SW corresponding to the "automatic button PUSH" is being displayed, the custom content indicated by the custom content display is changed in a predetermined order (in this embodiment, "ON"→"OFF"→"ON"→"OFF" .
While the shortcut window SW corresponding to the "automatic button PUSH" is being displayed, when the duration of the state in which the operation of the left key button and the right key button is not detected reaches a predetermined time (1.5 [s] in this embodiment), the display of the shortcut window SW corresponding to the "automatic button PUSH" is terminated on the display screen 31a accordingly.

On the other hand, when an operation of pressing the right key button is detected during the third custom state, a shortcut window SW corresponding to "Premier Up Custom" is displayed on the display screen 31a accordingly.
While the shortcut window SW corresponding to "premier up custom" is displayed, the custom content indicated by the custom content display is changed in a predetermined order (in this embodiment, "default"→"low appearance frequency"→"medium appearance frequency"→"high appearance frequency"→"default" .
When the operation of the left key button and the right key button is not detected during the display of the shortcut window SW corresponding to "Premier Up Custom" and the duration reaches a predetermined time (1.5 [s] in this embodiment), the display of the shortcut window SW corresponding to "Premier Up Custom" is ended on the display screen 31a accordingly.

On the other hand, when an operation of pressing the down key button is detected during the third custom state, the third custom state ends and the fourth custom state starts.

(4th custom state)
A fourth custom state is set during execution of a special game.
As described above, when an operation of pressing the down key button is detected during the third custom state, the fourth custom state is started.
During the fourth custom state, the second custom interface image IF2 is displayed on the display screen 31a.
At this time, the second custom interface image IF2 is displayed on a layer higher (on the front side/on the front side) than the first effect symbol z1. In particular, the second custom interface image IF2 is displayed at least at a position that does not cover (hide) the first effect symbol z1 that is statically displayed.

During the fourth custom state, the effect custom type that allows the custom contents to be changed changes according to the game state.
That is, during the special low probability state, custom contents can be changed for "custom initialization", "automatic button PUSH", "high tone cut mode ON/OFF", "low probability time look-ahead frequency custom" and "premium up custom".
On the other hand, during the special figure high probability state, custom contents can be changed for "custom initialization", "automatic button PUSH", "treble cut mode ON/OFF", "prefetch frequency custom at high probability" and "premium up custom".
On the other hand, during the jackpot game state, it is possible to change the contents of customization for "custom initialization", "automatic button PUSH", "treble cut mode ON/OFF" and "premium up custom".

Specifically, in response to the start of the fourth custom state, the display of the second custom interface image IF2 is started on the display screen 31a.
The method of changing the custom contents of each performance custom type while the fourth custom state is occurring (during the display of the second custom interface image IF2) is the same as the method of changing the custom content of each performance custom class while the second custom state is occurring (during the display of the second custom interface image IF2).
That is, while the second custom interface image IF2 is being displayed, it is possible to select custom content for each custom effect type by pressing the cross key button.
Here, in the present embodiment, even if custom contents are selected for each effect custom type by pressing the cross key button, the selected custom contents are not confirmed and the selected custom contents are not reflected in the custom information storage area unless the pressing operation of the effect button 5b is detected.

When the pressing operation of the effect button 5b is detected during the display of the second custom interface image IF2, the display of the second custom interface image IF2 is ended on the display screen 31a, and the fourth custom state is ended.
Further, when a pressing operation of the performance button 5b is detected during display of the second custom interface image IF2, it is determined whether or not the custom content (internally set custom content) indicated by the information stored in the custom information storage area matches the custom content selected in the second custom interface image IF2 for all the performance custom types.
Then, when it is determined that the custom content selected in the second custom interface image IF2 is different from the custom content indicated by the information stored in the custom information storage area (internally set custom content) for at least one effect custom type, the custom information storage area update process described above is executed, and the display of the custom change message image cm is started on the display screen 31a in accordance with the end of the display of the second custom interface image IF2 (the end of the fourth custom state).
On the other hand, when it is determined that the custom content selected in the second custom interface image IF2 is not different from the custom content (internally set custom content) indicated by the information stored in the custom information storage region for all the performance custom types, the custom information storage region update processing is not executed. That is, when there is no effect custom type with change, the custom information storage area update process is not executed. In this case, the display of the second custom interface image IF2 is terminated (the fourth custom state is terminated) on the display screen 31a in response to the detection of the pressing operation of the effect button 5b, and the custom change message image cm is not displayed.

Specifically, when the pressing operation of the effect button 5b is detected while the second custom interface image IF2 is being displayed (when there is a changed effect custom type), the fourth custom state is terminated accordingly. At this time, the state shifts to the third custom state. In particular, when the pressing operation of the effect button 5b is detected during the display of the second custom interface image IF2 (when the effect custom type with change exists), the display of the second custom interface image IF2 is ended and the display of the custom message image cm is started on the display screen 31a (see (a)→(b) of FIG. 86).
On the other hand, when the pressing operation of the effect button 5b is detected while the second custom interface image IF2 is being displayed (when there is no changed effect custom type), the fourth custom state is terminated accordingly. At this time, the state shifts to the third custom state. In particular, when the pressing operation of the effect button 5b is detected during the display of the second custom interface image IF2 (when there is no custom effect type with change), the display of the second custom interface image IF2 is ended on the display screen 31a accordingly, and the display of the image corresponding to the special game is restored (not shown).
Further, when the duration of the no-operation state reaches a predetermined time (10.0 [s] in this embodiment) while the second custom interface image IF2 is being displayed, the fourth custom state is terminated accordingly. At this time, the state shifts to the third custom state. When the duration of the non-operating state reaches a predetermined time (10.0 [s] in this embodiment) while the second custom interface image IF2 is being displayed, the display of the second custom interface image IF2 is ended accordingly, and the display of the image corresponding to the special game is restored (see FIGS. 86(a)→(c)).
Furthermore, when the customer waiting state is started while the second custom interface image IF2 is being displayed (in this embodiment, when a demo designation command is received), the fourth custom state is terminated accordingly. At this time, it shifts to a customer waiting state. In particular, when the customer waiting state is started while the second custom interface image IF2 is being displayed (in this embodiment, when a demo designation command is received), the display of the second custom interface image IF2 is terminated accordingly, and the display of the image corresponding to the customer waiting state is started (see FIGS. 86(a)→(d)).
Further, when the specific display end condition is established during the display of the second custom interface image IF2, the display of the second custom interface image IF2 is ended in accordance with the establishment of the specific display condition, and the display of the image notifying the occurrence of the specific abnormal state is started.

The display of the custom change message image cm ends when a predetermined time (10.0 [s] in this embodiment) elapses from its start. In particular, the display of the custom change message image cm is continued until a predetermined time elapses without being terminated in response to the customer waiting state being started during the display (in this embodiment, when a demo designation command is received).
Specifically, when a predetermined time (10.0 [s] in this embodiment) elapses from the start of the display of the custom change message image cm, the display of the custom change message image cm ends accordingly (see (a)→(b) in FIG. 87). At this time, when the display of the custom change message image cm ends, the display of the image corresponding to the special game is restored.
On the other hand, the display of the custom change message image cm is not terminated in response to the start of the customer waiting state (in the present embodiment, when a demo designation command is received) before a predetermined time (10.0 [s] in this embodiment) elapses from the start (see FIG. 87(a)→(c)). In this case, the display of the custom change message image cm is continued even during the customer waiting state. Then, when a predetermined time (10.0 [s] in this embodiment) elapses from the start of the display of the custom change message image cm, the display of the custom change message image cm ends accordingly (see FIG. 87(c)→(d)). At this time, when the display of the custom change message image cm ends, the image corresponding to the customer waiting state is displayed.
Here, in the present embodiment, if the specific display end condition is satisfied during a period from the start of the display of the custom change message image cm to the elapse of a predetermined time (10.0 [s] in the present embodiment), the display of the custom change message image cm is ended in response to the establishment of the specific display end condition, and the display of the image notifying the occurrence of the specific abnormal state is started.

(initialization of custom content)
During the display of the second custom interface image IF2, 'YES' is selected as the custom content of 'custom initialization' by pressing the cross key button, and when the presentation button 5b is pressed, the display of the initialization confirmation image is started instead of the display of the second custom interface image IF2. Then, when execution of initialization of the custom content is selected by pressing operation of the cross key button and pressing operation of the performance button 5b while the initialization confirmation image is being displayed, the custom content is initialized (returned to the initial state) for all the performance custom types.
Further, when the duration of the non-operating state reaches a predetermined time (30.0 [s] in this embodiment) during the customer waiting state, the display of the initialization confirmation image is started accordingly. Then, when execution of initialization of the custom content is selected by pressing operation of the cross key button and pressing operation of the performance button 5b while the initialization confirmation image is being displayed, the custom content is initialized (returned to the initial state) for all the performance custom types.
As described above, when the custom content is initialized, the first area of the custom information storage area stores (sets) the information specifying the custom content=“NO”, the second area stores (sets) the information specifying the custom content=“OFF”, the third area stores (sets) the information specifying the custom content=“OFF”, the fourth area stores (sets) the information specifying the custom content=“default”, and the fifth area stores (sets) the information specifying the custom content=“default”. is stored (set), and information specifying custom content=“default” is stored (set) in the sixth area.

(Processing executed by production control board 300)
Next, processing executed by the CPU 310 of the effect control board 300 will be described.
In this embodiment, command reception interrupt processing, sub timer interrupt processing, and movable body interrupt processing, which will be described later, are interrupt processing executed by an interrupt handler. On the other hand, Vsync interrupt processing, sound interrupt processing, and lamp interrupt processing, which will be described later, are interrupt processing (tasks) that can be executed in parallel at the same time by multitasking.
Here, Vsync interrupt processing, sound interrupt processing, and lamp interrupt processing may also be configured as interrupt processing executed by an interrupt handler.

(Sub CPU initialization processing)
First, the sub-CPU initialization process executed by the CPU 310 of the effect control board 300 will be described.
FIG. 38 is a flowchart showing sub CPU initialization processing.
A reset circuit (not shown) is arranged on the performance control board 300 . The reset circuit generates a reset signal when the pachinko machine 1 is powered on.
CPU310 of the production|presentation control board 300 starts the sub CPU initialization process shown in FIG. 38 according to generation|occurrence|production of the reset signal by a reset circuit.
When the sub CPU initialization process is started, first, the process moves to step S28-1.
In step S28-1, an initialization process is executed, and the process proceeds to step S28-2. In the initial setting process, various initial settings required for starting effect control are executed.
Specifically, in the initialization process, various registers and timers used by the CPU 310 are initialized to initialize the CPU 310 .
In the initialization process, various internal devices (CPU work memory 311, CPU interface 312, host interface 313, CG bus interface 314, DRAM interface 315, VRAM 316, serial communication controller 317, transfer circuit 318, preloader circuit 319, display circuit 320, graphics decoder circuit 321, drawing circuit 322, sound circuit 323, etc.) are initialized.
In particular, at this time, the value of the post-effector frequency correction parameter number register is initialized. As a result, a value (specifically, "0") designating the "normal post-effector frequency correction parameter" is set in the post-effector frequency correction parameter number register. As a result, the post-effector 360 thereafter performs frequency correction on the audio data of each channel according to the "normal post-effector frequency correction parameter".
Also, in the initialization process, various external devices (control ROM 302, CGROM 303, DRAM 304, etc.) are initialized. At this time, a value (“0” in this embodiment) is set in the initial transfer completion flag area of the DRAM 304 to designate a state in which an initial transfer, which will be described later, is not completed. In addition, a value (specifically, "0") specifying the "normal frequency correction parameter" is set in each frequency correction parameter number setting area (frequency correction parameter number setting area 1 to frequency correction parameter number setting area 3) of the DRAM 304.
Further, of the custom information storage areas, the first area stores (sets) information specifying custom content = "NO", the second area stores (sets) information specifying custom content = "OFF", the third area stores (sets) information specifying custom content = "OFF", the fourth area stores (sets) information specifying custom content = "default", and the fifth area stores (sets) information specifying custom content = "default". In the sixth area, information specifying custom content=“default” is stored (set).

In step S28-2, a material replacement offset setting process is executed, and the process proceeds to step S28-3. The material replacement offset setting process will be described later.
In step S28-3, an initial transfer data setting process is executed, and the process proceeds to step S28-4. In the initial transfer data setting process, information specifying data to be initially transferred is set.
Specifically, in the initial transfer data setting process, an initial transfer data list is set in a predetermined area of the DRAM 304, and a predetermined initial value (“0” in this embodiment) is set as the value of the data transfer counter.
The "initial transfer data list" is a list of data to be transferred (preloaded) from the CGROM 303 to the preload area of the DRAM 304 when power is turned on. In this embodiment, the initial transfer data list defines all compressed audio data among the data stored in the CGROM 303 as data to be transferred.
Specifically, in the initial transfer data list, for all the compressed audio data stored in the CGROM 303, information specifying the address of the storage area (storage area of the CGROM 303) from which each compressed audio data is read (hereinafter referred to as "read address"), information specifying the address of the storage area (storage area of the DRAM 304) to which the compressed audio data is written (hereinafter referred to as "write address"), and information specifying the order of transferring the compressed audio data (specifically, the value of the data transfer counter). , are registered.

At step S28-4, a digital amplifier setting process is executed, and the process proceeds to step S28-5. In the digital amplifier setting process, initial setting of the digital amplifier 305 is performed.
Specifically, in the digital amplifier setting process, first, a reset signal is transmitted to the digital amplifier 305 (the signal input to the reset terminal is turned on). As a result, in the digital amplifier 305, various registers (frequency correction parameter setting registers (frequency correction parameter setting unit 1, frequency correction parameter setting unit 2, and frequency correction parameter setting unit 3), volume setting (correction) register, terminal setting register, status information setting register, etc.) are initialized (cleared). At this time, a value (specifically, "0") corresponding to the normal state is set in the status information setting register.
In the digital amplifier setting process, next, “normal frequency correction parameters” (“normal frequency correction parameters 1” to “normal frequency correction parameters 3”) are transmitted to the digital amplifier 305 .
As a result, the “normal frequency correction parameter” is set in the frequency correction parameter setting register of the digital amplifier 305 . That is, "normal time/frequency correction parameter 1" is set in the frequency correction parameter setting unit 1, "normal time/frequency correction parameter 2" is set in the frequency correction parameter setting unit 2, and "normal time/frequency correction parameter 3" is set in the frequency correction parameter setting unit 3.
As a result, the digital amplifier 305 thereafter performs frequency correction on the audio data of channels 1 and 2 (upper left speaker and upper right speaker) according to the "normal frequency correction parameter 1", frequency correction of the audio data of channels 3 and 4 (middle left speaker and middle right speaker) according to the "normal frequency correction parameter 2", and frequency correction of the audio data of channel 5 (woofer) according to the "normal frequency correction parameter 3".

At step S28-5, an interrupt permission process is executed, and the process proceeds to step S28-6. In the interrupt permission processing, the interrupt disabled state is released. This enables (permits) the execution of various interrupt processes.
In step S28-6, random number update processing is executed, and the process proceeds to step S28-7. In the random number update process, random numbers for various effects are updated.
In step S28-7, an initial transfer process is executed, and the process proceeds to step S28-8. Initial transfer processing will be described later.

In step S28-8, status acquisition processing is executed, and the process proceeds to step S28-9. In the status information acquisition process, status information set in the status information setting register of the digital amplifier 305 is acquired.
In step S28-9, it is determined whether the status information acquired in step S28-8 is a value (specifically, "1") corresponding to an abnormal state. If it is determined that the acquired status information is a value corresponding to an abnormal state (Yes), the process proceeds to step S28-10.
In step S28-10, digital amplifier reset processing is executed, and the process proceeds to step S28-11. In the digital amplifier reset process, a reset signal is transmitted to the digital amplifier 305 (a signal input to the reset terminal of the digital amplifier 305 is turned on).
As a result, in the digital amplifier 305, various registers (frequency correction parameter setting registers (frequency correction parameter setting unit 1, frequency correction parameter setting unit 2, and frequency correction parameter setting unit 3), volume setting (correction) register, terminal setting register, status information setting register, etc.) are initialized (cleared). At this time, a value corresponding to the normal state (specifically, "0") is set in the status information setting register.

In step S28-11, parameter recovery processing is executed, and the process proceeds to step S28-6. In the parameter restoration process, based on the value set in the frequency correction parameter number setting area of the DRAM 304, the value of the frequency correction parameter setting register of the digital amplifier 305 is restored.
Specifically, in the parameter restoration process, first, the value of the frequency correction parameter number setting area 1 of the DRAM 304 is confirmed. Then, the frequency correction parameter corresponding to the value of the frequency correction parameter number setting area 1 is read from the control ROM 302 and the read frequency correction parameter is transmitted to the digital amplifier 305 .
Next, the value of frequency correction parameter number setting area 2 of DRAM 304 is checked. Then, it reads the frequency correction parameter corresponding to the value of the frequency correction parameter number setting area 2 from the control ROM 302 and transmits the read frequency correction parameter to the digital amplifier 305 .
Next, the value of frequency correction parameter number setting area 3 of DRAM 304 is checked. Then, the frequency correction parameter corresponding to the value of the frequency correction parameter number setting area 3 is read from the control ROM 302 and the read frequency correction parameter is transmitted to the digital amplifier 305 .

As a result, when the value of the frequency correction parameter number setting area 1 is "0", the "normal time/frequency correction parameter 1" is transmitted to the digital amplifier 305, and the "normal time/frequency correction parameter 1" is restored in the frequency correction parameter setting unit 1. On the other hand, when the value of the frequency correction parameter number setting area 1 is "1", the "jackpot/frequency correction parameter 1" is transmitted to the digital amplifier 305, and the "jackpot/frequency correction parameter 1" is restored in the frequency correction parameter setting unit 1. On the other hand, when the value of the frequency correction parameter number setting area 1 is "2", the "time saving/frequency correction parameter 1" is transmitted to the digital amplifier 305, and the "time saving/frequency correction parameter 1" is restored in the frequency correction parameter setting unit 1.
Further, when the value of the frequency correction parameter number setting area 2 is “0”, the “normal time/frequency correction parameter 2” is transmitted to the digital amplifier 305, and the “normal time/frequency correction parameter 2” is restored in the frequency correction parameter setting unit 2. On the other hand, when the value of the frequency correction parameter number setting area 2 is "1", the "jackpot/frequency correction parameter 2" is transmitted to the digital amplifier 305, and the "jackpot/frequency correction parameter 2" is restored in the frequency correction parameter setting unit 2. On the other hand, when the value of the frequency correction parameter number setting area 2 is "2", the "time saving/frequency correction parameter 2" is transmitted to the digital amplifier 305, and the "time saving/frequency correction parameter 2" is restored in the frequency correction parameter setting unit 2.
Further, when the value of the frequency correction parameter number setting area 3 is “0”, the “normal time/frequency correction parameter 3” is transmitted to the digital amplifier 305, and the “normal time/frequency correction parameter 3” is restored in the frequency correction parameter setting unit 3. On the other hand, when the value of the frequency correction parameter number setting area 3 is "1", the "jackpot/frequency correction parameter 3" is transmitted to the digital amplifier 305, and the "jackpot/frequency correction parameter 3" is restored in the frequency correction parameter setting unit 3. On the other hand, when the value of the frequency correction parameter number setting area 3 is "2", the "time saving/frequency correction parameter 3" is transmitted to the digital amplifier 305, and the "time saving/frequency correction parameter 3" is restored in the frequency correction parameter setting unit 3.

Next, the material replacement offset setting process in step S28-2 will be described.
FIG. 75 is a flowchart showing material replacement offset setting processing.
When the material replacement offset setting process is executed in step S28-2, as shown in FIG. 75, the process proceeds to step S45-1.
In step S45-1, first model determination bit data acquisition processing is executed, and the process proceeds to step S45-2. In the first model determination bit data acquisition process, the first model determination bit data is acquired. Specifically, the 4-bit data (first model determination bit data) stored in the four reception storage areas ma, mb, mc, and md are acquired.
In step S45-2, it is determined whether or not the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit A". If it is determined to be "decoration unit A" (Yes), the process proceeds to step S45-3, and if it is determined not to be "decoration unit A" (No), the process proceeds to step S45-4.
At this time, if the bit value corresponding to the reception storage area ma=“1” and the bit value corresponding to the reception storage areas mb, mc, md=“0” among the first model determination bit data (4 bits), it is determined that the type of the decoration unit DU attached to the front frame unit 4 is the “decoration unit A”, and in the other combination, it is determined that the decoration unit DU attached to the front frame unit 4 is not the “decoration unit A”.
In step S45-3, a value corresponding to "decorative unit A"("0" in this embodiment) is set as the first material replacement offset value in the first material replacement offset storage area, and the process proceeds to step S45-11.

In step S45-4, it is determined whether or not the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit B". If it is determined to be "decoration unit B" (Yes), the process proceeds to step S45-5, and if it is determined not to be "decoration unit B" (No), the process proceeds to step S45-6.
At this time, if the bit value corresponding to the reception storage area mb=“1” and the bit value corresponding to the reception storage areas ma, mc, md=“0” among the first model determination bit data (4 bits), the type of the decoration unit DU attached to the front frame unit 4 is determined to be the “decoration unit B”, and in the other combination, the type of the decoration unit DU attached to the front frame unit 4 is determined not to be the “decoration unit B”.
In step S45-5, a value corresponding to "decorative unit B"("1" in this embodiment) is set as the first material replacement offset value in the first material replacement offset storage area, and the process proceeds to step S45-11.

In step S45-6, it is determined whether or not the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit C". If it is determined to be "decoration unit C" (Yes), the process proceeds to step S45-7, and if it is determined not to be "decoration unit C" (No), the process proceeds to step S45-8.
At this time, when the bit value corresponding to the reception storage area mc is "1" and the bit value corresponding to the reception storage areas ma, mb, md is "0" among the first model determination bit data (4 bits), it is determined that the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit C".
In step S45-7, a value corresponding to "decorative unit C"("2" in this embodiment) is set as the first material replacement offset value in the first material replacement offset storage area, and the process proceeds to step S45-11.

In step S45-8, it is determined whether or not the type of the decoration unit DU attached to the front frame unit 4 is "decoration unit D". If it is determined to be "decoration unit D" (Yes), the process proceeds to step S45-9, and if it is determined not to be "decoration unit D" (No), the process proceeds to step S45-10.
At this time, if the bit value corresponding to the receiving storage area md=“1” and the bit value corresponding to the receiving storage areas ma, mb, mc=“0” among the first model determination bit data (4 bits), the type of the decoration unit DU attached to the front frame unit 4 is determined to be the “decoration unit D”, and in the other combination, the type of the decoration unit DU attached to the front frame unit 4 is determined not to be the “decoration unit D”.
In step S45-9, a value corresponding to "decorative unit D"("3" in this embodiment) is set as the first material replacement offset value in the first material replacement offset storage area, and the process proceeds to step S45-11.
In step S45-10, error setting processing is executed, and the process proceeds to step S45-11. In the error setting process, notification of an abnormal state is started (set). Specifically, the display screen 31 a of the main image display device 31 starts displaying (sets) information indicating that the attachment of the decoration unit DU to the front frame unit 4 is incomplete.

In step S45-11, a second model determination bit data acquisition process is executed, and the process proceeds to step S45-12. In the second model determination bit data acquisition process, the second model determination bit data is acquired. Specifically, the 4-bit data (second model determination bit data) stored in the four reception storage areas me, mf, mg, and mh are obtained.
In step S45-12, it is determined whether or not the type of the saucer unit SU attached to the front frame unit 4 is "saucer unit A". If it is determined to be "saucer unit A" (Yes), the process proceeds to step S45-13, and if it is determined not to be "saucer unit A" (No), the process proceeds to step S45-14.
At this time, if the bit value corresponding to the reception storage area me = "1" and the bit value corresponding to the reception storage areas mf, mg, mh = "0" in the second model determination bit data (4 bits), it is determined that the type of the saucer unit SU attached to the front frame unit 4 is "sauce unit A".
In step S45-13, as the second material replacement offset value in the second material replacement offset storage area, a value (in this embodiment, "0") corresponding to "pan unit A" is set, the series of processes is terminated, and the process proceeds to the next process (step S28-3).

In step S45-14, it is determined whether or not the type of the saucer unit SU attached to the front frame unit 4 is "saucer unit B". If it is determined to be "saucer unit B" (Yes), the process proceeds to step S45-15, and if it is determined not to be "saucer unit B" (No), the process proceeds to step S45-16.
At this time, if the bit value corresponding to the reception storage area mf = "1" and the bit value corresponding to the reception storage areas me, mg, mh = "0" in the second model determination bit data (4 bits), it is determined that the type of the saucer unit SU attached to the front frame unit 4 is "sauce unit B".
In step S45-15, as the second material replacement offset value in the second material replacement offset storage area, a value (in this embodiment, "1") corresponding to "pan unit B" is set, the series of processes is terminated, and the process proceeds to the next process (step S28-3).

In step S45-16, it is determined whether or not the type of the saucer unit SU attached to the front frame unit 4 is "saucer unit C". If it is determined to be "saucer unit C" (Yes), the process proceeds to step S45-17, and if it is determined not to be "saucer unit C" (No), the process proceeds to step S45-18.
At this time, if the bit value corresponding to the reception storage area mg = "1" and the bit value corresponding to the reception storage areas me, mf, mh = "0" in the second model determination bit data (4 bits), it is determined that the type of the saucer unit SU attached to the front frame unit 4 is "sauce unit C".
In step S45-17, as the second material replacement offset value in the second material replacement offset storage area, a value (in this embodiment, "2") corresponding to "pan unit C" is set, and the series of processes is terminated, and the process proceeds to the next process (step S28-3).

In step S45-18, it is determined whether or not the type of the saucer unit SU attached to the front frame unit 4 is "saucer unit D". If it is determined to be "saucer unit D" (Yes), the process proceeds to step S45-19, and if it is determined not to be "saucer unit D" (No), the process proceeds to step S45-20.
At this time, if the bit value corresponding to the reception storage area mh = "1" and the bit value corresponding to the reception storage areas me, mf, mg = "0" in the second model determination bit data (4 bits), it is determined that the type of the saucer unit SU attached to the front frame unit 4 is "sauce unit D", and in the other combination, the type of the saucer unit SU attached to the front frame unit 4 is determined not to be "saucer unit D".
In step S45-19, as the second material replacement offset value in the second material replacement offset storage area, a value (in this embodiment, "3") corresponding to "pan unit D" is set, the series of processes is terminated, and the process proceeds to the next process (step S28-3).
In step S45-20, an error setting process is executed, a series of processes is completed, and the process proceeds to the next process (step S28-3). In the error setting process, notification of an abnormal state is started (set). Specifically, the display screen 31a of the main image display device 31 starts displaying (sets) information indicating that the attachment of the receiving tray unit SU to the front frame unit 4 is incomplete.

(Initial transfer processing)
Next, the initial transfer processing in step S28-7 will be described.
FIG. 39 is a flowchart showing initial transfer processing.
When the initial transfer process is executed in step S28-7, as shown in FIG. 39, the process proceeds to step S44-1.
In step S44-1, it is determined whether or not the value set in the initial transfer completion flag area is "1", and if it is determined that the value set in the initial transfer completion flag area is not "1" (is "0") (No), the process proceeds to step S44-2.

In step S44-2, SATA transfer processing is executed, and the process proceeds to step S44-3. In the SATA transfer process, data stored in the CGROM 303 is transferred (preloaded) to the preload area of the DRAM 304 according to the initial transfer data list set in step S28-1.
Specifically, in the SATA transfer process, first, the value of the data transfer counter is checked. Next, the initial transfer data list is referenced to obtain the read address and write address corresponding to the confirmed data transfer counter value. Then, the data (compressed audio data) stored in the storage area specified by the acquired read data address is read, and the read data (compressed image data) is stored in the storage area specified by the acquired write address.
In the SATA transfer process, next, "1" is added to the value of the data transfer counter.

In step S44-3, it is determined whether or not the initial transfer has been completed. If it is determined that the initial transfer has been completed (Yes), the process proceeds to step S44-4.
Here, in step S44-3, based on the value of the data transfer counter, it is determined whether transfer of all data registered in the initial transfer data list has been completed. When it is determined that the transfer of all the data registered in the initial transfer data list is completed, it is determined that the initial transfer is completed, and when it is determined that the transfer of all the data registered in the initial transfer data list is not completed, it is determined that the initial transfer is not completed.
In step S44-4, an initial transfer completion flag setting process is executed, a series of processes is terminated, and the process proceeds to the next process (step S28-8). In the initial transfer completion flag setting process, a value (“1” in this embodiment) that designates the state in which the initial transfer is completed is set in the initial transfer completion flag area.

As described above, the initial transfer completion flag area is set to "0" during the period from the execution of the initial setting process until the transfer (initial transfer) of all the data registered in the initial transfer data list (all the compressed audio data stored in the CGROM 303) is completed. Then, the SATA transfer process of step S44-2 is repeatedly executed while "0" is set in the initial transfer completion flag area.
After that, when the transfer (initial transfer) of all the data registered in the initial transfer data list (all the compressed audio data stored in the CGROM 303) is completed, "1" is set in the initial transfer completion flag area.
In particular, in the present embodiment, when "1" is set in the initial transfer completion flag area, a state is generated in which control of audio output by the various speakers 22 (audio output processing by the sound circuit 323) and control of display of effect images by the various image display devices 31 and 32 (drawing processing by VDP) can be executed.
That is, when "0" is set in the initial transfer completion flag area, it becomes impossible to control the output of sound by the various speakers 22 (sound output processing by the sound circuit 323) and control the display of effect images by the various image display devices 31 and 32 (drawing processing by VDP).
On the other hand, when "1" is set in the initial transfer completion flag area, it becomes possible to control the output of sound by the various speakers 22 (sound output processing by the sound circuit 323) and control the display of effect images by the various image display devices 31 and 32 (drawing processing by VDP).
On the other hand, in the present embodiment, before the transfer of all the data registered in the initial transfer data list (all the compressed audio data stored in the CGROM 303) is completed (before the initial transfer completion flag area is set to "1"), a state occurs in which control of driving (emission) of the various lamps 20 and 21 (lamp driving processing by the lamp controller 317a) and control of driving the various motors 23 (various movable bodies) (motor driving processing by the motor controller 317b) can be executed. .
That is, after the initialization process is executed, in response to the permission to execute various interrupt processes, a state is generated in which control of driving (light emission) of various lamps 20 and 21 (lamp driving process by lamp controller 317a) and control of driving of various motors 23 (various movable bodies) (motor driving process by motor controller 317b) can be executed.

(Command reception interrupt processing)
Next, command reception interrupt processing executed by the CPU 310 of the effect control board 300 will be described.
The CPU 310 of the effect control board 300 executes command reception interrupt processing (not shown) in response to reception of a control command from the main control board 200 .
In the command reception interrupt process, the control command received from the main control board 200 is stored (stored) in the reception buffer area of the DRAM 304 of the effect control board 300 .

(Sub timer interrupt processing)
Next, sub-timer interrupt processing executed by the CPU 310 of the effect control board 300 will be described.
FIG. 40 is a flowchart showing sub timer interrupt processing.
The effect control board 300 is configured including a clock generation circuit. A clock generation circuit generates a clock pulse signal at predetermined intervals.
The CPU 310 of the effect control board 300 starts sub timer interrupt processing shown in FIG. 40 at predetermined intervals based on the generation of clock pulses by the clock generation circuit. When the sub timer interrupt process is started, first, the process moves to step S31-1.
In step S31-1, register saving processing is executed, and the process proceeds to step S31-2. In the register saving process, the value of the register is saved in the saving area of the DRAM 304 .

In step S31-2, timer update processing is executed, and the process proceeds to step S31-3. In the timer update process, values of various timers (effect scenario timer, etc.) included in the effect control board 300 are updated. Specifically, a predetermined value (a value corresponding to a predetermined period) is added or subtracted from the values of various timers.
In step S31-3, command analysis processing is executed, and the process proceeds to step S31-4. In the command analysis process, the control command stored in the reception buffer of the DRAM 304 of the effect control board 300 is analyzed, and the process corresponding to the received control command is executed. The command analysis processing will be described later.

In step S31-4, time schedule management processing is executed, and the process proceeds to step S31-5. In the time schedule management process, the progress of production is managed based on the production scenario data set in the production scenario setting area and the value of the production scenario timer corresponding to the production scenario data.
Specifically, in the time schedule management process, it is determined whether or not there is process data whose start time has come for each of the production scenario data set in the production scenario setting area. When it is determined that there is process data whose start time has come, each instruction information (message) included in the process data is stored (stored) in the corresponding buffer area.
At this time, command information regarding the display effect (command information specifying the start of the display effect, command information specifying the end of the display effect, etc.) is stored in the display command buffer area.
On the other hand, the command information regarding the sound effect (command information specifying the start of the sound effect, etc.) is stored in the sound command buffer area.
On the other hand, the command information (command information specifying the start of the lamp effect, etc.) related to the lamp effect is stored in the lamp command buffer area.
On the other hand, the command information (command information specifying the start of the movable body presentation, etc.) related to the movable body presentation is stored in the movable body command buffer area.

In step S31-5, register return processing is executed, and the sub timer interrupt processing ends. In the register restoration process, the value of the register saved in step S31-1 is restored.

(Command analysis processing)
Next, the command analysis processing in step S31-3 will be described.
FIG. 41 is a flowchart showing command analysis processing.
When the command analysis process is executed in step S31-3, as shown in FIG. 41, the process proceeds to step S32-1.
In step S32-1, a set value command reception process is executed, and the process proceeds to step S32-2.
In the setting value command reception process, it is determined whether or not a setting value specifying command has been received. And when it determines with having received the setting value designation|designated command, the value corresponding to the setting value which the said setting value designation|designated command designates is memorize|stored in the setting value storage area|region of DRAM304 of the production|presentation control board 300.

In step S32-2, a game state command reception process is executed, and the process proceeds to step S32-3.
In the game state command reception process, it is determined whether or not a game state designation command has been received. Then, when it is determined that the game state designation command has been received, various production flags are set.
In step S32-3, a pending command reception process is executed, and the process proceeds to step S32-4. The pending command reception process will be described later.
In step S32-4, prefetch command reception processing is executed, and the process proceeds to step S32-5. The prefetch command reception processing will be described later.
In step S32-5, variation command reception processing is executed, and the process proceeds to step S32-6. Variation command reception processing will be described later.
In step S32-6, a stop command reception process is executed, and the process proceeds to step S32-7. The stop command reception process will be described later.
In step S32-7, an opening command reception process is executed, and the process proceeds to step S32-8. The opening command reception processing will be described later.

At step S32-8, a game status command reception process is executed, a series of processes is terminated, and the process proceeds to the next process (step S31-4).
In the game situation command reception process, first, it is determined whether or not a game situation designation command has been received. Then, when it is determined that the game situation designation command has been received, a game situation setting process, which will be described later, is executed. On the other hand, if it is determined that the game situation designation command has not been received, the process proceeds to the next process (step S31-4) without executing the game situation setting process.
In the game situation setting process, the game situation designation command is analyzed.
Then, when generation of the ready-to-fire state is designated by the game state designation command, a value (for example, "1") designating that the ready-to-fire state is occurring is set in the game state flag area of the DRAM 304 of the performance control board 300.例文帳に追加In addition, an effect is started that suggests (informs) that the state of being ready to be fired is occurring.
On the other hand, when the release of the ready-to-fire state is designated by the game state designation command, a value (for example, "0") designating that the ready-to-fire state is being released is set in the game state flag area of the DRAM 304 of the performance control board 300.例文帳に追加In addition, the effect of suggesting (notifying) that the state of being ready to be fired is occurring is ended.

(Hold command reception processing)
Next, the pending command reception process of step S32-3 will be described.
FIG. 42 is a flowchart showing pending command reception processing.
When the hold command reception process is executed in step S32-3, as shown in FIG. 42, the process proceeds to step S36-1.
In step S36-1, it is determined whether or not the pending number designation command has been received, and if it is determined that the pending number designation command has been received (Yes), the process proceeds to step S36-2, and the pending number designation command is not received.
In step S36-2, it is determined whether the hold number designation command specifies an increase in the hold number (the hold number is increased by "1"), and if it is determined that the hold number designation command specifies an increase in the hold number (Yes), the process proceeds to step S36-3, and if it is determined that the hold number designation command does not specify an increase in the hold number (specifies that the hold number is decreased by "1"), the process proceeds to step S36-4.

In step S36-3, a pending number addition process is executed, a series of processes is terminated, and the process proceeds to the next process (step S32-4).
In the pending number addition process, first, it is determined whether or not the pending number designation command designates an increase in the special figure 1 pending number.
When it is determined that the reserved number designation command designates an increase in the special figure 1 reserved number, a value obtained by adding "1" to the value set in the special figure 1 reserved number counter is newly set in the special figure 1 reserved number counter. In addition, the normal pending effect corresponding to the newly acquired (stored) special figure 1 game information is started.
At this time, as a display area for displaying the reserved pattern h, among the four display positions included in the reserved pattern display area b2, the display position corresponding to the storage area (storage area 1 to storage area 4) storing the newly acquired special figure 1 game information is set. Here, the storage area (storage area 1 to storage area 4) in which the newly acquired special figure 1 game information is stored is determined based on the value of the special figure 1 pending number counter.

On the other hand, when it is determined that the reservation number designation command designates an increase in the special figure 2 reservation number, a value obtained by adding "1" to the value set in the special figure 2 reservation number counter is newly set in the special figure 2 reservation number counter. In addition, the normal pending effect corresponding to the newly acquired (stored) special figure 2 game information is started.
At this time, as a display area for displaying the reserved pattern h, among four display positions included in the reserved pattern display area b3, a storage area (storage area 1 to storage area 4) in which the newly acquired special figure 2 game information is stored is set. Here, the storage area (storage area 1 to storage area 4) in which the newly acquired special figure 2 game information is stored is determined based on the value of the special figure 2 reservation number counter.

In step S36-4, a reservation number subtraction process is executed, a series of processes is terminated, and the process proceeds to the next process (step S32-4).
In the reservation number subtraction process, first, it is determined whether or not the reservation number designation command specifies the subtraction of the special figure 1 reservation number.
When it is determined that the reserved number designation command designates the subtraction of the special figure 1 reserved number, the value obtained by subtracting "1" from the value set in the special figure 1 reserved number counter is newly set in the special figure 1 reserved number counter. Also, the display position of each reserved design h displayed in the reserved design display area b2 is shifted (moved).
Specifically, the pending effect corresponding to the pending symbol h displayed in the pending symbol display area b1 is ended. As a result, the display of the reserved pattern h corresponding to the finished reserved effect is ended.
Further, when the reserved pattern h is displayed at the display position corresponding to the storage area 1 in the reserved pattern display area b2, the display position of the reserved pattern h is shifted from the reserved pattern display area b2 (display position corresponding to the storage area 1) to the reserved pattern display area b1.
When the reserved pattern h is displayed at the display position corresponding to the storage area 2 in the reserved pattern display area b2, the display position of the reserved pattern h is shifted from the display position corresponding to the storage area 2 to the display position corresponding to the storage area 1.
When the reserved pattern h is displayed at the display position corresponding to the storage area 3 in the reserved pattern display area b2, the display position of the reserved pattern h is shifted from the display position corresponding to the storage area 3 to the display position corresponding to the storage area 2.
When the reserved pattern h is displayed at the display position corresponding to the storage area 4 in the reserved pattern display area b2, the display position of the reserved pattern h is shifted from the display position corresponding to the storage area 4 to the display position corresponding to the storage area 3.

On the other hand, when it is determined that the reserved number designation command designates the subtraction of the special figure 2 reserved number, the value obtained by subtracting "1" from the value set in the special figure 2 reserved number counter is newly set in the special figure 2 reserved number counter. Also, the display position of each reserved design h displayed in the reserved design display area b3 is changed (shifted).
Specifically, the pending effect corresponding to the pending symbol h displayed in the pending symbol display area b1 is ended. As a result, the display of the reserved pattern h corresponding to the finished reserved effect is terminated.
Further, when the reserved pattern h is displayed at the display position corresponding to the storage area 1 in the reserved pattern display area b3, the display position of the reserved pattern h is shifted from the reserved pattern display area b3 (display position corresponding to the storage area 1) to the reserved pattern display area b1.
When the reserved pattern h is displayed at the display position corresponding to the storage area 2 in the reserved pattern display area b3, the display position of the reserved pattern h is shifted from the display position corresponding to the storage area 2 to the display position corresponding to the storage area 1.
When the reserved pattern h is displayed at the display position corresponding to the storage area 3 in the reserved pattern display area b3, the display position of the reserved pattern h is shifted from the display position corresponding to the storage area 3 to the display position corresponding to the storage area 2.
When the reserved pattern h is displayed at the display position corresponding to the storage area 4 in the reserved pattern display area b3, the display position of the reserved pattern h is shifted from the display position corresponding to the storage area 4 to the display position corresponding to the storage area 3.

(Prefetch command reception processing)
Next, the prefetch command reception processing in step S32-4 will be described.
FIG. 43 is a flowchart showing prefetch command reception processing.
When the prefetch command reception process is executed in step S32-4, as shown in FIG. 43, the process proceeds to step S33-1.
In step S33-1, it is determined whether or not a prefetching designation command (a first prefetching designation command, a second prefetching designation command, and a third prefetching designation command) has been received. If it is determined that a prefetching designation command has been received (Yes), the process proceeds to step S33-2.

In step S33-2, prefetch information analysis processing is executed, and the process proceeds to step S33-3. In the look-ahead information analysis process, the information specified by the look-ahead specification command is stored in a predetermined area of the DRAM 304 of the effect control board 300 as pending information.
A suspension information storage area capable of storing suspension information is set in the DRAM 304 of the effect control board 300 . In addition, as the reservation information storage area, a first reservation information storage area corresponding to the first special symbol lottery (special figure 1 game information storage area of RAM 230) and a second reservation information storage area corresponding to the second special symbol lottery (special figure 2 game information storage area of RAM 230) are set.
The first pending information storage area includes storage areas 1 to 4 as storage areas capable of storing pending information. And, in the first pending information storage area, pending information corresponding to the special figure 1 game information stored in the special figure 1 game information storage area is stored. That is, the pending information stored in the storage area 1 of the first pending information storage area corresponds to the special figure 1 game information stored in the storage area 1 of the special figure 1 game information storage area. Further, the pending information stored in the storage area 2 of the first pending information storage area corresponds to the special figure 1 game information stored in the storage area 2 of the special figure 1 game information storage area. Further, the pending information stored in the storage area 3 of the first pending information storage area corresponds to the special figure 1 game information stored in the storage area 3 of the special figure 1 game information storage area. Further, the pending information stored in the storage area 4 of the first pending information storage area corresponds to the special figure 1 game information stored in the storage area 4 of the special figure 1 game information storage area.
The second pending information storage area includes storage areas 1 to 4 as storage areas capable of storing pending information. And, in the second pending information storage area, pending information corresponding to the special figure 2 game information stored in the special figure 2 game information storage area is stored. That is, the pending information stored in the storage area 1 of the second pending information storage area corresponds to the special figure 2 game information stored in the storage area 1 of the special figure 2 game information storage area. Further, the pending information stored in the storage area 2 of the second pending information storage area corresponds to the special figure 2 game information stored in the storage area 2 of the special figure 2 game information storage area. Further, the pending information stored in the storage area 3 of the second pending information storage area corresponds to the special figure 2 game information stored in the storage area 3 of the special figure 2 game information storage area. Further, the pending information stored in the storage area 4 of the second pending information storage area corresponds to the special figure 2 game information stored in the storage area 4 of the special figure 2 game information storage area.
Each reserved information includes symbol information indicating the type of the stopped symbol, first variation information indicating the content of the variation mode (“variation mode number” or “undefined value”), and second variation information indicating the content of the variation pattern (“variation pattern number” or “undefined value”).

In the look-ahead information analysis process, first, it is determined whether or not the received first look-ahead designation command corresponds to the first special symbol lottery.
Then, when it is determined that the received first prefetching designation command corresponds to the first special symbol lottery, the type of the stop design specified by the first prefetching designation command ("loss pattern" or "jackpot p design"), the content of the variation mode specified by the second prefetching specification command ("variation mode m" or "undefined value"), and the content of the variation pattern specified by the third prefetching specification command ("variation pattern n" or "undefined value") are analyzed, Reserved information including pattern information corresponding to the type of the analyzed stop pattern, first variation information corresponding to the content of the analyzed variation mode, and second variation information corresponding to the content of the analyzed variation pattern is generated. Then, the generated pending information is stored (saved) in the first pending information storage area.
On the other hand, when it is determined that the received first prefetching designation command corresponds to the second special symbol lottery, the type of stop design specified by the first prefetching designation command ("loss pattern" or "jackpot p design"), the content of the variation mode specified by the second prefetching specification command ("variation mode m" or "undefined value"), and the content of the variation pattern specified by the third prefetching specification command ("variation pattern n" or "undefined value") are analyzed, Reserved information including pattern information corresponding to the type of the analyzed stop pattern, first variation information corresponding to the content of the analyzed variation mode, and second variation information corresponding to the content of the analyzed variation pattern is generated. Then, the generated pending information is stored (saved) in the second pending information storage area.
In the following description, the pending information stored in the pending information storage area in step S33-2 is referred to as "prefetch target pending information". In addition, among the pending information stored in the first pending information storage area, the pending information whose notification display (variable display and stop display) is executed prior to the prefetch target pending information is referred to as "preceding pending information".

In step S33-3, it is determined whether or not the pre-reading notice performance is being executed, and if it is determined that the pre-reading notice performance is not being executed (No), the process proceeds to step S33-4, and if it is determined that the pre-reading notice performance is being executed (Yes), a series of processing is terminated and the next processing (step S32-5) is performed.
In this embodiment, "1" is set in the flag area of the DRAM 304 of the effect control board 300 during execution of the pre-reading notice effect. Therefore, in step S33-3, it is determined whether or not the pre-reading notice effect is being executed based on whether or not "1" is set in the pre-reading notice effect in-progress flag area.
In step S33-4, it is determined whether or not the pre-reading notice performance execution condition is satisfied, and if it is determined that the pre-reading notice performance execution condition is satisfied (Yes), the process proceeds to step S33-5, and if it is determined that the pre-reading notice performance execution condition is not satisfied (No), a series of processing is terminated and the next processing (step S32-5) is performed.
In the present embodiment, it is determined that the pre-reading notice effect execution conditions are satisfied when all of the following conditions are satisfied: (1) a predetermined number (“2” in this embodiment) of preceding pending information is stored; (2) there is no preceding pending information indicating a type (variation pattern number) belonging to “normal reach fluctuation” or “super reach fluctuation” as the type of variation pattern; and (3) a jackpot gaming state is not occurring.
It should be noted that the content of the look-ahead advance notice effect execution condition can be changed as appropriate. That is, it may be determined that the pre-reading notice effect execution conditions are met when one or more of the conditions (1) to (3) are met instead of all the conditions (1) to (3). Further, conditions different from the above conditions (1) to (3) may be included as conditions for executing the pre-reading advance notice effect. As other conditions, for example, it is possible to define that (4) the prefetch target hold information is the hold information corresponding to the special figure 1 game information, (5) that the time saving control is stopped, and the like.

In step S33-5, a pre-reading notice effect lottery process is executed, and the process proceeds to step S33-6. In the pre-reading notice effect lottery process, a pre-reading notice effect lottery is executed for determining whether or not to execute the pre-reading notice effect lottery.
A control ROM 302 of the performance control board 300 stores a pre-reading notice effect lottery table in which winning values of the pre-reading notice effect lottery are registered.
In the pre-reading notice effect lottery process, first, the reserved notice appearance designation information stored in the reserved notice appearance designation information setting area is confirmed. Then, when the non-appearance designation information is set in the reserved notice appearance designation information setting area, the prefetch notice effect lottery is not executed (it is decided not to execute the prefetch notice effect). On the other hand, when the appearance designation information is set in the pending notice appearance designation information setting area, a pre-reading notice effect lottery is executed.
In the pre-reading notice effect lottery, first, a pre-reading notice effect lottery random number is acquired from a predetermined random number counter. Then, it is determined whether or not to execute the pre-reading advance notice effect, based on the obtained pre-reading notice effect lottery random number and the pre-reading notice effect lottery table. At this time, when the obtained lottery random number for foretelling performance matches the winning value (winning), it is decided to execute the foretelling foretelling performance, and when the obtained lottery random number for reading foretelling performance does not match the winning value (lost), it is decided not to perform the foretelling foretelling performance.
In step S33-6, it is determined whether or not the pre-reading notice effect lottery executed in step S33-5 is won, and if it is determined that the pre-reading notice effect lottery is won (Yes), the process proceeds to step S33-7, and if it is determined that the pre-reading notice effect lottery is lost (No), a series of processing is terminated and the next process (step S32-5) is performed.

At step S33-7, a pre-reading notice effect setting process is executed, a series of processes is terminated, and the process proceeds to the next process (step S32-5). In the pre-reading notice effect setting process, the content of the pre-reading notice effect (holding notice effect) is set.
Specifically, in the look-ahead advance notice effect setting process, first, the pending final mode selection process is executed. In the final pending mode selection process, the final pending mode is selected and set.
“Final Suspension Mode” refers to the mode of the notice object pending symbol hy that finally changes in the pending notice performance.
The control ROM 302 of the effect control board 300 stores a final pending color lottery table in which the correspondence between the final pending mode lottery random number and the final pending mode is registered.
In addition, as the final holding mode lottery table, the final holding mode lottery table corresponding to each type of variation pattern is stored.
In the final pending mode selection process, first, a final pending mode lottery random number is obtained from a predetermined random number counter. Further, the type of variation pattern indicated by the prefetch target suspension information is confirmed, and the suspension final mode lottery table corresponding to this confirmation result is read. Then, a final pending mode is selected (determined) based on the acquired final pending mode lottery random number and the read final pending mode lottery table.

In the look-ahead notice effect setting process, next, a pending change opportunity selection process is executed. In the pending change trigger selection process, a pending change trigger is selected and set.
The control ROM 302 of the performance control board 300 stores a hold change opportunity lottery table in which correspondence between a hold change opportunity lottery random number and a hold change pattern is registered.
The "holding change pattern" is information (scenario data) specifying a combination of holding change triggers.
In addition, as a hold change opportunity lottery table, a hold change opportunity lottery table corresponding to each combination of the special figure 1 hold number ("2" to "4") and the hold final mode is stored.
In the pending change opportunity selection process, first, a pending change opportunity lottery random number is obtained from a predetermined random number counter. In addition, the special figure 1 reservation number and the reservation final mode selected in the reservation final mode selection process are confirmed, and the reservation change opportunity lottery table corresponding to this confirmation result is read. Then, based on the acquired pending change opportunity lottery random number and the read pending change opportunity lottery table, the pending notice performance number is determined (judged). Then, the performance scenario data corresponding to the determined pending notice performance number is read, and the performance scenario data thus read and the performance scenario timer corresponding to the performance scenario data are set in the performance scenario area.

In the look-ahead notice effect setting process, next, a pending change content selection process is executed. In the pending change content selection process, the pending change content corresponding to each pending change trigger is selected and set.
Specifically, in the pending change content selection process, as the pending change content corresponding to each pending change opportunity, the mode of the notice subject pending pattern hy before the change and the mode of the notice subject pending pattern hy after the change are set.
In the present embodiment, of the one or more hold change triggers set in the hold change trigger selection process, the hold change content corresponding to each hold change trigger is selected in order from the hold change trigger that arrives (occurs later) (later hold change trigger).
For example, when 3 [time] hold change triggers are set in the hold change trigger selection process, the hold change contents corresponding to each hold change trigger are selected in the order of the third (final) hold change trigger, the second hold change trigger, and the first hold change trigger.
Further, when selecting the content of pending change corresponding to the pending change opportunity of each time, first, the mode of the notice subject pending pattern hy after the change is selected, and then the mode of the notice subject pending pattern hy before the change is selected. At this time, as the mode of the notice target reserved design hy before the change, a mode with a lower degree of expectation than the mode of the notice target reserved design hy after the change is determined. As a result, the mode of the notice target retained pattern hy changes (promotes) to a mode with a high degree of expectation in accordance with the arrival of each pending change opportunity.
A control ROM 302 of a performance control board 300 stores a pending change content lottery table in which correspondence between a pending change content lottery random number and a state of a notice target pending symbol hy before change is registered.
Further, as a pending change content lottery table, a pending change content lottery table corresponding to each mode of the pending pattern h (mode of the notice subject pending pattern hy after change) is stored.
Then, in the reservation change content lottery table corresponding to each mode of the reserved pattern h (mode of the notice subject reserved pattern hy after change), as the form of the notice subject reserved pattern hy before change, only a mode with a low degree of expectation compared with the mode of the notice subject reserved pattern hy after change is registered.
In the pending change content selection process, first, among the pending change triggers set in the pending change trigger selection process, the pending change details are selected for the final pending change trigger. For this, first, the mode of the notice subject pending symbol hy after the change related to the final pending change trigger is selected. At this time, the final pending mode selected in the final pending mode selection process is selected as the mode of the notice target pending pattern hy after the change related to the final pending change opportunity. Next, the mode of the notice subject pending symbol hy before the change related to the final pending change opportunity is selected. For this, first, a pending change content lottery random number is obtained from a predetermined random number counter. Further, the holding change content lottery table corresponding to the form of the notice target holding pattern hy after the change selected for the holding change opportunity of the final round is read. Then, based on the obtained pending change content lottery random number and the read pending change content lottery table, the state of the pre-notification target pending symbol hy related to the final pending change trigger is selected.
In the pending change content selection process, next, the pending change contents are selected for each pending change opportunity excluding the final pending change opportunity among the pending change opportunities set in the pending change opportunity selection process. At this time, the hold change contents corresponding to each hold change opportunity are determined in order from the hold change opportunity that arrives later.
In order to determine the content of the pending change corresponding to each pending change opportunity, first, the aspect of the notice subject pending pattern hy after the change related to the relevant pending change opportunity is determined. At this time, the mode of the pre-change notice subject reserved pattern hy already selected for the next pending change opportunity is selected as the mode of the notice subject reserved pattern hy after change related to the current pending change opportunity. Next, the aspect of the notice object pending symbol hy before the change related to the present pending change opportunity is determined. For this, first, a pending change content lottery random number is obtained from a predetermined random number counter. Further, the holding change content lottery table corresponding to the mode of the notice target holding pattern hy after the change selected for the current holding change opportunity is read. Then, based on the obtained pending change content lottery random number and the read pending change content lottery table, the aspect of the pre-notification subject pending symbol hy related to the present pending change opportunity is selected.
In the pending change content selection process, next, the pending change content selected for each pending change opportunity is set in the area corresponding to the pending change opportunity in the production scenario setting area. Thereby, according to the arrival of each hold change opportunity, the state of the notice target hold pattern hy is changed (promoted) according to the hold change contents set for the hold change opportunity.

In the pre-reading notice effect setting process, next, “1” is set in the pre-reading notice effect in-progress flag area of the DRAM 304 of the effect control board 300 .
As described above, the suspension notice effect is started.
It is to be noted that "0" is set to the flag area during pre-reading notice effect according to the end of the pending notice effect by a process (not shown).

(variation command reception processing)
Next, the variation command reception process of step S32-5 will be described.
FIG. 44 is a flow chart showing a variation command reception process.
When the variation command reception process is executed in step S32-5, as shown in FIG. 44, the process proceeds to step S34-1.
In step S34-1, it is determined whether or not a predetermined control command has been received. If it is determined that a predetermined control command has been received (Yes), the process proceeds to step S34-2.
Here, the predetermined control command refers to a symbol type designation command, a variation mode designation command and a variation pattern designation command.
In step S34-2, stop effect determination processing is executed, and the process proceeds to step S34-3. In the stop effect determination process, a stop effect number (mode of stop effect) is determined.
Specifically, in the stop effect determination process, a stop effect number (mode of stop effect) is determined based on the type of stop symbol specified by the symbol type designation command. Then, the determined stop effect number is stored in the stop effect number storage area of the DRAM 304 of the effect control board 300 .

In step S34-3, a variable effect determination process is executed, and the process proceeds to step S34-4. In the variable effect determination process, a variable effect number (mode of variable effect) is determined.
Concretely, in fluctuation production decision processing, first, first half fluctuation production decision processing which decides the first half fluctuation production number (mode of first half fluctuation production) is executed.
A control ROM 302 of a performance control board 300 stores a first half variation performance lottery table in which correspondence between a variation mode number (type of variation mode) and a first half variation performance number (mode of first half variation performance) is registered.
In the first half variation performance determination process, first, the first half variation performance lottery table is read. Then, among the first half variation performance numbers registered in the first half variation performance lottery table, the first half variation performance number corresponding to the variation mode number specified by the variation mode designation command is determined (selected).

In the variable effect determination process, next, the second half variable effect determination process for determining the second half variable effect number (mode of the second half variable effect) is executed.
A control ROM 302 of a performance control board 300 stores a second half variable performance lottery table in which correspondence between a variation pattern number (variation pattern type) and a second half variable performance number (mode of second half variable performance) is registered.
In the second half variation performance determination process, first, the second half variation performance lottery table is read. Then, out of the second half variation performance numbers registered in the second half variation performance lottery table, the second half variation performance number corresponding to the variation pattern number designated by the variation pattern designation command is determined (selected).

In step S34-4, a notice effect determination process is executed, and the process proceeds to step S34-5. In the announcement effect determination process, a main announcement effect number (mode of main announcement effect) is selected.
A control ROM 302 of the performance control board 300 stores a preliminary announcement performance lottery table in which the correspondence between the preliminary announcement performance lottery random number and the main preliminary announcement performance number (mode of the main preliminary performance) is registered.
Further, as a notice effect lottery table, a notice effect lottery table corresponding to each stop symbol number (various types of stop symbols) is stored.
In order to determine the aspect of the main notice effect, first, a notice effect lottery random number is obtained from a predetermined random number counter. Also, the stop symbol number designated by the stop symbol designation command is confirmed, and the notice effect lottery table corresponding to the confirmation result is read. Then, the main notice effect lottery number is determined (judged) based on the obtained notice effect lottery random number and the read-out notice effect lottery table.

In step S34-5, a variable effect setting process is executed, a series of processes is completed, and the process proceeds to the next process (step S32-6). In the variable performance setting process, the performance scenario data of the variable performance is set.
Specifically, in the variable effect setting process, the effect scenario data corresponding to the first half variable effect number determined in step S34-3 and the effect scenario data corresponding to the second half variable effect number determined in step S34-3 are read.
Next, the read performance scenario data are synthesized to generate performance scenario data relating to the variable performance. Then, the generated production scenario data and the production scenario timer corresponding to the production scenario data are set in the production scenario setting area.
Also, the effect scenario data corresponding to the main notice effect number determined in step S34-4 is read. Then, the effect scenario data read out and the effect scenario timer corresponding to the effect scenario data are set in the effect scenario setting area. As a result, the main notice effect is started at a predetermined timing during execution of the variable effect.

(Stop command reception processing)
Next, the stop command reception process of step S32-6 will be described.
FIG. 45 is a flowchart showing stop command reception processing.
When the stop command reception process is executed in step S32-6, as shown in FIG. 45, the process proceeds to step S35-1.
In step S35-1, it is determined whether or not a stop designation command has been received. If it is determined that a stop designation command has been received (Yes), the process proceeds to step S35-2.
In step S35-2, stop effect start processing is executed, a series of processing ends, and the next processing (step S32-7) is performed. In the stop effect start process, effect scenario data for the stop effect is set.
Specifically, in the stop effect setting process, the stop effect number stored in the stop effect number storage area is obtained, and the effect scenario data corresponding to the obtained stop effect number is read. Then, the effect scenario data read out and the effect scenario timer corresponding to the effect scenario data are set in the effect scenario setting area. As a result, the stop effect (stop display of the effect symbols z1 and z2) is started.

(Opening command reception processing)
Next, the opening command reception processing of step S32-7 will be described.
FIG. 46 is a flowchart showing opening command reception processing.
When the opening command reception process is executed in step S32-7, as shown in FIG. 46, the process proceeds to step S39-1.
In step S39-1, it is determined whether or not an opening designation command has been received. If it is determined that an opening designation command has been received (Yes), the process proceeds to step S39-2, and if it is determined that an opening designation command has not been received (No), the series of processes is terminated and the process proceeds to the next process (step S32-8).
In step S39-2, a winning effect setting process is executed, a series of processes is terminated, and the process proceeds to the next process (step S32-8). In the winning effect setting process, the effect scenario data of the winning effect is set.
Specifically, in the winning effect setting process, the winning effect number is selected according to the type of stop symbol specified by the opening specifying command. Also, the effect scenario data corresponding to the selected winning effect number is read. Then, the effect scenario data read out and the effect scenario timer corresponding to the effect scenario data are set in the effect scenario setting area. Thus, the winning effect is started.

(Vsync interrupt processing)
Next, the Vsync interruption process which CPU310 of the production|presentation control board 300 performs is demonstrated.
FIG. 47 is a flowchart showing Vsync interrupt processing.
The synchronization signal generation circuit of the display circuit 320 generates a vertical synchronization signal (Vsync) (sets the vertical synchronization signal to a high level) every predetermined cycle.
The CPU 310 of the effect control board 300 starts Vsync interrupt processing shown in FIG. 47 every second predetermined period based on the generation of the vertical synchronization signal by the synchronization signal generation circuit. When the Vsync interrupt process is started, first, the process moves to step S40-1.
In step S40-1, it is determined whether or not the value set in the initial transfer completion flag area is "1". If it is determined that the value set in the initial transfer completion flag area is "1" (Yes), the process proceeds to step S40-2.

In step S40-2, frame buffer switching processing is executed, and the process proceeds to step S40-3. In the frame buffer switching process, the designation of the frame buffer area (designation of the drawing area/designation of the output area) is switched.
Specifically, in the frame buffer switching process, of the two frame buffer areas, designation of the frame buffer area designated as the drawing area is switched from the drawing area to the output area, and designation of the frame buffer area designated as the output area is switched from the output area to the drawing area.

In step S40-3, drawing command buffer switching processing is executed, and the process proceeds to step S40-4. In the drawing command buffer switching process, the designation of the drawing command buffer area (designation of construction area/designation of transfer area) is switched.
Specifically, in the drawing command buffer switching process, of the two drawing command buffer areas, the drawing command buffer area designated as the construction area is switched from the construction area to the transfer area, and the designation of the drawing command buffer area designated as the transfer area is switched from the transfer area to the construction area.
In step S40-4, drawing/output start processing is executed, and the process proceeds to step S40-5. In the drawing/output start processing, the start of drawing processing by the drawing circuit 322 is specified, and the start of output processing by the display circuit 320 is specified.
Specifically, in the drawing/output start process, a value designating the start of the drawing process is set in the drawing register of the microcomputer 301 . As a result, the drawing process by the drawing circuit 322 is started. That is, the drawing circuit 322 starts generating drawing data for one frame in the frame buffer area designated as the drawing area using the compressed image data for one frame stored (preloaded) in the preload area of the DRAM 304.
Also, in the drawing/output start processing, a value designating the start of output processing is set in the display register of the microcomputer 301 . As a result, output processing by the display circuit 320 is started. That is, the display circuit 320 starts generating and outputting a video signal based on drawing data for one frame generated in the frame buffer area designated as the output area.

In step S40-5, drawing command transfer start processing is executed, and the process proceeds to step S40-6. In the drawing command transfer start process, the start of transfer processing by the transfer circuit 318 is designated, and the start of preload processing by the preloader circuit 319 is designated.
Specifically, in the drawing command transfer start process, a value designating the start of the transfer process for transferring the display list to the preloader circuit 319 is set in the data transfer register of the microcomputer 301 . As a result, transfer processing by the transfer circuit 318 is started. That is, the transfer circuit 318 starts transferring the display list generated in the drawing command buffer area designated as the transfer area to the preloader circuit 319 .
Also, in the drawing command transfer start processing, a value designating the start of preload processing is set in the display preloader register of the microcomputer 301 . As a result, the preloading process by the preloader circuit 319 is started. That is, the preloader circuit 319 starts to transfer one frame of compressed image data (transfer from the CGROM 303 to the preload area of the DRAM 304) specified by the display list (drawing command) transferred by the transfer circuit 318, and to rewrite the display list (drawing command).

In step S40-6, command construction task wake-up processing is executed, and the Vsync interrupt processing ends. In the command construction task wake-up process, the wake-up of the command construction task process is set. As a result, command construction task processing, which will be described later, is started.

(command construction task processing)
Next, the command construction task processing which is activated in step S40-6 will be described.
FIG. 48 is a flowchart showing command construction task processing.
When the command construction task process is awakened in step S40-6, as shown in FIG. 48, the process proceeds to step S46-1.
In step S46-1, it is determined whether or not unanalyzed command information is stored in the display command buffer area. If it is determined that unanalyzed command information is stored (Yes), the process proceeds to step S46-2, and if it is determined that unanalyzed command information is not stored (No), the process proceeds to step S46-3.
In step S46-2, command information analysis processing is executed, and the process proceeds to step S46-1. In the command information analysis process, unanalyzed command information is analyzed, and a process according to the analysis result is executed.
Specifically, in the command information analysis process, when the unanalyzed command information is the command information specifying the start of the display effect, first, among the animation tables stored in the control ROM 302, the animation table corresponding to the display effect number specified by the command information is read. Then, in the animation table setting area of the DRAM 304, the read animation table, the frame rate corresponding to the animation table, and the display priority information corresponding to the animation table are set (stored/registered). At this time, the frame rate setting table is referenced, the frame rate corresponding to the index number assigned to the animation table is obtained, and the obtained frame rate is set.
On the other hand, when the unanalyzed command information is the command information specifying the end of the display performance, among the animation tables set in the animation table setting area, the animation table corresponding to the display performance number specified by the command information is cleared (erased).

In step S46-3, command construction processing is executed, and the command construction task processing ends. In the command construction process, a display list is constructed in the drawing command buffer area designated as the construction area.
Specifically, in the command building process, first, the frame information update process is executed.
In the frame information update process, frame information is updated for all animation tables set in the animation table setting area.
Specifically, in the frame information update process, for each animation table set in the animation table setting area, frame information of the next order is selected instead of the currently selected frame information as the frame information to construct the display list.
In the command building process, next, the command building process is executed.
In the command construction process, a display list is constructed in the drawing command buffer area designated as the construction area.
Specifically, in the command construction process, first, a drawing command is generated for each animation table set in the animation table setting area. For this, frame information selected as a target for constructing a display list is obtained from frame information defined in each animation table. A drawing command is generated based on the obtained frame information.
Here, the drawing command specifies the image address of the image data used for drawing, the magnification (enlargement/reduction ratio) at the time of drawing the image data, the coordinates at which the image data is drawn (coordinates in the frame buffer area), the transmittance (transparency, transparency, transparency) at the time of drawing the image data, and the like.
In the command building process, next, the drawing commands generated for all the animation tables set in the animation table setting area are arranged in a predetermined order to build a display list.
At this time, the order of drawing commands corresponding to the animation table is set based on the display priority information of each animation table set in the animation table setting area.
That is, a display list is constructed by arranging a plurality of drawing commands so that a drawing command having a lower display priority among the plurality of drawing commands is executed first for drawing processing based on the drawing command with respect to a drawing command having a higher display priority. In other words, a display list is constructed by arranging a plurality of drawing commands so that drawing processing based on a drawing command having a lower display priority among the plurality of drawing commands is executed earlier.

(sound interrupt processing)
Next, the sound interrupt processing executed by the CPU 310 of the effect control board 300 will be described.
FIG. 49 is a flowchart showing sound interrupt processing.
The CPU 310 of the effect control board 300 starts sound interrupt processing shown in FIG. 49 at predetermined intervals based on the generation of clock pulses by the clock generation circuit. When the sound interrupt process is started, first, the process moves to step S41-1.
In step S41-1, it is determined whether or not the value set in the initial transfer completion flag area is "1", and if it is determined that the value set in the initial transfer completion flag area is "1" (Yes), the process proceeds to step S41-2, and if it is determined that the value set in the initial transfer completion flag area is not "1" (is "0") (No), the sound interrupt processing is terminated.

In step S41-2, command information analysis processing is executed, and the sound interruption processing ends. In the command information analysis processing, it is determined whether or not unanalyzed command information is stored in the sound command buffer area, and when it is determined that unanalyzed command information is stored, processing according to the unanalyzed command information is executed.
Specifically, in the command information analysis process, the command list corresponding to the sound effect control number specified by the unanalyzed command information is read from the control ROM 302 and the read command list is set in the control register of the sound circuit 323 . As a result, the sound circuit 323 operates according to the command list set in the control register.

(Lamp interrupt processing)
Next, the lamp interrupt processing executed by the CPU 310 of the effect control board 300 will be described.
FIG. 50 is a flowchart showing lamp interrupt processing.
The CPU 310 of the effect control board 300 starts lamp interrupt processing shown in FIG. 50 at predetermined intervals based on the generation of clock pulses by the clock generation circuit. When the lamp interrupt process is started, first, the process proceeds to step S42-1.
In step S42-1, a command information analysis process is executed, and the lamp interrupt process ends. In the command information analysis processing, it is determined whether or not unanalyzed command information is stored in the lamp command buffer area, and when it is determined that unanalyzed command information is stored, processing according to the unanalyzed command information is executed.
Specifically, in the command information analysis process, when the unanalyzed command information is command information specifying the start of a lamp performance, the compressed lamp drive data corresponding to the lamp performance number specified by the command information is read, and the read compressed lamp drive data is set in the lamp register. As a result, the lamp controller 317a controls the lamp effect (drive (lighting) of the various lamps 20 and 21) according to the compressed lamp drive data set in the lamp register.

(Movable body interrupt processing)
Next, the movable body interrupt processing executed by the CPU 310 of the effect control board 300 will be described.
FIG. 51 is a flowchart showing movable body interrupt processing.
CPU310 of the production|presentation control board 300 starts the movable body interrupt processing shown in FIG. 51 for every predetermined period based on the generation|occurrence|production of the clock pulse by a clock generation circuit. When the movable body interrupt process is started, first, the process proceeds to step S43-1.
In step S43-1, register save processing is executed, and the process proceeds to step S43-2. In the register saving process, the value of the register is saved in the saving area of the DRAM 304 .
In step S43-2, command information analysis processing is executed, and the process proceeds to step S43-3. In the command information analysis processing, it is determined whether or not unanalyzed command information is stored in the movable body command buffer area, and when it is determined that unanalyzed command information is stored, processing is executed according to the unanalyzed command information.
Specifically, in the command information analysis process, when the unanalyzed command information is command information specifying the start of the movable body presentation, the compression motor drive data specified by the command information is read, and the read compression motor drive data is set in the motor register. As a result, the motor controller 317b controls the movable body effect (drive of various motors 23 (various movable bodies)) according to the compression motor driving data set in the motor register.
In step S43-3, register return processing is executed, and the movable body interrupt processing ends. In the register restoration process, the value of the register saved in step S43-1 is restored.

(Action of pachinko machine 1)
In the pachinko machine 1, the second custom interface image IF2 is displayed during the period when the effect custom setting can be changed. In addition, a custom change message image cm is displayed when the change of the production custom setting is confirmed.
In particular, when the variation of the special pattern is started during the display of the second custom interface image IF2 (when any one of the symbol type designation command, variation mode designation command, and variation pattern designation command is received), the display of the second custom interface image IF is terminated.
On the other hand, when the variation of the special symbol is started during the display of the custom change message image cm (when any one of the symbol type designation command, variation mode designation command, and variation pattern designation command is received), the display of the custom change message image cm is not finished.
That is, in the pachinko machine 1, the custom change message image cm is displayed according to confirmation of the change of the effect custom setting. Thus, based on the display of the custom change message image cm, it is possible to inform the player that the change of the effect custom setting has been confirmed.
In particular, in the pachinko machine 1, the display of the second custom interface image IF2 is terminated when the variation of the special symbols is started (when any one of the subcommands of the symbol type designation command, the variation mode designation command, and the variation pattern designation command is received), but the display of the custom change message image cm is not terminated when the special symbol variation is started (when any of the subcommands of the symbol type designation command, the variation mode designation command, and the variation pattern designation command is received). This makes it possible for the player to more reliably recognize that the modification of the effect custom setting has been finalized.
On the other hand, in the pachinko machine 1, when the specific display termination condition is met during the display of the second custom interface image IF2, the display of the second custom interface image IF2 is terminated. Further, when the specific display end condition is satisfied while the custom change message image cm is being displayed, the display of the custom change message image cm is ended.
As a result, the pachinko machine 1 can optimize the display.
As described above, in the pachinko machine 1, it is possible to clearly notify that the change of the effect custom setting has been confirmed, and it is possible to prevent the player from feeling uncomfortable.

(Modification 1)
Although the embodiments of the present invention have been described above, various modifications can be made to the above embodiments.
For example, in the above embodiment, the ducker 355 is set to decrease the volume of the audio bus 5 to which the lower speaker is connected based on the input of the audio bus 8 to which no speaker is connected.
However, the ducker 355 may be set to decrease the volume of the audio bus 5 to which the lower speaker is connected based on the input of the audio bus 6 to which the woofer is connected.
Even with such a configuration, when the volume of the woofer exceeds a predetermined value, the volume of the lower speaker is decreased without decreasing the volume of the woofer, thereby suppressing an increase in the total current consumption of the various speakers 22. - 特許庁

(Modification 2)
Further, in the above embodiment, the compressed audio data stored in the CGROM 303 is preloaded into the preload area of the DRAM 304, and the sound effect is executed based on the compressed audio data preloaded into the preload area.
However, the compressed audio data stored in the CGROM 303 may not be preloaded into the preload area of the DRAM 304, and sound effects may be performed based on the compressed audio data stored in the CGROM 303.

(Modification 3)
Further, in the above-described embodiment, the saucer unit SU includes two saucers (the upper saucer 8 and the lower saucer 9).
However, the saucer unit SU may include one saucer (only the upper saucer 8).
With such a configuration, all the game balls paid out by the game ball payout device 440 flow into the upper receiving tray 8 .
In particular, in addition to the above-described first dispensing hole 8a and the above-described first discharge hole 8b being provided on the wall surface on the back side of the upper tray 8, the above-described second discharge hole 9b is provided on the bottom surface of the upper tray 8.
The first payout hole 8a is provided at the upstream end of the upper receiving tray 8 (the upstream end of the path along which the game ball flows down). The game balls paid out by the game ball payout device 440 flow into the upper tray 8 from the first payout hole 8a.
The first discharge hole 8b is provided at the downstream end of the upper tray 8 (the downstream end of the path along which the game ball flows down). The game balls stored in the upper receiving tray 8 can be discharged out of the upper receiving tray 8 (specifically, the dollar box placed below the receiving tray unit SU) through the first discharge hole 8b. Specifically, a game ball outlet (not shown) is provided on the bottom surface of the tray unit SU. The first discharge hole 8b is connected to a game ball discharge port via a game ball discharge path (not shown) provided on the back side of the upper tray 8. As shown in FIG. As a result, the game ball discharged from the first discharge hole 8b passes through the game ball discharge path and is discharged from the game ball discharge port into the dollar box.
The second discharge hole 9b is provided at a position downstream of the first discharge hole 8a and upstream of the first discharge hole 8b. In this modification, the second discharge hole 9b is provided at the upstream end of the upper tray 8 (the upstream end of the path along which the game ball flows down). The game balls stored in the upper receiving tray 8 can be discharged out of the upper receiving tray 8 (specifically, the dollar box placed under the receiving tray unit SU) from the second discharge hole 9b. Specifically, the second discharge hole 9b is connected to the game ball discharge port via the game ball discharge path (not shown). As a result, the game ball discharged from the second discharge hole 9b passes through the game ball discharge path and is discharged from the game ball discharge port into the dollar box.
As described above, in this modified example, game balls can be discharged from the upper tray 8 to the dollar box through the first discharge hole 9b and the second discharge hole 9b. At this time, both the game ball discharged from the first discharge hole 9b and the game ball discharged from the second discharge hole 9b pass through the game ball discharge path and are discharged from the game ball discharge port into the dollar box.
The game balls stored in the upper tray 8 may be discharged from the first discharge hole 8b or the second discharge hole 9b to the inside of the pachinko machine 1 (for example, a counting device for counting the game balls).

The configuration of the first discharge hole 8b is as described in the above embodiment. In other words, the first discharge hole 8b is configured to have dimensions that allow the game balls to pass through (discharge) one by one. That is, the first discharge hole 8b is configured with dimensions that make it impossible to pass (discharge) two or more game balls at the same time.
The configuration of the second discharge hole 9b is as described in the above embodiment. The dimension of the second discharge hole 9b is larger than the dimension of the first discharge hole 8b. As a result, the second discharge hole 9b allows more game balls to pass through at the same time than the first discharge hole 8b. In other words, the number of game balls that can pass through the second discharge hole 9b at the same time is greater than the number of game balls that can pass through the first discharge hole 8b at the same time. Specifically, the second discharge hole 9b is configured to have dimensions that allow two or more (in this embodiment, five) game balls to pass through (discharge) at the same time.

A first opening/closing member 80 capable of opening and closing the first discharge hole 8b is provided on the back side of the upper tray 8. As shown in FIG. The configuration of the first opening/closing member 80 is as described in the above embodiment. That is, the first opening/closing member 80 is an opening/closing member that is opened and closed non-electrically (manually) without using an actuator. The first opening/closing member 80 can be displaced in the left-right direction within a range from the closed position (see FIG. 57) to the maximum open position (see FIG. 59).
When the first opening/closing member 80 is arranged at the closed position, the first discharge hole 8b is closed by the opening/closing piece 82, and the game ball cannot pass through the first discharge hole 8b.
When the first opening/closing member 80 is displaced from the closed position toward the left side (maximum open position side) as viewed from the back side, the closing of the first discharge hole 8b by the opening/closing piece 82 is gradually released, and the first discharge hole 8b is gradually opened. At this time, when the first opening/closing member 80 is arranged at the minimum open position (see FIG. 58), the opening width of the first discharge hole 8b becomes substantially the same as the diameter of the game ball, and the game ball can pass through the first discharge hole 8b. Then, when the first opening/closing member 80 is arranged at the maximum open position, the entire first discharge hole 8b is opened.
That is, when the first opening/closing member 80 is arranged on the right side (closed position side) of the minimum open position as viewed from the rear side, it becomes impossible for the game ball to pass through the first discharge hole 8b. On the other hand, when the first opening/closing member 80 is arranged on the left side of the minimum open position (maximum open position side) as viewed from the back side, it becomes possible for the game ball to pass through the first discharge hole 8b. As a result, the first opening/closing member 80 is arranged at the minimum open position, so that the minimum opening width that enables passage (discharging) of game balls is ensured as the opening width of the first discharge hole 8b.

A first ball release button 85 is provided on the side of the upper tray 8 . The configuration of the first ball eject button 85 is as described in the above embodiment. That is, the first ball extracting button 85 includes an operation portion 85a and a pushing piece portion 85b. The first ball eject button 85 can be vertically displaced (depressed) within a range from the initial position (see FIG. 57) to the lowest position (see FIG. 59).
When the operation portion 85a of the first ball removal button 85 is not operated, the first opening/closing member 80 is arranged at the closed position, and the first ball removal button 85 is arranged at the initial position. Therefore, the game balls cannot pass through the first discharge hole 8b, and the game balls stored in the upper tray 8 are not discharged.
When the operation part 85a is pushed downward from the state where the first ball removal button 85 is arranged at the initial position, the first opening/closing member 80 is displaced from the closed position toward the left side (maximum open position side) as viewed from the rear side. At this time, the larger the amount of operation (the amount of pushing) of the operating portion 85a, the larger the amount of displacement of the first opening/closing member 80, and as a result, the larger the amount of opening (opening width) of the first discharge hole 8b.
When the first opening/closing member 80 is displaced to the minimum open position by pushing the operation part 85a, the game balls can pass through the first discharge hole 8b, and the game balls stored in the upper tray 8 are discharged from the first discharge hole 8b. That is, when the first ball ejection button 85 is arranged at a specific position by pushing the operation portion 85a, the first opening/closing member 80 is arranged at the minimum open position, and the game balls can pass through the first discharge hole 8b, and the game balls stored in the upper tray 8 are discharged from the first discharge hole 8b.
As a result, when the first ball ejection button 85 is arranged above the specific position (initial position side), it becomes impossible for the game ball to pass through the first discharge hole 8b. On the other hand, when the first ball ejection button 85 is arranged below the specific position (lowermost position side), it becomes possible for the game ball to pass through the first discharge hole 8b. As a result, the first ball ejection button 85 is arranged (pushed in) at a specific position, so that the minimum opening width that allows the passage (ejection) of the game ball is secured as the opening width of the first discharge hole 8b.
Furthermore, when the first ball release button 85 is pushed to the lowest position, the first opening/closing member 80 is arranged at the maximum open position.
Then, when the pushing operation part 85a is stopped from the state where the first ball extracting button 85 is arranged at the lowest position, the first opening/closing member 80 is returned to the closed position and the first ball extracting button 85 is returned to the initial position due to the depressing force of the coil spring sp.
As described above, the player can discharge the game balls stored in the upper receiving tray 8 to the outside of the pachinko machine 1 (specifically, the dollar box placed below the receiving tray unit SU) through the first discharge hole 8b by pressing the first ball ejection button 85 (operation portion 85a).

A second opening/closing member 90 capable of opening and closing the second discharge hole 9b is provided on the bottom side of the upper tray 8 . The configuration of the second opening/closing member 90 is as described in the above embodiment. That is, the second opening/closing member 90 is an opening/closing member that is opened and closed non-electrically (manually) without using an actuator. The second opening/closing member 90 can be displaced in the left-right direction within a range from the closed position (see FIG. 60) to the maximum open position (see FIG. 62).
When the second opening/closing member 90 is arranged at the closed position, the second discharge hole 9b is entirely closed by the opening/closing plate portion 91, making it impossible for the game ball to pass through the second discharge hole 9b.
When the second opening/closing member 90 is displaced from the closed position toward the maximum open position, the closing of the second discharge hole 9b by the opening/closing plate portion 91 is gradually released, and the second discharge hole 9b is gradually opened. At this time, when the second opening/closing member 90 is arranged at the minimum open position (see FIG. 61), the opening width of the second discharge hole 9b becomes substantially the same as the diameter of the game ball, and the game ball can pass through the second discharge hole 9b. In particular, when the second opening/closing member 90 is arranged at the minimum open position, it becomes possible to pass (discharge) game balls one by one from the second discharge hole 9b. Then, when the second opening/closing member 90 is arranged at the maximum open position, the entire second discharge hole 9b is opened. In particular, when the second opening/closing member 90 is arranged at the maximum open position, it becomes possible to simultaneously pass (discharge) two or more game balls (five balls in this embodiment) from the second discharge hole 9b.
In other words, when the second opening/closing member 90 is arranged closer to the closed position than the minimum open position, it becomes impossible for the game ball to pass through the second discharge hole 9b. On the other hand, when the second opening/closing member 90 is arranged from the minimum open position to the maximum open position, it becomes possible for the game ball to pass through the second discharge hole 9b. As a result, the second opening/closing member 90 is arranged at the minimum open position, so that the minimum opening width that enables passage (discharging) of game balls is secured as the opening width of the second discharge hole 9b.

A second ball release button 95 is provided on the front surface of the upper receiving plate 8 . The configuration of the second ball eject button 95 is as described in the above embodiment. The second ball eject button 95 includes an operation portion 95a. The second ball eject button 95 can be displaced along the depth direction (performed a pushing operation) within a range from the initial position (see FIG. 60) to the lowest position (see FIG. 62).
When the operation portion 95a of the second ball removal button 95 is not operated, the second opening/closing member 90 is arranged at the closed position, and the second ball removal button 95 is arranged at the initial position. Therefore, the game balls cannot pass through the second discharge hole 9b, and the game balls stored in the upper tray 8 are not discharged.
When the operation part 95a is pushed backward from the state where the second ball extraction button 95 is arranged at the initial position, the second opening/closing member 90 is displaced from the closed position toward the left side (maximum open position side) when viewed from below. At this time, as the operation amount (push amount) of the operation portion 95a increases, the displacement amount of the second opening/closing member 90 increases, and as a result, the opening amount (open width) of the second discharge hole 9b increases.
When the second opening/closing member 90 is displaced to the minimum open position by pushing the operation part 95a, the game balls can pass through the second discharge hole 9b, and the game balls stored in the upper tray 8 are discharged from the second discharge hole 9b. That is, when the second ball ejection button 95 is arranged at a specific position by pushing the operation part 95a, the second opening/closing member 90 is arranged at the minimum open position, the game balls can pass through the second discharge hole 9b, and the game balls stored in the upper tray 8 are discharged from the second discharge hole 9b.
As a result, when the second ball extraction button 95 is arranged on the front side (initial position side) of the specific position, it becomes impossible for the game ball to pass through the second discharge hole 9b. On the other hand, when the second ball ejection button 95 is arranged on the back side (lowest position side) from the specific position, it becomes possible for the game ball to pass through the second discharge hole 9b. As a result, the second ball ejection button 95 is arranged (pushed in) at a specific position, so that the minimum opening width that allows the passage (ejection) of the game ball is secured as the opening width of the second discharge hole 9b.
Furthermore, when the second ball release button 95 is pushed to the lowest position, the second opening/closing member 90 is arranged at the maximum open position. As a result, the entire second discharge hole 9b is opened, and two or more game balls (five balls in this embodiment) can be discharged from the second discharge hole 9b at the same time.
Then, when the pushing operation part 95a is stopped from the state where the second ball extracting button 95 is arranged at the lowest position, the second opening/closing member 90 is returned to the closed position and the second ball extracting button 95 is returned to the initial position due to the depressing force of the depressing means.
As described above, the player can discharge the game balls stored in the upper receiving tray 8 to the outside of the pachinko machine 1 (specifically, the dollar box placed below the receiving tray unit SU) through the second discharge hole 9b by pushing the second ball ejection button 95 (operation portion 95a).

In particular, in this modified example, the dimension of the second discharge hole 9b is larger than the dimension of the first discharge hole 8b. That is, the second discharge hole 9b is capable of allowing more game balls to pass through (discharge) at the same time than the first discharge hole 8b. As a result, when an abnormal state (hereinafter referred to as a ``full-tank error'') occurs in which the upper tray 8 is full of game balls and the game balls put out by the game-ball putting-out device 440 cannot be sent to the tray, the full-tank error can be quickly released.
In addition, in this modification, the first ball ejection button 85 can be put into a state in which the game ball can pass through the first discharge hole 8b (a state in which the game ball can be discharged from the first discharge hole 8b) by an operation amount equal to or less than (less than) the diameter of the game ball (about 11 [mm]).
Specifically, the first ball ejection button 85 can be put into a state in which the game ball can pass through the first ejection hole 8b (a state in which the game ball can be ejected from the first ejection hole 8b) with an operation amount of 4 [mm].
That is, the operation amount for displacing the first ball eject button 85 from the initial position to the specific position is 4 [mm]. In other words, the first ball ejection button 85 can be arranged at a specific position by pushing it 4 [mm] from the initial position.
As a result, the game ball can be discharged from the upper receiving tray 8 with a small amount of operation.
In addition, in the present embodiment, the second ball eject button 95 can be put in a state in which the game ball can pass through the second ejection hole 9b (a state in which the game ball can be ejected from the second ejection hole 9b) by an operation amount equal to or less than (less than) the diameter of the game ball.
In particular, the second ball ejection button 95 can be put into a state in which the game ball can pass through the second ejection hole 9b (a state in which the game ball can be ejected from the second ejection hole 9b) with an operation amount smaller than the operation amount of the first ball ejection button 85 required to enable the game ball to be ejected from the first ejection hole 8b. In other words, the operation amount (minimum operation amount) of the second ball ejection button 95 required to allow the game ball to pass through the second ejection hole 9b (the state in which the game ball can be ejected from the second ejection hole 9b) is smaller than the operation amount (minimum operation amount) of the first ball ejection button 85 required to bring the game ball into the state in which the game ball can pass through the first ejection hole 8b (the state in which the game ball can be ejected from the first ejection hole 8b).
Specifically, the second ball ejection button 95 can be put into a state in which the game ball can pass through the second ejection hole 9b (a state in which the game ball can be ejected from the second ejection hole 9b) with an operation amount of 3 [mm].
That is, the operation amount for displacing the second ball eject button 95 from the initial position to the specific position is 3 [mm]. In other words, the second ball eject button 95 can be arranged at a specific position by pushing it 3 [mm] from the initial position. In particular, "the operation amount for displacing the second ball eject button 95 from the initial position to the specific position"<"the operation amount for displacing the first ball eject button 85 from the initial position to the specific position".
As a result, the game ball can be discharged from the upper receiving tray 8 with a small amount of operation. In particular, when a player is required to quickly remove the ball from the upper tray 8, such as when a full tank error occurs, it is possible to prompt the player to operate the second ball removal button 95 that enables efficient ball removal.

In addition, in this modification, the second ball ejection button 95 can be put into a state in which the game ball can pass through the second ejection hole 9b (a state in which the game ball can be ejected from the second ejection hole 9b) with an operation load smaller than the operation load of the first ball ejection button 85 that is required to enable the game ball to be ejected from the first ejection hole 8b. In other words, the operation load (minimum operation load) of the second ball ejection button 95 required to allow the game ball to pass through the second ejection hole 9b (the state to allow the game ball to be ejected from the second ejection hole 9b) is smaller than the operation load (minimum operation load) of the first ball ejection button 85 required to allow the game ball to pass through the first ejection hole 8b (the state to allow the game ball to be ejected from the first ejection hole 8b).
Specifically, with an operation load of 4 [N], the first ball ejection button 85 can be put into a state in which the game ball can pass through the first ejection hole 8b (a state in which the game ball can be ejected from the first ejection hole 8b).
That is, the operation load required to displace the first ball eject button 85 from the initial position to the specific position is 4 [N]. In other words, the first ball eject button 85 arranged at the initial position can be arranged at a specific position by pushing it with a force of 4 [N].
On the other hand, for the second ball ejection button 95, an operation load of 2[N] enables a state in which the game ball can pass through the second ejection hole 9b (a state in which the game ball can be ejected from the second ejection hole 9b).
That is, the operation load required to displace the second ball eject button 95 from the initial position to the specific position is 2 [N]. In other words, the second ball eject button 95 arranged at the initial position can be arranged at a specific position by pushing it with a force of 2 [N]. In particular, "the operation load required to displace the second ball eject button 95 from the initial position to the specific position"<"the operation load required to displace the first ball eject button 85 from the initial position to the specific position".
As a result, the ball can be removed from the second ball removal button 95 with an operation load smaller than that of the first ball removal button 85 . Therefore, when the player is required to quickly remove the ball from the upper tray 8, such as when a full tank error occurs, it is possible to prompt the player to operate the second ball removal button 95 that enables efficient ball removal.

Further, in this modified example, the maximum amount of operation of the second ball ejection button 95 is larger than the maximum amount of operation of the lower tray ball ejection button 85 . That is, the operation amount of the second ball ejection button 95 required to open the second ejection hole 9b to the upper limit (maximum) is greater than the operation amount of the first ball ejection button 85 required to open the first ejection hole 8b to the upper limit (maximum).
That is, the operation amount (maximum operation amount) for displacing the first ball extraction button 85 from the initial position to the lowest position is equal to or less than (less than) the diameter of the game ball. Specifically, the operation amount (maximum operation amount) for displacing the first ball eject button 85 from the initial position to the lowest position is 6 [mm]. In other words, the first ball eject button 85 can be placed at the lowest position by pushing it 6 [mm] from the initial position.
On the other hand, the operation amount (maximum operation amount) for displacing the second ball extraction button 95 from the initial position to the lowest position is equal to or larger than the diameter of the game ball (excess). Specifically, the operation amount (maximum operation amount) for displacing the second ball eject button 95 from the initial position to the lowest position is 14.5 [mm]. In other words, the second ball eject button 95 can be placed at the lowest position by pushing it 14.5 [mm] from the initial position. In particular, "the operation amount (maximum operation amount) for displacing the second ball eject button 95 from the initial position to the lowest position">"the operation amount (maximum operation amount) for displacing the first ball eject button 85 from the initial position to the lowest position".
As a result, of the two ball ejection buttons (first ball ejection button 85 and second ball ejection button 95), the ball ejection button (second ball ejection button 95) having a larger maximum operation amount becomes a ball ejection button with high ejection efficiency of game balls. Therefore, the player can intuitively select the ball removal by the second ball removal button 95 when a quick ball removal from the upper tray 8 is required, such as when a full tank error occurs.

As described above, in this modification, the first ball eject button 85 can make the game ball passable through the first discharge hole 8b with an operation amount equal to or less than the diameter of the game ball, and the second ball eject button 95 can make the game ball passable through the second discharge hole 9b with an operation amount equal to or less than the diameter of the game ball.
As a result, it becomes possible to discharge the game ball from the upper receiving tray 8 with a small operation amount for each of the ball discharge buttons 85 and 95.例文帳に追加
Therefore, it is possible to improve the work efficiency when discharging the game ball from the upper receiving tray 8 .

(Modification 4)
Further, in the above embodiment, the third custom state is always set during the execution of the special game, and when the depression of the down key button is detected during the third custom state, the fourth custom state is started accordingly. Then, during the fourth custom state, the second custom interface image IF2 is displayed on the display screen 31a, and it is possible to change the custom content for a predetermined effect custom type according to the game state.
However, the second custom interface image IF2 is not displayed during the second half of the period in which the variable display of the special symbol (variable performance) is executed, during the waiting period for passing through the gates, during the jackpot game state, during the right-handed period, etc., and it is possible to make it impossible to change the contents of customization for all the custom performance types (or part of the custom performance types). It should be noted that even during these periods, it is possible to change the setting contents of the light amount setting and the sound volume setting.
The ``waiting period for passage of a game ball through a specific gate'' is a period from winning a ``jackpot'' to detection of passage of a game ball through a specific gate in a game machine in which a jackpot game state is started when passage of a game ball through a specific gate is detected after winning a ``jackpot''.

Further, when the custom content is changed for any of the performance custom types during the variable display of the special symbols, an image indicating that the custom content has been changed is displayed and a voice indicating that the custom content has been changed may be output at the end of the variable display. At this time, if the customer waiting state is started while the image indicating that the custom content has been changed is being displayed (the sound indicating that the custom content is being changed is being output), the display of the image indicating that the custom content has been changed (the sound indicating that the custom content is being changed is output) may be terminated in the middle. On the other hand, when the variable display of the next special symbol is started while the image indicating that the custom content has been changed is being displayed (the sound indicating that the custom content is being changed is being output), the display of the image indicating that the custom content has been changed (the sound indicating that the custom content is being changed) may be continued.

Also, a configuration may be adopted in which a predetermined sound (hereinafter referred to as "change sound") is output each time a pressing operation of the volume adjustment button is detected during a period in which the volume setting can be changed. In particular, during the period in which the volume setting can be changed during the special game, the change sound may be output every time the pressing operation of the volume adjustment button is detected. On the other hand, during the period during which the volume setting can be changed during the customer waiting state, during the period from the start of the customer waiting state to the elapse of a predetermined time, a configuration may be adopted in which a change voice is output each time a press operation of the volume adjustment button is detected, and a configuration in which the change voice is not output even if the press operation of the volume adjustment button is detected during the period after the elapse of the predetermined time from the start of the customer waiting state.

1 pachinko machine 35 decoration unit detection switch 36 tray unit detection switch 200 main control board 300 effect control board DU decoration unit SU tray unit IF1 first custom interface image IF2 second custom interface image cm custom change message image

Claims (1)

a front frame having a design part formed on the upper part;
a game board on which a game area is formed;
a guide passage disposed above the game area and having an outer peripheral surface and an inner peripheral surface;
a display means for displaying a setting image during a period in which a change in settings relating to effects is possible, and displaying a specific image when changes in the settings relating to effects are confirmed;
When the first condition is met during display of the setting image, display of the setting image is terminated,
if the first condition is satisfied while the specific image is being displayed, the display of the specific image is not terminated;
Among the lines extending in the direction perpendicular to the board surface of the game board, a line passing through the top of the outer peripheral surface is defined as a first reference line,
Among the portions where the vertical line with respect to the first reference line can intersect, the rearmost portion on the lower surface of the design portion is the first design portion,
Among the portions where the vertical lines with respect to the first reference line intersect, if the lowermost portion on the lower surface of the design portion is the second design portion,
The first design portion is located below the first reference line, and the distance from the first reference line is equal to or less than the diameter of the game ball,
The second design portion is located below the first reference line, and the distance from the first reference line is equal to or greater than the diameter of the game ball ,
A virtual straight line connecting the first design portion and the second design portion is inclined so that the guide passage side is higher,
The second design portion is horizontally spaced apart from the first design portion,
A gaming machine, wherein the guide passage is visible from the front side through a space formed between the first design portion and the second design portion.

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