JP6581122B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine such as a pachinko machine, an arrangement ball machine, a sparrow ball game machine, and a slot, and more particularly to a gaming machine capable of appropriately adjusting the volume during the game.

  As a conventional gaming machine such as a pachinko machine, for example, a gaming machine described in Patent Document 1 is known. This gaming machine can adjust the volume.

JP 2013-34615 A

  However, the gaming machine as described above has a problem that although the volume can be adjusted when the game is stopped, the volume cannot be adjusted during the game.

  In view of the above problems, an object of the present invention is to provide a gaming machine capable of appropriately adjusting the volume during a game.

  The object of the present invention is achieved by the following means. In addition, although the code | symbol in a parenthesis attaches the referential mark of embodiment mentioned later, this invention is not limited to this.

According to the first aspect of the present invention, there is provided a gaming machine that executes a lottery process caused by a predetermined signal and displays an image effect corresponding to the lottery result on the display means (see the liquid crystal display device 42 shown in FIG. 2). And
A speaker that outputs sound in accordance with the gaming state (see speaker 11 shown in FIG. 1);
A game hall side operation means (see rear switch 15 shown in FIG. 6 (a)) in which the game hall side can operate the set value of the sound volume;
A player-side operation means (see front switch 14 shown in FIG. 1) that allows the player to operate the set value of the sound volume;
Demo effect execution means (see step S12 shown in FIG. 26) for executing a demonstration effect display executed during non-game,
The display means (refer to the liquid crystal display device 42 shown in FIG. 2) displays a confirmed content indicating whether or not the lottery result is in a special gaming state, and then the image effect corresponding to the new lottery result is not displayed. 2, the player's operation means (front switch shown in FIG. 1) is connected to the display means (refer to the liquid crystal display device 42 shown in FIG. 2) later than the player can operate the set value of the sound volume. 14) is displayed (see timing T2 shown in FIG. 16), and the display means (the liquid crystal display device shown in FIG. 2) is displayed. 42), when the demonstration effect display executed by the demonstration effect execution means (see step S12 shown in FIG. 26) is displayed, the display erasure means (FIG. 2) deletes the display of the volume adjustable notification image. A reference step S12) shown in, have a,
A volume adjustment image (for example, FIG. 11 (FIG. 11)) showing the sound volume corresponding to the sound volume setting value by the operation of the sound volume setting value by the player side operation means (see the front switch 14 shown in FIG. 1). b)) is displayed on the display means (see the liquid crystal display device 42 shown in FIG. 2),
It can be set by the player side operation means (see the front switch 14 shown in FIG. 1) in accordance with the set value of the sound volume by the game hall side operation means (see the back switch 15 shown in FIG. 6 (a)). Although the maximum value of the sound volume is varied, at least a part of the symbol (for example, FIG. 20B) displayed on the display means (see the liquid crystal display device 42 shown in FIG. 2) during the game is displayed. When the volume adjustment image (see, for example, the image P201 shown in FIG. 20B) is displayed on the display means (see the liquid crystal display device 42 shown in FIG. 2) so as not to overlap with the image P10 shown in FIG. Even if the maximum value of the sound volume is different, the display means (see FIG. 2) is arranged so that the number of image steps indicating the sound volume in the sound volume adjustment image (for example, see image P201 shown in FIG. 20B) is the same. LCD display It is characterized by comprising to display the location 42 reference).
According to a second aspect of the present invention, in the gaming machine according to the first aspect, the volume of the sound that can be set by the game hall side operating means (see the rear switch 15 shown in FIG. 6A). The set value is obtained from a volume output table (for example, a volume output increase / decrease value table VO_REG_TBL shown in FIG. 8 or a volume output value table VL_TBL_A shown in FIG. 9),
The sound volume setting values that can be set by the player-side operation means (see the front switch 14 shown in FIG. 1) are the sound volume output table (for example, the volume output increase / decrease value table VO_REG_TBL shown in FIG. 8; The sound volume setting value acquired from the sound volume output value table VL_TBL_A) reflects an increase value or a decrease value.
Furthermore, according to the invention of claim 3, in the gaming machine according to claim 1 or 2, the display erasing means (see step S12 shown in FIG. 26) is the display means (liquid crystal display device shown in FIG. 2). 42), the display of the volume adjustable notification image is erased after a predetermined period of time has elapsed since the demonstration effect display executed by the demonstration effect execution means (see step S12 shown in FIG. 26) is displayed. The volume-adjustable notification image is displayed (see timings T3 to T6 shown in FIG. 16).

  According to the present invention, it is possible to appropriately adjust the volume during the game.

It is a perspective view which shows the external appearance of the game machine which concerns on one Embodiment of this invention. It is a front view of the game board of the gaming machine according to the embodiment. It is a block diagram which shows the control apparatus of the game machine which concerns on the same embodiment. FIG. 5 is a block diagram of an effect control board shown in FIG. 4. FIG. 5 is a block diagram of the decorative lamp substrate shown in FIG. 4. (A) is a front view of the rear switch according to the embodiment, (b) is a diagram showing a simple access code table stored in an effect control ROM used when performing volume adjustment. It is a figure which shows the volume output value table stored in the sound ROM used when performing volume adjustment. It is a figure which shows the volume output increase / decrease value table stored in the production control ROM used when not performing the table shown in FIG. 7 when performing volume adjustment. It is a figure which shows the volume output value table stored in the sound ROM used when using the table shown in FIG. 8 when performing volume adjustment. It is a figure which shows the brightness | luminance adjustment table stored in presentation control ROM used when performing brightness | luminance adjustment. An example of a screen on which a screen for waiting for a customer is displayed on the liquid crystal display device according to the embodiment is shown, (a) shows an example of a screen on which a screen for volume adjustment / brightness adjustment is not displayed, and (b) It is a figure which shows the example of a screen where the screen of volume adjustment / luminance adjustment is displayed. The example of a screen by which the screen for waiting for a customer is displayed on the liquid crystal display device according to the embodiment is shown, and (a) is an example of a screen showing a state in which the volume is increased by one level from the state shown in FIG. (B) is a figure which shows the example of a screen which shows the state in which the sound volume fell 1 step | paragraph from the state shown in FIG.11 (b). The example of a screen where the screen for waiting for a customer is displayed on the liquid crystal display device according to the embodiment is shown, (a) shows an example of a screen where the volume is set to the maximum, and (b) shows the minimum volume. It is a figure which shows the example of a screen set to. The screen example in which the screen for waiting for a customer is displayed on the liquid crystal display device according to the embodiment is shown, and (a) is a screen example showing a state where the brightness is increased by one step from the state shown in FIG. (B) is a figure which shows the example of a screen which shows the state from which the brightness | luminance fell one step from the state shown in FIG.11 (b). The screen example in which the screen for waiting for a customer is displayed on the liquid crystal display device according to the embodiment is shown, (a) shows the screen example in which the luminance is set to the maximum, and (b) shows the minimum luminance. It is a figure which shows the example of a screen set to. It is a figure which shows the timing chart when a game state will be in a customer waiting standby state. The example of a screen transition at the time of a power saving mode OFF when a game state will be in a waiting state for a customer is shown, (a) shows an example of a screen when it is in a waiting state for a customer, and (b) is a volume adjustment / brightness An example of a screen on which an adjustment screen is displayed and a screen of a production button device is displayed is shown. (C) is an example of a screen on which a model image demo movie is displayed. (D) is a company logo. (E) is a diagram showing an example of a screen on which a screen when the customer enters a waiting state is displayed again. An example of screen transition in the power saving mode when the gaming state is in a waiting state for a customer is shown, (a) is an example of a screen in a waiting state for a customer, and (b) is a volume adjustment / brightness adjustment. (C) shows an example of a screen on which a screen of a production button device is displayed, and (c) shows an example of a screen on which a model image demo movie is displayed and power saving is being displayed. d) shows an example of a screen on which a company logo is displayed, and (e) is a diagram showing an example of a screen on which a screen when waiting for a customer is displayed again and power saving is displayed. . It is a figure which shows the timing chart which shows a series of flow which stops from the fluctuation | variation start of a special symbol, and also stops from the fluctuation | variation start of a special symbol, and then starts jackpot. (A) shows an example of a screen on which a volume adjustment / brightness adjustment screen is displayed during the change of the special symbol, and (b) shows a display mode different from (a) during the change of the special symbol. It is a figure which shows the example of a screen where the screen of volume adjustment / luminance adjustment is displayed. (A) shows an example of a screen on which a screen indicating that volume adjustment / brightness adjustment is impossible when the special symbol is stopped, and (b) shows volume adjustment / brightness adjustment when the special symbol is stopped. It is a figure which shows the example of a screen as which the screen is displayed. It is a figure which shows the example of a screen in which the screen of volume adjustment / brightness | luminance adjustment is displayed at the time of the change start of special symbols. (A) shows an example of a screen on which the change of the special symbol is started. (B) shows a screen for adjusting the volume / brightness after a predetermined time has elapsed after the screen of (a) is displayed. FIG. (A) shows a screen example in which a screen indicating that volume adjustment / brightness adjustment is not possible is displayed when the special symbol is stopped, and (b) shows volume adjustment by a player's operation at the time of jackpot start. FIG. 10 is a diagram illustrating an example of a screen on which a screen for brightness adjustment is displayed. It is a figure which shows the error list which shows the specific content when a game state will be in an error state. It is a flowchart figure which shows the main process of the presentation control which concerns on the same embodiment. It is a flowchart figure which shows the detail of the brightness | luminance setting process shown in FIG. It is a flowchart figure which shows the detail of the sound output process shown in FIG. It is a flowchart figure which shows the command reception process of the production control which concerns on the same embodiment. It is a flowchart figure which shows the timer interruption process of presentation control which concerns on the same embodiment.

  Hereinafter, an embodiment of a gaming machine according to the present invention will be specifically described with reference to FIGS. 1 to 30 by taking a pachinko gaming machine as an example. In addition, in the following description, when showing the direction of up, down, left and right, it means up, down, left and right when viewed from the front of the figure.

<Description of appearance configuration>
First, the external configuration of the pachinko gaming machine according to the present embodiment will be described with reference to FIGS.

  As shown in FIG. 1, a pachinko gaming machine 1 has a rectangular front frame 3 attached to the front surface of a wooden outer frame 2 so that it can be opened and closed, and a game board storage frame (see FIG. 1) attached to the back surface of the front frame 3. (Not shown) in which the game board 4 is mounted. The game board 4 is mounted with the game area 40 shown in FIG. 2 facing the front, and a glass door frame 5 supporting transparent glass is provided on the front side of the game area 40 as shown in FIG. It has been. A plurality of decorative lamps LA (see FIG. 5) such as LED lamps that exhibit the effect of light decoration are arranged on the peripheral frame of the front frame 3. The game area 40 is an area surrounded by a ball guide rail 6 (see FIG. 2) disposed on the surface of the game board 4.

  On the other hand, as shown in FIG. 1, the pachinko gaming machine 1 is provided with a front operation panel 7 below the glass door frame 5, and the front operation panel 7 is provided with an upper tray unit 8. The unit 8 is integrally formed with an upper tray 9 for storing discharged game balls. A firing handle 10 for operating the launching unit is provided on the right end side of the front operation panel 7, and BGM (Background music) is provided on both upper side surfaces of the front frame 3 and on the left adjacent position of the launching handle 10. ) Or a speaker 11 for outputting sound effects or the like.

  Further, the front operation panel 7 is provided with a ball lending button 12 and a prepaid card discharge button 13 (card return button 13), and further, a front switch 14 having a substantially cross key is provided. The front switch 14 is mainly used by a player, and includes up / down / left / right selection switches SW1 to SW4 corresponding to four positions, up / down / left / right, and a determination switch SW5 provided at the center of the up / down / left / right selection switches SW1 to SW4. And can be used for adjusting the volume of the sound output from the speaker 11, adjusting the light emission brightness of the plurality of decorative lamps LA (see FIG. 6), and providing a notice effect.

  On the other hand, a back switch 15 (see FIG. 6A) is provided on the back side of the gaming machine 1. This back switch 15 is mainly used by game hall employees and the like, and can adjust the volume of BGM or sound effect output from the speaker 11. As shown in FIG. 6A, the rear switch 15 can be adjusted in 10 steps from 0 to 9.

  On the other hand, a push button type effect button device 16 that can change the effect by pressing when a built-in lamp (not shown) is lit is provided on the upper plate surface portion of the upper tray 9. Further, the upper tray 9 is provided with a ball removal button 17 for pulling downward the game balls stored in the upper tray 9.

  On the other hand, as shown in FIG. 2, a center case 41 is disposed in the game area 40 of the game board 4, and a liquid crystal display device 42 composed of an LCD (Liquid Crystal Display) or the like is integrated with the center case 41. Provided. The liquid crystal display device 42 divides the display area into three areas, left, middle, and right, and independently displays a variable display of numbers, characters, characters (character conversation, lyric telop, etc.) or symbols (decorative symbols). It is possible. The center case 41 is provided with a decorative top ornament 43a, a left ornament 43b, and a right ornament 43c so as to surround the liquid crystal display device 42. The top ornament 43a, the left ornament 43b, The right decoration 43c is provided with a plurality of decoration lamps LA (see FIG. 5) such as LED lamps that produce an effect by decoration of light. In addition, although not shown, a movable accessory is arranged on the back side of the upper decoration 43a, the left decoration 43b, and the right decoration 43c. The movable accessory is also provided with a plurality of decorative lamps LA (see FIG. 5) such as LED lamps that produce an effect by decoration of light.

  On the other hand, a special symbol 1 starting port 44 is disposed directly below the center case 41, and a special symbol 1 starting port switch 44a (see FIG. 3) for detecting a winning ball is provided therein. Then, the number of effective winning balls detected by the special symbol 1 starting port switch 44a (see FIG. 3), that is, the first starting reserved ball number is displayed on the liquid crystal display device 42 by a predetermined number (for example, four). . Note that this first starting reserved ball number is incremented by 1 (+1) when a game ball wins the special symbol 1 starting port 44 and is detected by the special symbol 1 starting port switch 44a (see FIG. 3). When the variable display of the special symbol 1 such as a number, character, or symbol (decorative symbol) is started, 1 is subtracted (-1).

  Further, a special symbol 2 starting port 45 is disposed on the right end side of the center case 41, that is, on the right ornament 43c end side, and a special symbol 2 starting port switch 45a (for detecting a winning ball) is provided therein. 4). Then, the number of effective winning balls detected by the special symbol 2 starting port switch 45a (see FIG. 3), that is, the number of second starting reserved balls is displayed on the liquid crystal display device 42 by a predetermined number (for example, four). . The number of the second starting reserved balls is incremented by 1 (+1) when a game ball wins the special symbol 2 starting port 45 and is detected by the special symbol 2 starting port switch 45a (see FIG. 3). When the variable display of the special symbol 2 such as a number, character or symbol (decorative symbol) is started, 1 is subtracted (-1).

  On the other hand, an identification lamp device 46 indicating identification information corresponding to the special symbol 1 and the special symbol 2 is provided on the upper left side of the center case 41, that is, on the upper side of the left ornament 43b. The identification lamp device 46 is provided with first and second identification lamps 46a and 46b for notifying the player of the special symbol 1 and the special symbol 2 being fluctuating or the information of the special symbol 1 and the special symbol 2 being lost. It has. The first identification lamp 46 a corresponds to the special symbol 1, and the second identification lamp 46 b corresponds to the special symbol 2. When the special symbol 1 is changing, the first identification lamp 46a blinks. When the special symbol 1 is hit, the first identification lamp 46a is lit. When the special symbol 1 is lost, the first identification lamp 46a is turned on. Turns off. Further, when the special symbol 2 is changing, the second identification lamp 46b blinks. When the special symbol 2 is hit, the second identification lamp 46b is lit. When the special symbol 2 is lost, the second identification lamp 46b is turned on. 46b is turned off.

  On the other hand, as shown in FIG. 2, a special winning opening 47 is arranged on the right side of the special symbol 1 starting opening 44, and a special winning opening switch 47a (see FIG. 3) for detecting a winning ball is provided therein. It has been. In addition, a normal symbol starting port 48 made of a gate is disposed in the upper right part of the liquid crystal display device 42, and a normal symbol starting port switch 48a (see FIG. 3) for detecting the passage of a game ball is provided therein. It has been. Further, on the right side of the big winning opening 47 and the left side of the special symbol 1 starting opening 44, general winning openings 49 are arranged (one on the right side and three on the left side in the drawing), respectively, A general winning opening switch 49a (see FIG. 3) for detecting the passage of the game ball is provided.

  On the other hand, in the lower right peripheral edge of the game area 40 of the game board 4, three 7 segments are arranged side by side, of which two 7 segments are the special symbol display device 50, and the other 7 segments are The number of reserved balls such as special symbol 1 or special symbol 2 is displayed. As shown in FIG. 2, the special symbol display device 50 includes a special symbol 1 display device 50a and a special symbol 2 display device 50b. On the left side of the special symbol 1 display device 50a, two special symbol display devices 50a are provided. A normal symbol display device 51 made of LEDs is provided. A plurality of game nails (not shown) are arranged in the game area 40 of the game board 4, and a windmill 52 as a game ball drop direction changing member is arranged.

<Description of control device>
Next, a control device that performs electronic control according to the progress of the game provided in the pachinko gaming machine having the above-described external configuration will be described with reference to FIGS.

  As shown in FIG. 3, the control device includes a main control board 60 that controls the overall game operation, a payout control board 70 that pays out a game ball based on a control command from the main control board 60, an image, It is mainly composed of a sub-control board 80 that controls light and sound. As shown in FIG. 3, the sub control board 80 includes an effect control board 90, a decorative lamp board 100, and a liquid crystal control board 120.

  The main control board 60 is a one-chip microcomputer comprising a main control CPU 600, a main control ROM 601 storing a game program describing a series of game control procedures, and a main control RAM 602 functioning as a work area, a buffer memory, etc. It is equipped with. Further, the main control board 60 is equipped with a RAM clear switch 603 that can clear the main control RAM 602 that can be used by employees of the game hall. The main control board 60 configured in this manner is connected to a payout control board 70 that controls the payout motor M to pay out game balls. Further, a special symbol 1 starting port switch 44a for detecting a winning in the special symbol 1 starting port 44, a special symbol 2 starting port switch 45a for detecting a winning in the special symbol 2 starting port 45, and a normal symbol starting port A normal symbol start port switch 48 a for detecting the passage of 48 and a general winning port switch 49 a for detecting a winning to the general winning port 49 are connected. In addition, a special symbol 1 display device 50a, a special symbol 2 display device 50b, and a normal symbol display device 51 are connected to the main control board 60. Furthermore, a door opening sensor 55 for detecting whether or not the glass door frame 5 provided on the glass door frame 5 is opened is connected to the main control board 60, and each start port 44, 45, 48 and each When a player provided in the winning openings 47, 49 executes an illegal act against the game by a strong magnet, radio wave, or vibration, a radio sensor 56, a magnetic sensor 57, a vibration for detecting the illegal act A sensor 58 is connected.

  When the main control board 60 configured in this way receives a signal from the special symbol 1 starting port switch 44a, the special symbol 2 starting port switch 45a, or the normal symbol starting port switch 48a, a special gaming state advantageous to the player is obtained. A lottery of whether to generate (so-called “big hit”) or not to generate a special gaming state advantageous to the player (so-called “losing”), and the variation pattern of special symbols according to the success / failure information that is the lottery result The display content of the stop symbol or the normal symbol is determined, and the determined information is transmitted to the special symbol 1 display device 50a, the special symbol 2 display device 50b, or the normal symbol display device 51. As a result, the lottery result is displayed on the special symbol 1 display device 50a, the special symbol 2 display device 50b, or the normal symbol display device 51. Further, the main control board 60 generates an effect control command DI_DATA (see FIG. 4) including the determined information and transmits it to the effect control board 90. When the main control board 60 receives signals from the general winning opening switch 49a and the big winning opening switch 47a, it determines how many game balls are to be paid out to the player, and payout control including the determined information. By sending the command PAY_CMD to the payout control board 70, the payout control board 70 pays out the game ball to the player.

  The payout control board 70 receives the payout control command PAY_CMD from the main control board 60 and generates a payout motor signal based on the received payout control command PAY_CMD. Then, with the generated payout motor signal, the payout motor M is controlled to pay out the game ball to the player. Further, the payout control board 70 transmits a prize ball count signal indicating a payout operation of the game ball and a status signal STAY_SIGNAL relating to an abnormality in the payout operation, and fires the game ball in response to the player's operation. The process which transmits the firing control signal which starts or stops the operation | movement of 71 is performed. The status signal STAY_SIGNAL includes a plurality of signals such as a replenishment out signal, a ball clogging signal, and a payout shortage error signal.

  On the other hand, as shown in FIG. 4, the effect control board 90 stores an effect control CPU 900 having an effect control RAM 900a functioning as a work area, a buffer memory, and the like, a control program describing the effect control procedure, and the like. A production control ROM 901, a sound LSI 902 that generates BGM or sound effects and adjusts the volume thereof, and a sound ROM 903 that stores sound data such as BGM or sound effects are mounted.

  As shown in FIG. 4, the effect control CPU 900 is connected to the effect control ROM 901 via an effect address bus ADR_BUS (24 bits in the figure) and an effect data bus DA_BUS (16 bits in the figure), and is connected to the effect address bus ADR_BUS. The lower 2 bits and the upper 8 bits of the effect data bus DA_BUS are connected to the sound LSI 902. The sound LSI 902 is connected to the sound ROM 903 via a sound address bus MADR_BUS (26 bits in the drawing) and a sound data bus MDA_BUS (16 bits in the drawing).

  As shown in FIGS. 3 and 4, the effect control CPU 900 configured as described above has a special bonus based on the jackpot lottery result (whether the jackpot or lose) from the main control board 60 that controls the overall game operation described above. Stop based on symbol variation pattern (including special symbol 1 variation pattern, special symbol 2 variation pattern), current gaming state, number of starting reserved balls (including first starting reserved ball number, second starting reserved ball number), lottery result An effect control command DI_DATA (8 bits in the figure) including basic information necessary for a decorative design and the effect interrupt signal DI_IRQ are transmitted. As a result, the effect control CPU 900 receives the effect control command DI_DATA, and determines the effect pattern corresponding to the effect control command DI_DATA by lottery from a number of effect patterns stored in advance in the effect control ROM 901. To do. And the control signal which instruct | indicates execution of the determined production pattern is temporarily stored in production control RAM900a.

  In addition, the effect control CPU 900 transmits a control signal related to sound to the sound LSI 902 among the control signals instructing execution of the effect pattern stored in the effect control RAM 900a. In response to this, the sound LSI 902 reads out sound data corresponding to the control signal from the sound ROM 903 and transmits the read sound data to the speaker 11 as BGM or sound source data AMOR / L of sound effects. Thereby, BGM or sound effect corresponding to the determined effect pattern is output from the speaker 11.

  Further, the effect control CPU 900 controls the image-related control signals, that is, the liquid crystal control command LCD_CMD (16 bits in the drawing) and the liquid crystal control interrupt signal LCD_IRQ among the control signals for executing the effect patterns stored in the effect control RAM 900a. Is transmitted to the liquid crystal control board 120. As a result, the liquid crystal control board 120 controls the liquid crystal display device 42 to display an image based on the liquid crystal control command LCD_CMD, so that an image corresponding to the determined effect pattern is displayed on the liquid crystal display device 42. It will be. The liquid crystal control board 120 is equipped with a ROM that stores various image data for displaying an image in accordance with the contents of the effect, and a VDP (Video Display Processor) that controls the overall effect output. Yes.

  Then, the effect control CPU 900 controls the control signal related to light (decorative lamp output data LAMP_DATA and the decorative lamp output data LAMP_DATA) among the control signals for instructing execution of the effect pattern stored in the effect control RAM 900a. A decorative lamp output data control signal LAMP_CLK) is transmitted to the decorative lamp substrate 100. As a result, the decorative lamp substrate 100 performs control to turn on or off the decorative lamp LA (see FIG. 5) such as an LED lamp that produces an effect by decoration of light, and therefore corresponds to the determined effect pattern. An effect by decoration of light will be executed.

  On the other hand, the effect control CPU 900 is connected to a push button-type effect button device 16 that can change the effect when the player presses the built-in lamp (not shown). Thereby, the effect control CPU 900 transmits effect button lamp data BU_LAMP_DATA to the effect button device 16 in the case of an effect that causes the player to press the effect button device 16, and the player presses the effect button device 16. It is possible to receive the effect button sensor BU_SEN indicating whether or not from the effect button device 16.

  Furthermore, the first control lamp 46a and the second identification lamp 46b are connected to the effect control CPU 900, and the special symbol 1 is fluctuating in the first identification lamp 46a, or information on the loss of hit of the special symbol 1 is lost. Is transmitted to the first identification lamp data ID1_LAMP_DATA for informing the player of the information, and the second identification lamp 46b is in a state where the special symbol 2 is fluctuating or information on the special symbol 2 is lost. 2 Identification lamp data ID2_LAMP_DATA is transmitted.

  Furthermore, the effect control CPU 900 is connected to the front switch 14 and receives the contact signal FSW_DATA of the up / down / left / right selection switches SW1 to SW4 or the determination switch SW5. Further, the effect control CPU 900 is connected to the back switch 15 and receives the adjustment content in any of 10 levels from 0 to 9, that is, the adjustment signal BSW_DATA.

  As shown in FIG. 5, the decorative lamp substrate 100 is mainly mounted with a buffer 1000 and a plurality of decorative lamp driving drivers 1001a to 1001c (three in the drawing), and these decorative lamp driving drivers 1001a to 1001c include A plurality of decorative lamps LA are connected to each other.

  The buffer 1000 converts the decoration lamp output data LAMP_DATA transmitted from the effect control CPU 900 and the decoration lamp output data control signal LAMP_CLK for controlling the decoration lamp output data LAMP_DATA into LAMP_DATAa / b / c and LAMP_CLKa / b / c. And transmitted to the decorative lamp driving drivers 1001a to 1001c.

  Then, the decorative lamp driving drivers 1001a to 1001c perform driving control of turning on or off the plurality of decorative lamps LA based on the converted data (LAMP_DATAa / b / c, LAMP_CLKa / b / c). Further, the cathode side of the decorative lamp LA is connected to the decorative lamp driving drivers 1001a to 1001c, and the anode side is connected to a 12V power source via a resistor R. The decorative lamp LA may be any type, for example, a three-color LED may be used, or a single-color LED lamp such as a white LED may be used. Either of them may be used.

  By the way, the power supply to each board | substrate demonstrated above is supplied from the power supply board 130 shown in FIG. In the drawing, the power supply route is omitted.

<Description of volume adjustment / brightness adjustment>
Here, since the feature of the present embodiment is related to volume adjustment and luminance adjustment, this point will be described in detail below with reference to FIGS.

  First, a table used for volume adjustment and luminance adjustment will be described in detail.

<Description of volume adjustment table>
The effect control ROM 901 stores a simple access code table SAC_TBL shown in FIG. This simple access code table SAC_TBL stores the number of simple access codes (hereinafter referred to as SAC number) associated with sound volume output data stored in a sound ROM 903, which will be described later. That is, the simple access code table SAC_TBL stores 10-stage numbers from 0 to 9 in the rear switch 15 shown in FIG. 6A, and these numbers are stored in the table TB1 shown in FIG. 6B. Each is stored. The uses of the back switch 15 in the 10-step numbers 0 to 9 are stored in the table TB2 shown in FIG. 6B. More specifically, when the arrow 15a (see FIG. 6A) of the rear switch 15 is adjusted to “0”, the volume of BGM or sound effect output from the speaker 11 is “silent (muted)”. ) ”And the arrow 15a is adjusted to“ 1 ”, the volume is adjusted to“ small volume for presentation ”, and when the arrow 15a is adjusted to“ 2 ”, the volume is set to“ presentation volume ”. It is adjusted to “Large Volume”. On the other hand, “3” to “9” can be adjusted to the game room volume, and when the arrow 15a is adjusted to “3” to “5”, it becomes possible to shift to the power saving mode. When the volume is adjusted to “3”, the volume of the BGM or sound effect output from the speaker 11 is adjusted to a low volume. When the volume is adjusted to “4”, the volume is adjusted to a medium volume and set to “5”. When adjusted, the volume is adjusted to a large volume. Further, when the arrow 15a is adjusted to “6” to “9”, the normal mode is maintained without shifting to the power saving mode. Among them, when the arrow 15a is adjusted to “6”, the sound is output from the speaker 11. When the volume of BGM or sound effect is adjusted to a low volume and adjusted to “7”, the volume is adjusted to a medium volume, and when adjusted to “8”, the volume is adjusted to a high volume. When the volume is adjusted to “9”, the volume is adjusted to the maximum volume.

  On the other hand, in the simple access code table SAC_TBL, the number of SACs corresponding to the numbers stored in the table TB1 is stored in the table TB3 shown in FIG. The number of SACs stored in this table TB3 corresponds to the numbers in 10 steps from 0 to 9 in the rear switch 15, and can be set by the employees on the game hall side. The reference value (volume setting value) Is “0”). That is, if the player does not press the up / down / left / right selection switches SW1 to SW4 of the front switch 14, the BGM adjusted to the volume based on the volume output data corresponding to the number of SACs stored in the table TB3 and the effect Sound or the like is output from the speaker 11.

  On the other hand, when the player presses the right selection switch SW4 (see FIG. 1) of the front switch 14 to increase the volume, the number of SACs corresponding to the number of presses (setting value) is stored in the simple access code table SAC_TBL. As shown in FIG. 6B, these SAC numbers are stored in the table TB4.

  In this table TB4, when an employee on the game hall side selects any of 0 to 2 on the rear switch 15, no SAC number is stored, and the player selects the right of the front switch 14. Even if the switch SW4 is pressed, the volume cannot be adjusted. On the other hand, when an employee or the like on the game hall selects any of 3 to 9 on the rear switch 15, every time the player presses the right selection switch SW4 of the front switch 14, +1 is incremented. The number of SACs corresponding to increasing volume setting values is stored. The number of SACs is increased by +1 with respect to the number of SACs of the reference values stored in the table TB3, and the player can increase the volume in two steps from the reference value. .

  On the other hand, when the player presses the left selection switch SW3 (see FIG. 1) of the front switch 14 to decrease the volume, the number of SACs corresponding to the number of presses (setting value) is stored in the simple access code table SAC_TBL. These SAC numbers are stored in the table TB5 as shown in FIG. 6B.

  In this table TB5, when an employee on the game hall side selects any of 0 to 2 in the rear switch 15, no SAC number is stored, and the player selects the front switch 14 to the left. Even if the switch SW3 is pressed, the volume cannot be adjusted. On the other hand, when an employee or the like on the game hall side selects any of 3 to 9 on the back switch 15, every time the player presses the left selection switch SW3 of the front switch 14, −1 The number of SACs corresponding to the volume setting value that decreases gradually is stored. The number of SACs is stored by decreasing by −1 with respect to the number of SACs of the reference value stored in the table TB3, and the player can reduce the volume in two steps from the reference value. Yes. A specific operation method related to volume adjustment by the player will be described later.

  Thus, depending on the settings of the game hall employees, etc., by providing a setting that does not allow the player to adjust the volume, another player becomes uncomfortable by changing the volume. Such troubles between players can be prevented in advance.

  On the other hand, the sound ROM 903 (see FIG. 4) stores a volume output value table VL_TBL as shown in FIG. In the volume output value table VL_TBL, the number of SACs stored in the simple access code table SAC_TBL is stored from 0 to 100. These SAC numbers are stored in the table TB10 shown in FIG.

  The volume output value table VL_TBL stores volume output data in the speaker 11 corresponding to the number of SACs stored in the table TB10. These volume output data are stored in the table TB11 shown in FIG. Has been. More specifically, the table TB11 stores volume output data of the volume output from the speaker 11, and is further provided in the sound LSI 902 (see FIG. 4) for setting the volume output data. The register address (C0H) is also stored. The volume output value table VL_TBL stores an end code (FFH) for ending the access to the volume output value table VL_TBL for the sound LSI 902 (see FIG. 4). These end codes are stored in the table TB12 shown in FIG.

  In this way, the simple access code table SAC_TBL is stored in the effect control ROM 901 (see FIG. 4), and the volume output value table VL_TBL is stored in the sound ROM 903 (see FIG. 4), thereby being stored in the sound ROM 903. The volume of the sound output from the speaker 11 can be adjusted according to the data. That is, when the production control CPU 900 presses the contact signal of the up / down / left / right selection switches SW1 to SW4 of the front switch 14 (for example, the right selection switch SW4 of the front switch 14 once, that is, the volume setting value is “+1”). ) And the adjustment signal BSW_DATA from the back switch 15 (for example, when the arrow 15a of the back switch 15 has selected “3”), the effect control ROM 901 via the effect address bus ADR_BUS and the effect data bus DA_BUS. When the simple access code table SAC_TBL stored in the table is accessed, the effect control CPU 900 reads the number of SACs (for example, 31) from the simple access code table SAC_TBL, and the effect of the read SAC number (for example, 31). Address bus A And outputs it to the sound LSI902 through the R_BUS and effect data bus DA_BUS. Then, the sound LSI 902 reads the sound volume output data corresponding to the number of SACs (for example, 31) to the sound volume output value table VL_TBL stored in the sound ROM 903 via the sound address bus MADR_BUS and the sound data bus MDA_BUS. Access, read the volume output data (for example, 35H) in the speaker 11 corresponding to the number of SACs (for example, 31) and the internal register address (C0H) of the sound LSI 902 via the sound data bus MDA_BUS, and end The code (FFH) is read out via the sound data bus MDA_BUS. As a result, the sound LSI 902 outputs the BGM adjusted to the volume based on the volume output data (for example, 35H) read from the sound ROM 903 and the sound source data AMOR / L_A of the sound effect to the speaker 11. Therefore, by storing the simple access code table SAC_TBL in the effect control ROM 901 and the volume output value table VL_TBL in the sound ROM 903, the sound output from the speaker 11 can be determined by the data stored in the sound ROM 903. The volume can be adjusted.

<Description of another volume adjustment table>
By the way, the table for adjusting the volume of the sound output from the speaker 11 is not limited to the table shown in FIGS. 6B and 7, and the tables shown in FIGS. 8 and 9 may be used.

  The sound volume output increase / decrease value table VO_REG_TBL shown in FIG. 8 is stored in the effect control ROM 901, and the sound volume output increase / decrease value table VO_REG_TBL stores 10-step numbers 0 to 9 in the rear switch 15 in the table TB20. ing. The usages of the back switch 15 in 10-step numbers 0 to 9 are stored in the table TB21. The contents of the usage shown in the table TB21 are the same as the contents of the usage of the table TB2 shown in FIG.

  On the other hand, in the volume output increase / decrease value table VO_REG_TBL, the number of SACs corresponding to the numbers stored in the table TB20 is stored in the table TB22 shown in FIG. The number of SACs stored in this table TB22 corresponds to the numbers in 10 steps from 0 to 9 in the rear switch 15, and can be set by an employee on the game hall side. Is “0”). That is, if the player does not press any of the up / down / left / right selection switches SW1 to SW4 of the front switch 14, the BGM adjusted to the volume based on the volume output data corresponding to the number of SACs stored in the table TB22 and the effect Sound or the like is output from the speaker 11.

  On the other hand, when the player presses the right selection switch SW4 (see FIG. 1) of the front switch 14 to increase the volume, the volume output data (see FIG. 9) increases corresponding to the number of presses (set value). Each value is stored in the volume output increase / decrease value table VO_REG_TBL, and these increased values are stored in the table TB23 as shown in FIG.

  In this table TB23, when an employee on the game hall side selects any one of 0 to 2 in the rear switch 15, no increase value of the volume output data is stored, and the player can change the front switch Even if the 14 right selection switch SW4 is pressed, the volume cannot be adjusted. On the other hand, when an employee or the like on the game hall side selects any one of 3 to 9 on the back switch 15, every time the player presses the right selection switch SW4 of the back switch 15, +1 is added. The increase value of the volume output data corresponding to the increasing volume setting value is stored. As the increase value of the volume output data, an increase value that increases by + 3H is stored, and the player can increase the volume in two steps from the reference value.

  On the other hand, when the player presses the left selection switch SW3 (see FIG. 1) of the front switch 14 to reduce the volume, the volume output data (see FIG. 9) corresponding to the number of presses (set value) decreases. Each value is stored in a volume output increase / decrease value table VO_REG_TBL. These reduction values are stored in the table TB24 as shown in FIG.

  In this table TB24, when an employee on the game hall side selects any of 0 to 2 in the rear switch 15, no decrease value of the volume output data is stored, and the player can switch the front switch Even if the 14 left selection switch SW3 is pressed, the volume cannot be adjusted. On the other hand, when an employee or the like on the game hall side selects any of 3 to 9 on the back switch 15, every time the player presses the left selection switch SW3 of the front switch 14, −1 Stores a decrease value of the volume output data corresponding to the volume setting value that decreases gradually. As the decrease value of the volume output data, a decrease value that decreases by -3H is stored, and the player can decrease the volume in two steps from the reference value.

  On the other hand, the sound ROM 903 (see FIG. 4) stores a volume output value table VL_TBL_A as shown in FIG. In this volume output value table VL_TBL_A, the number of SACs stored in the volume output increase / decrease value table VO_REG_TBL is stored from 0 to 9, and these SAC numbers are respectively stored in the table TB30 shown in FIG. .

  The volume output value table VL_TBL_A stores volume output data in the speaker 11 corresponding to the number of SACs stored in the table TB30. These volume output data are stored in the table TB31 shown in FIG. Has been. More specifically, the table TB31 stores volume output data of the volume output from the speaker 11, and is further provided in the sound LSI 902 (see FIG. 4) for setting the volume output data. The register address (C0H) is also stored. The volume output value table VL_TBL_A stores an end code (FFH) for ending the access to the volume output value table VL_TBL_A for the sound LSI 902. These end codes are stored in the table TB32 shown in FIG.

  Thus, by storing the volume output increase / decrease value table VO_REG_TBL in the effect control ROM 901 and the volume output value table VL_TBL_A in the sound ROM 903, the data stored in the sound ROM 903 can be greatly reduced. . That is, the effect control CPU 900 uses the effect address bus ADR_BUS and the effect data bus DA_BUS based on the adjustment signal BSW_DATA from the back switch 15 (for example, when the arrow 15a of the back switch 15 selects “3”). Then, when accessing the volume output increase / decrease value table VO_REG_TBL stored in the effect control ROM 901, the effect control CPU 900 reads the number of SACs (for example, 3) from the volume output increase / decrease value table VO_REG_TBL, and the read SAC number ( For example, 3) is output to the sound LSI 902 via the effect address bus ADR_BUS and the effect data bus DA_BUS. Then, the sound LSI 902 reads the sound volume output data corresponding to the number of SACs (for example, 3) to the sound volume output value table VL_TBL_A stored in the sound ROM 903 via the sound address bus MADR_BUS and the sound data bus MDA_BUS. Access, read the volume output data (for example, 32H) in the speaker 11 corresponding to the number of SACs (for example, 3) and the internal register address (C0H) of the sound LSI 902 via the sound data bus MDA_BUS, and end The code (FFH) is read out via the sound data bus MDA_BUS. Accordingly, the sound LSI 902 stores the sound volume output data (for example, 4BH) in the sound volume output data (for example, 32H) in the speaker 11 read from the sound ROM 903 in the internal register. Then, the effect control CPU 900 reads the volume output data (for example, 32H) in the speaker 11 stored in the internal register of the sound LSI 902 via the effect data bus DA_BUS, and controls the up / down / left / right selection switches SW1 to SW4 of the front switch 14. Based on the contact signal (for example, when the right selection switch SW4 of the front switch 14 is pressed once, that is, when the volume setting value is “+1”), the volume output data is increased or decreased. That is, in the present embodiment, the volume output data in the speaker 11 is 32H + 03H = 35H, and the effect control CPU 900 uses the sound LSI 902 via the effect address bus ADR_BUS and the effect data bus DA_BUS. Output to. As a result, the sound LSI 902 outputs the BGM adjusted to the volume based on the volume output data (for example, 35H) in the speaker 11 and the sound source data AMOR / L of the sound effect to the speaker 11.

  Thus, by storing the volume output increase / decrease value table VO_REG_TBL in the effect control ROM 901 and the volume output value table VL_TBL_A in the sound ROM 903, the data stored in the sound ROM 903 can be greatly reduced. be able to.

  In this embodiment, the volume output value table VL_TBL_A is stored in the sound ROM 903, but may be stored in the effect control ROM 901. According to this, it is not necessary to bother to access the sound ROM 903 when reading the volume output data corresponding to the number of SACs.

<Description of brightness adjustment table>
Next, a table used when adjusting the luminance will be described.

  The effect control ROM 901 stores a brightness adjustment table BR_TBL shown in FIG. In the brightness adjustment table BR_TBL, as shown in a table TB50 shown in FIG. 10, brightness setting values are stored, and three-stage numbers 1 to 3 are stored. And the brightness | luminance adjustment value corresponding to this brightness | luminance setting value is stored in table TB51. More specifically, when the luminance setting value is set to “3”, the luminance adjustment value of the decorative lamp LA is 100%. That is, the decorative lamp LA is lit at the maximum luminance value. When the brightness setting value is set to “2”, the brightness adjustment value of the decorative lamp LA is 60%. That is, the decoration lamp LA is turned on with a luminance value of 60% (a luminance value obtained by multiplying the maximum luminance value by 60%). Further, when the luminance setting value is set to “1”, the luminance adjustment value of the decorative lamp LA is 30%. That is, the decorative lamp LA is turned on with a luminance value of 30% (a luminance value obtained by multiplying the maximum luminance value by 30%).

  This luminance setting value is set to “3” as an initial value, but can be freely adjusted by the player. That is, if the player presses the upper selection switch SW1 (see FIG. 1) of the front switch 14 to increase the brightness setting value, the brightness setting value increases by +1. On the other hand, when the player presses the lower selection switch SW2 (see FIG. 1) of the front switch 14 to decrease the luminance setting value, the luminance setting value is decreased by −1. Thereby, the player can freely adjust the luminance value of the decorative lamp LA in three stages. A specific operation method related to brightness adjustment by the player will be described later.

  By the way, this brightness adjustment is not limited to the decorative lamp LA, and the brightness of the lamp of the effect button device 16 can be adjusted in the same manner. However, the identification lamp device 46 (see FIG. 2), the special symbol display device 50 (see FIG. 2), and the normal symbol display device 51 (see FIG. 2) are used in order to reliably convey information related to the hit to the player. With respect to the above, it is preferable that the brightness cannot be adjusted.

<Explanation of operation method for volume adjustment / brightness adjustment by player>
Next, an operation method related to volume adjustment / brightness adjustment by the player will be described with reference to FIGS.

  The screen examples shown in FIGS. 11 to 15 are non-game state, that is, a screen for waiting for a customer waiting for a player indicating that the player is suspending the game (in the drawing, a special symbol (decorative symbol) is “123”. ”Shows a state of being stopped (see image P1)).

  When the special symbol (decorative symbol) shown in FIG. 11A is stopped in the state of “123” (see image P1), the screen is displayed on the liquid crystal display device 42. When any one of the up / down / left / right selection switches SW1 to SW4 of the switch 14 is pressed once, the screen shown in FIG. 11B is displayed on the liquid crystal display device 42. That is, a volume adjustment screen (see image P2) is displayed at the bottom of the screen (see image P1) indicating that the special symbol (decoration symbol) is stopped at the state of "123". A brightness adjustment screen (see image P3) is displayed on the left side of P1). Then, in the lower left corner of the screen of the liquid crystal display device 42, a screen (see image P4) for notifying the player that the volume adjustment / brightness adjustment can be performed using the front switch 14 is displayed.

  The volume adjustment shown in the image P2 can be adjusted in a plurality of levels (in the figure, 5 levels), “MIN” shown on the left in the figure is the minimum volume, and “MAX” shown on the right in the figure is the maximum volume. This indicates that there is a square frame that is filled in black among a plurality of square frames, and indicates the current volume adjustment stage (in the figure, the volume is currently adjusted in three stages). Further, the brightness adjustment shown in the image P3 can be adjusted in a plurality of steps (in the drawing, three steps), “MIN” shown in the lower part of the figure is the minimum brightness, and “MAX” shown in the figure is the highest brightness. A square frame that is blacked out among the plurality of square frames indicates the current brightness adjustment stage (in the figure, the brightness is currently adjusted in two stages).

  By the way, the volume adjustment image P2 and the brightness adjustment image P3 shown in FIG. 11B show the current setting contents, and the player can select one of the up / down / left / right selection switches SW1 to SW4 of the front switch 14. Volume adjustment and brightness adjustment are not performed depending on the operation by pressing one of them once (operation when changing from the screen example shown in FIG. 11A to the screen example shown in FIG. 11B). . Thus, the player can perform desired volume adjustment / brightness adjustment after firmly grasping the current volume adjustment stage and brightness adjustment stage.

  Thus, after the screen example shown in FIG. 11B is displayed on the liquid crystal display device 42, when the player presses the right selection switch SW4 (see FIG. 1) of the front switch 14 once to adjust the volume, As shown in FIG. 12 (a), the sound volume is increased by one level, and four of the five square frames are painted black (three square frames shown in FIG. 11 (b) are painted black). In other words, an image (see image P20) in which four square frames are painted black is displayed on the liquid crystal display device 42.

  On the other hand, after the screen example shown in FIG. 11B is displayed on the liquid crystal display device 42, when the player presses the left selection switch SW3 (see FIG. 1) of the front switch 14 once to adjust the volume, As shown in FIG. 12B, the one-step volume is lowered, and as shown in FIG. 12B, two of the five square frames are painted black (three square frames shown in FIG. 11B are painted black). The image (see the image P21) is displayed on the liquid crystal display device 42 in a state in which the two square frames are painted black.

  Thus, when the player adjusts the volume, when the right selection switch SW4 (see FIG. 1) of the front switch 14 is pressed to increase the volume, each time the player presses it, FIG. A plurality of square frames are painted black one by one so that the image P2 shown in FIG. 12A changes to the image P20 shown in FIG. 12A, so that the sound volume increases step by step. Further, when the left selection switch SW3 of the front switch 14 is pressed to reduce the volume, the image P2 shown in FIG. 11B changes to the image P21 shown in FIG. In addition, the plurality of square frames are whitened one by one, that is, are filled with white, and the volume is lowered one step at a time. However, as shown in FIG. 13A, when the plurality of square frames are all blacked out and the volume is adjusted to the maximum (see image P22), the player tries to further increase the volume of the front switch 14 When the right selection switch SW4 (see FIG. 1) is pressed, as shown in FIG. 13B, one square frame located on the left of the plurality of square frames is painted black, and the volume is adjusted to the minimum. (See image P23). Thereby, the player can know at an early stage that the volume cannot be maximized any more. In the state where the screen example shown in FIG. 13B is displayed on the liquid crystal display device 42, the player presses the left selection switch SW3 (see FIG. 1) of the front switch 14 to further reduce the volume. Even so, the display of the image P23 shown in FIG. 13B remains unchanged. That is, one square frame located on the left of the plurality of square frames is painted black, and a display indicating that the volume is minimum is maintained.

  By the way, the initial value of the volume adjustment that can be adjusted in a plurality of steps (five steps in the figure) is set at the third step. That is, it is set to the volume adjustment position shown in the image P2 shown in FIG. More specifically, the volume setting value can be set from “−2” to “2”. The volume setting value “−2” is the first level (“MIN” shown on the left in the drawing), “−” “1” corresponds to the second stage, “0” corresponds to the third stage, “+1” corresponds to the fourth stage, and “+2” corresponds to the fifth stage (“MAX” shown on the right in the drawing). Therefore, since the volume setting value is “0” when it is set at the third stage, the game site side employee stored in the table TB3 of the simple access code table SAC_TBL shown in FIG. The number of SACs of the reference value set by the staff or the like by the back switch 15 or the game side employees stored in the table TB22 of the volume output increase / decrease value table VO_REG_TBL shown in FIG. The volume is adjusted by the SAC number of the reference value. On the other hand, when the player presses the left selection switch SW3 (see FIG. 1) of the front switch 14 to lower the volume below the reference value, the volume setting value becomes “−2” or “−1”. The number of SACs stored in the table TB5 of the simple access code table SAC_TBL shown in (b), or the number of SACs stored in the table TB22 of the volume output increase / decrease value table VO_REG_TBL shown in FIG. The sound volume is adjusted based on the decrease value of the sound volume output data. On the other hand, when the player presses the right selection switch SW4 (see FIG. 1) of the front switch 14 to increase the volume from the reference value, the volume setting value becomes “+2” or “+1”. ), The number of SACs stored in the table TB4 of the simple access code table SAC_TBL, or the number of SACs stored in the table TB22 of the volume output increase / decrease value table VO_REG_TBL shown in FIG. 8 and the volume stored in the table TB23. The volume is adjusted based on the increase value of the output data.

  On the other hand, after the screen example shown in FIG. 11 (b) is displayed on the liquid crystal display device 42, when the player presses the upper selection switch SW1 (see FIG. 1) once in order to adjust the brightness, As shown in FIG. 14A, the one-step luminance is increased, and three of the three square frames are painted black (two square frames shown in FIG. 11B are painted black). The image (see the image P30) in which three square frames are filled with black from the current state is displayed on the liquid crystal display device 42.

  On the other hand, after the screen example shown in FIG. 11B is displayed on the liquid crystal display device 42, when the player presses the lower selection switch SW2 (see FIG. 1) once to adjust the brightness once. As shown in FIG. 14B, the one-step luminance is lowered, and one of the three square frames is painted black (two square frames shown in FIG. 11B are painted black). The image (see the image P31) in which one square frame is blacked out by one from the displayed state is displayed on the liquid crystal display device 42.

  Thus, when the player adjusts the brightness, when the upper selection switch SW1 (see FIG. 1) on the front switch 14 is pressed down to increase the brightness, each time the player presses the switch, FIG. As shown in FIG. 14 (a), the square frame is painted black one by one so that the luminance increases step by step. Further, when the lower selection switch SW2 of the front switch 14 is pressed to reduce the luminance, the image P3 shown in FIG. 11B changes to the image P31 shown in FIG. 14B each time the button is pressed once. In addition, a plurality of square frames are whitened one by one, that is, they are painted white, so that the luminance is lowered step by step. However, as shown in FIG. 15A, when the plurality of square frames are all blacked out and the brightness is adjusted to the maximum (see image P32), the player tries to further increase the brightness of the front switch 14 When the upper selection switch SW1 (see FIG. 1) is pressed, as shown in FIG. 15B, one of the square frames positioned below is blacked out to adjust the luminance to the minimum. (See image P33). Thereby, the player can know at an early stage that the luminance cannot be maximized any more. In the state where the screen example shown in FIG. 15B is displayed on the liquid crystal display device 42, the player presses the lower selection switch SW2 (see FIG. 1) of the front switch 14 to further reduce the luminance. However, the display of the image P33 shown in FIG. 15B remains unchanged. That is, one of the square frames positioned below among the plurality of square frames is painted black, and the display indicating that the luminance is minimum is maintained.

  By the way, the initial value of the brightness adjustment that can be adjusted in a plurality of stages (three stages in the figure) is set to the third stage, that is, the maximum (see the image P32 shown in FIG. 15A). ). More specifically, the luminance setting value can be set from “1” to “3”. The luminance setting value “1” is the first level (“MIN” shown on the left in the drawing), and “2” is The second stage, “3”, corresponds to the third stage (“MAX” shown in the figure). When it is set to the maximum, the brightness adjustment value 100% corresponding to the brightness setting value “3” stored in the table TB51 of the brightness adjustment table BR_TBL shown in FIG. The lamp will light up. On the other hand, when the player presses down the lower selection switch SW2 (refer to FIG. 1) once to lower the luminance from the initial value, it is stored in the table TB51 of the luminance adjustment table BR_TBL shown in FIG. At the brightness adjustment value 60% corresponding to the brightness setting value “2”, the decoration lamp LA and the lamp of the effect button device 16 are turned on, and the lower selection switch SW2 (see FIG. 1) of the front switch 14 is pressed once. Then, the decoration lamp LA and the lamp of the effect button device 16 are turned on at the luminance adjustment value 30% corresponding to the luminance setting value “1” stored in the table TB51 of the luminance adjustment table BR_TBL shown in FIG. Become.

<Explanation regarding timing at which player can adjust volume / brightness>
Next, the timing at which the player can adjust the volume / brightness as described above will be described with reference to FIGS.

<When game state is non-game state (waiting for customers)>
First, the case where the gaming state is a non-gaming state (waiting for customers) will be described.

  At the timing T1 shown in FIG. 16 (in the drawing, this time is set to 0 second (0 s)), that is, the fluctuation of the special symbol (decorative symbol) stops, and the first starting reserved ball number and the second starting reserved ball number When the effect control command DI_DATA (see FIG. 4) indicating that the player is suspending the game is transmitted from the main control board 60, the effect control CPU 900 causes the rear switch 15 (FIG. 6 (a)), that is, a customer waiting for a player regardless of whether or not the power saving mode is set (see table TB2 in FIG. 6 (b) or table TB21 in FIG. 8). A liquid crystal control command LCD_CMD (see FIG. 4) for causing the liquid crystal display device 42 to display a waiting screen is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a screen for waiting for a customer, as shown in FIGS. 17 (a) and 18 (a). In the figure, the special symbol (decorative symbol) is stopped at the state “123” (see image P1).

  The effect control CPU 900 is set to the power saving mode regardless of the adjustment contents of the back switch 15 (see FIG. 6A), that is, set to the power saving mode (see the table TB2 in FIG. 6B or the table TB21 in FIG. 8). Regardless of whether or not the lighting state of the decorative lamp LA is maintained, the lighting state before the gaming state becomes the non-gaming state (customer waiting state) remains unchanged. In addition, the effect control CPU 900 is set to the power saving mode regardless of the adjustment contents of the back switch 15 (see FIG. 6A), that is, set to the power saving mode (see the table TB2 in FIG. 6B or the table TB21 in FIG. 8). Regardless of whether or not the BGM is output, control is performed so that the BGM output from the speaker 11 is continuously output as it is.

  On the other hand, volume adjustment / brightness adjustment is possible at this time, but the effect control CPU 900 does not press any one of the up / down / left / right selection switches SW1 to SW4 of the front switch 14 once. Control is performed such that the screen (image P2, image P3, image P4) as shown in FIG. 11B is not displayed on the liquid crystal display device. That is, if the player does not operate anything, the display device 42 does not display a screen (image P2, image P3, image P4) as shown in FIG. By pressing any one of the up / down / left / right selection switches SW1 to SW4 once, the current volume setting value / brightness setting value that has not been subjected to volume adjustment / brightness adjustment by this pressing is displayed. . Thereby, the player can perform desired volume adjustment / brightness adjustment. Note that when the volume adjustment / brightness adjustment is performed, a sound (for example, a single sound such as “pico”) notifying the player of the change is output from the speaker 11.

  On the other hand, when the effect button device 16 is pressed at this time, a menu screen (not shown) is displayed on the liquid crystal display device 42. However, the image of the effect button device 16 for notifying the player of this is not displayed on the liquid crystal display device 42, and the lamp of the effect button device 16 is not lit, and is in a non-lighted state.

  Thus, an effect control command DI_DATA (see FIG. 4) such as a variation pattern command indicating that the player is playing a game such as an effect executed based on the lottery result from the main control board 60 at the timing T2 shown in FIG. If it is not transmitted until (in the drawing, this time is 30 seconds (30 s)), the above-described state is continued. Note that during the period of the timings T1 to T2, when the player adjusts the volume / brightness, this period becomes longer. This point will be described later.

  Next, the effect control CPU 900 performs an effect such that the player is executed based on the lottery result from the main control board 60 until time T2 shown in FIG. 16 (in the drawing, this time is 30 seconds (30 s)). If an effect control command DI_DATA (see FIG. 4) such as a variation pattern command indicating that a game is in progress is not transmitted, a screen for waiting for a customer displayed on the liquid crystal display device 42 (FIG. 17 (a), FIG. 18 (a)) is controlled so as to display continuously, but regardless of the adjustment contents of the rear switch 15 (see FIG. 6 (a)), that is, set to the power saving mode (see FIG. 6 (b)). Regardless of whether or not the table TB2 or the table TB21 of FIG. 8 is used), the lighting mode of the decorative lamp LA is controlled to be the waiting mode. Furthermore, the effect control CPU 900 is set to the power saving mode regardless of the adjustment contents of the back switch 15 (see FIG. 6A), that is, the table TB2 in FIG. 6B or the table TB21 in FIG. Regardless of whether the BGM is output or not, the BGM output from the speaker 11 is faded out, and control is performed so that the BGM is not output from the speaker 11.

  On the other hand, at this time, since the volume adjustment / brightness adjustment is possible regardless of the setting of the power saving mode, the player presses one of the up / down / left / right selection switches SW1 to SW4 of the front switch 14 once. Even if not, the liquid crystal display device 42 is automatically set to the volume adjustment screen (see image P2), the brightness adjustment screen (see image P3), and the like as shown in FIGS. 17 (b) and 18 (b). The effect control CPU 900 displays a liquid crystal control command LCD_CMD (see FIG. 4) related to these screens so that a screen (see image P4) for notifying the player that the volume adjustment / brightness adjustment can be performed using the front switch 14 is displayed. ) Is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a screen as shown in FIGS. 17B and 18B. Thereby, the player can perform volume adjustment / brightness adjustment while referring to the set value displayed on the liquid crystal display device 42. Then, when the player changes the volume, the effect control CPU 900 outputs the sound output from the speaker 11 according to the change contents (At this time, the BGM is faded out, so the BGM is output from the speaker 11. Control the volume to be higher or lower. Further, when the luminance is changed, the luminance of the decorative lamp LA that emits light is controlled to be increased or decreased according to the changed content. Thereby, the player can perform desired volume adjustment / brightness adjustment. Note that when the volume / luminance is changed, a sound (for example, a single sound such as “pico”) for notifying the player of the change is output from the speaker 11.

  On the other hand, when the effect button device 16 is pressed at this time, a menu screen (not shown) is displayed on the liquid crystal display device 42. Therefore, the effect control CPU 900 displays the screen of the effect button device 16 for informing this to the player ( A liquid crystal control command LCD_CMD (see FIG. 4) for displaying the images P5 (see FIG. 17B and FIG. 18B) is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls so that the image P5 shown in FIGS. 17B and 18B is displayed on the liquid crystal display device. Further, the effect control CPU 900 performs control so that the lamp of the effect button device 16 is lit. As a result, when the player presses the effect button device 16, a menu screen (not shown) is displayed on the liquid crystal display device. When a menu screen (not shown) is displayed on the liquid crystal display device 42, the front switch 14 is used for selecting and determining the contents of the menu screen. Therefore, if there is no volume adjustment / brightness adjustment item in the contents of the menu screen, the volume adjustment / brightness adjustment cannot be performed.

  Thus, an effect control command DI_DATA (see FIG. 4) such as a variation pattern command indicating that the player is playing a game such as an effect executed based on the lottery result from the main control board 60 is at the timing T3 shown in FIG. If it is not transmitted until (in the drawing, this time is 180 seconds (180 s)), the above-described state is continued. In addition, during the period of timing T2-T3, when a player performs volume adjustment / brightness adjustment, this period becomes long, and this point will be described later.

  Next, the effect control CPU 900 performs an effect such that the player is executed based on the lottery result from the main control board 60 until time T3 shown in FIG. 16 (in the drawing, this time is 180 seconds (180 s)). If an effect control command DI_DATA (see FIG. 4) such as a variation pattern command indicating that a game is in progress is not transmitted, the adjustment content of the back switch 15, that is, the adjustment signal BSW_DATA (see FIG. 4) is confirmed. If it is not adjusted to any one of “3” to “5” (see FIG. 6A), the effect control CPU 900 is set to the power saving mode (the table TB2 in FIG. 6B or the table in FIG. 8). The liquid crystal control command LCD_CMD (see FIG. 4) for displaying a screen as shown in FIG. 17C is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display the model image demo movie (see image P6).

  Further, the effect control CPU 900 performs control so that the light emission mode of the decorative lamp LA becomes the light emission mode for the demo movie. Furthermore, the effect control CPU 900 performs control so that BGM is not output from the speaker 11.

  On the other hand, if the adjustment content of the back switch 15 is adjusted to any one of “3” to “5” (see FIG. 6A), the effect control CPU 900 is set to the power saving mode (FIG. 6B). And the liquid crystal control command LCD_CMD (see FIG. 4) for displaying a screen as shown in FIG. 18C is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a screen (see image P60) indicating that the model image demo movie and power saving are being performed.

  Further, the effect control CPU 900 performs control so that the light emission mode of the decoration lamp LA becomes the light emission mode for power saving. Furthermore, the effect control CPU 900 performs control so that BGM is not output from the speaker 11.

  On the other hand, at this time, the volume adjustment / brightness adjustment is possible regardless of the setting of the power saving mode. Therefore, the liquid crystal display device 42 displays the volume adjustment screen (see image P2) displayed at the timing T2, and the brightness adjustment. Screen (see image P3) and a screen (see image P4) for notifying the player that the volume adjustment / brightness adjustment can be performed using the front switch 14 are continuously displayed (FIGS. 17C and 18C). c)). Thereby, the player can perform volume adjustment / brightness adjustment while referring to the set value displayed on the liquid crystal display device 42. When the player changes the volume, the effect control CPU 900 performs control so that the volume of the sound output from the speaker 11 is increased or decreased according to the changed content. Further, when the luminance is changed, the luminance of the decorative lamp LA that emits light is controlled to be increased or decreased according to the changed content. Thereby, the player can perform desired volume adjustment / brightness adjustment. However, when the power saving mode is set (see table TB2 in FIG. 6B or table TB21 in FIG. 8), the luminance of the decorative lamp LA that emits light only when the luminance is changed is changed. The light emission mode for power saving is otherwise increased or decreased, or the brightness of the decorative lamp LA that emits light is not increased or decreased, and the light emission mode for power saving is maintained. It is preferable to do this. Note that when the volume / luminance is changed, a sound (for example, a single sound such as “pico”) for notifying the player of the change is output from the speaker 11.

  On the other hand, regardless of the setting of the power saving mode, when the effect button device 16 is pressed, a menu screen (not shown) is displayed on the liquid crystal display device 42, so the effect control CPU 900 notifies the player of this. For this purpose, a liquid crystal control command LCD_CMD (see FIG. 4) for displaying the screen of the effect button device 16 (see the image P5 shown in FIGS. 17C and 18C) is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control substrate 120 controls the liquid crystal display device 42 so that the image P5 shown in FIGS. 17C and 18C is displayed on the liquid crystal display device 42. Further, the effect control CPU 900 performs control so that the lamp of the effect button device 16 is lit. As a result, when the player presses the effect button device 16, a menu screen (not shown) is displayed on the liquid crystal display device. When a menu screen (not shown) is displayed on the liquid crystal display device 42, the front switch 14 is used for selecting and determining the contents of the menu screen. Therefore, if there is no volume adjustment / brightness adjustment item in the contents of the menu screen, the volume adjustment / brightness adjustment cannot be performed.

  Thus, an effect control command DI_DATA (see FIG. 4) such as a variation pattern command indicating that the player is playing a game such as an effect executed based on the lottery result from the main control board 60 at the timing T4 shown in FIG. If it is not transmitted until then, the above-mentioned state will be continued. Note that during the period of timing T3 to T4, when the player performs volume adjustment / brightness adjustment, this period becomes longer. This point will be described later.

  Next, the effect control CPU 900 performs an effect control command such as a variation pattern command indicating that the player is playing a game such as a game that is executed based on the lottery result from the main control board 60 until time T4 shown in FIG. If DI_DATA (see FIG. 4) is not transmitted, the power saving mode is not set (see table TB2 in FIG. 6B or table TB21 in FIG. 8). A liquid crystal control command LCD_CMD (see FIG. 4) for displaying a company logo (see image P7) as shown is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 performs control so that the image P7 shown in FIG.

  Further, the effect control CPU 900 performs control so that the light emission mode of the decorative lamp LA becomes the light emission mode for the demo movie. Furthermore, the effect control CPU 900 performs control so that BGM is not output from the speaker 11.

  On the other hand, if the power saving mode is set (see table TB2 in FIG. 6B or table TB21 in FIG. 8), the effect control CPU 900 displays the company logo (see FIG. 18D) on the liquid crystal display device 42. A liquid crystal control command LCD_CMD (see FIG. 4) for displaying the image P7) is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 performs control so that the image P7 shown in FIG.

  Further, the effect control CPU 900 performs control so that the light emission mode of the decoration lamp LA becomes the light emission mode for power saving. Furthermore, the effect control CPU 900 performs control so that BGM is not output from the speaker 11.

  On the other hand, the volume control / brightness adjustment is possible regardless of the setting of the power saving mode at this time, but the effect control CPU 900 allows the player to select any one of the up / down / left / right selection switches SW1 to SW4 of the front switch 14. If one is not pressed once, the volume adjustment screen (see image P2), the brightness adjustment screen (see image P3), and the player can be notified of the volume adjustment / brightness adjustment using the front switch 14. Control is performed so that the screen (see image P4) is not displayed on the liquid crystal display device. That is, if no operation is performed by the player, the display device 42 includes a volume adjustment screen (see image P2), a brightness adjustment screen (see image P3), and the player using the front switch 14 to adjust the volume. A screen (see image P4) for notifying that the brightness can be adjusted is not displayed, and the player presses any one of the up / down / left / right selection switches SW1 to SW4 of the front switch 14 once. The current volume setting value / brightness setting value that has not been subjected to volume adjustment / brightness adjustment by pressing is displayed. Thereby, the player can perform desired volume adjustment / brightness adjustment. However, when the power saving mode is set (see table TB2 in FIG. 6B or table TB21 in FIG. 8), the luminance of the decorative lamp LA that emits light only when the luminance is changed is changed. The light emission mode for power saving is otherwise increased or decreased, or the brightness of the decorative lamp LA that emits light is not increased or decreased, and the light emission mode for power saving is maintained. It is preferable to do this. Note that when the volume adjustment / brightness adjustment is performed, a sound (for example, a single sound such as “pico”) notifying the player of the change is output from the speaker 11.

  On the other hand, when the effect button device 16 is pressed regardless of the setting of the power saving mode, a menu screen (not shown) is displayed on the liquid crystal display device 42. However, the image of the effect button device 16 for notifying the player of this is not displayed on the liquid crystal display device 42, and the lamp of the effect button device 16 is not lit, and is in a non-lighted state.

  Accordingly, at timing T4 shown in FIG. 16, only the company logo (see image P7) is displayed on the liquid crystal display device 42 as shown in FIGS. 17 (d) and 18 (d). Thereby, a player can be made to recognize a corporate logo firmly.

  Thus, an effect control command DI_DATA (see FIG. 4) such as a variation pattern command indicating that the player is playing a game such as an effect executed based on the lottery result from the main control board 60 is at the timing T5 shown in FIG. If it is not transmitted until then, the above-mentioned state will be continued. Note that during the period of timings T4 to T5, when the player adjusts the volume / brightness, this period becomes longer. This point will be described later.

  Next, the effect control CPU 900 produces an effect control command such as a variation pattern command indicating that the player is playing a game such as a game that is executed based on the lottery result from the main control board 60 until time T5 shown in FIG. If DI_DATA (see FIG. 4) is not transmitted, if the power saving mode is not set (see table TB2 in FIG. 6B or table TB21 in FIG. 8), the liquid crystal is displayed as shown in FIG. A liquid crystal control command LCD_CMD (see FIG. 4) for causing the display device 42 to display a customer waiting screen is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display the screen shown in FIG. In the figure, the special symbol (decorative symbol) is stopped at the state “123” (see image P1).

  Further, the effect control CPU 900 performs control so that the light emission mode of the decorative lamp LA becomes the light emission mode for waiting for customers. Furthermore, the effect control CPU 900 performs control so that BGM is not output from the speaker 11.

  On the other hand, if the power saving mode is set (see table TB2 in FIG. 6B or table TB21 in FIG. 8), the effect control CPU 900 waits for the customer in the liquid crystal display device 42 as shown in FIG. A liquid crystal control command LCD_CMD (see FIG. 4) for displaying a screen for power saving and a screen indicating that power saving is in progress (see image P8) is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display the screen shown in FIG. In the figure, the special symbol (decorative symbol) is stopped at the state “123” (see image P1).

  Further, the effect control CPU 900 performs control so that the light emission mode of the decoration lamp LA becomes the light emission mode for power saving. Furthermore, the effect control CPU 900 performs control so that BGM is not output from the speaker 11.

  On the other hand, at this time, since the volume adjustment / brightness adjustment is possible regardless of the setting of the power saving mode, the player presses one of the up / down / left / right selection switches SW1 to SW4 of the front switch 14 once. Even if not, the liquid crystal display device 42 is automatically displayed on the volume adjustment screen (see image P2), the brightness adjustment screen (see image P3), as shown in FIGS. The effect control CPU 900 displays a liquid crystal control command LCD_CMD (see FIG. 4) related to these screens so that a screen (see image P4) for notifying the player that the volume adjustment / brightness adjustment can be performed using the front switch 14 is displayed. ) Is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a screen as shown in FIGS. 17 (e) and 18 (e). Thereby, the player can perform volume adjustment / brightness adjustment while referring to the set value displayed on the liquid crystal display device 42. When the player changes the volume, the effect control CPU 900 performs control so that the volume of the sound output from the speaker 11 is increased or decreased according to the changed content. Further, when the luminance is changed, the luminance of the decorative lamp LA that emits light is controlled to be increased or decreased according to the changed content. Thereby, the player can perform desired volume adjustment / brightness adjustment. However, when the power saving mode is set (see table TB2 in FIG. 6B or table TB21 in FIG. 8), the luminance of the decorative lamp LA that emits light only when the luminance is changed is changed. The light emission mode for power saving is otherwise increased or decreased, or the brightness of the decorative lamp LA that emits light is not increased or decreased, and the light emission mode for power saving is maintained. It is preferable to do this. Note that when the volume / luminance is changed, a sound (for example, a single sound such as “pico”) for notifying the player of the change is output from the speaker 11.

  On the other hand, regardless of the setting of the power saving mode, when the effect button device 16 is pressed, a menu screen (not shown) is displayed on the liquid crystal display device 42, so the effect control CPU 900 notifies the player of this. A liquid crystal control command LCD_CMD (see FIG. 4) for displaying the screen of the effect button device 16 (see image P5 shown in FIGS. 17 (e) and 18 (e)) is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a screen as shown in FIGS. 17 (e) and 18 (e). Then, the effect control CPU 900 performs control so that the lamp of the effect button device 16 is lit. As a result, when the player presses the effect button device 16, a menu screen (not shown) is displayed on the liquid crystal display device. When a menu screen (not shown) is displayed on the liquid crystal display device 42, the front switch 14 is used for selecting and determining the contents of the menu screen. Therefore, if there is no volume adjustment / brightness adjustment item in the contents of the menu screen, the volume adjustment / brightness adjustment cannot be performed.

  Thus, an effect control command DI_DATA (see FIG. 4) such as a variation pattern command indicating that the player is playing a game such as an effect executed based on the lottery result from the main control board 60 is at timing T6 shown in FIG. If it is not transmitted until then, the above-mentioned state will be continued. Note that during the period of timing T5 to T6, when the player performs volume adjustment / brightness adjustment, this period becomes longer, and this point will be described later.

  Next, at timing T6 shown in FIG. 16, when the presentation control command DI_DATA (see FIG. 4) is transmitted from the main control board 60 indicating that the player is playing (special symbol variation start), the presentation control is performed. The CPU 900 ends the non-game state (waiting for customers) and starts changing the special symbol. At timing T6, if the presentation control command DI_DATA (see FIG. 4) indicating that the player is playing is not transmitted from the main control board 60, the presentation control CPU 900 again performs processing at timings T3 to T6. Will be repeated.

<When the game state is playing>
Next, a case where the gaming state is in gaming will be described.

  When the presentation control command DI_DATA (see FIG. 4) is transmitted from the main control board 60 to indicate that the player is playing a game (special symbol variation start) at the timing T6 shown in FIG. Then, a liquid crystal control command LCD_CMD (see FIG. 4) for causing the liquid crystal display device 42 to display a screen in which the special symbol is changed is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a special symbol variation screen (see image P10) as shown in FIG.

  At this time, since the volume adjustment / brightness adjustment is possible, when the player presses one of the up / down / left / right selection switches SW1 to SW4 of the front switch 14 once, the effect control CPU 900 displays FIG. The volume adjustment screen (see image P200), the brightness adjustment screen (see image P300) with high transparency (shown by broken lines in the figure), and the player using the front switch 14 as shown in FIG. / A liquid crystal control command LCD_CMD (see FIG. 4) for displaying a screen (see image P400) for notifying that brightness adjustment is possible is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a screen as shown in FIG. Thereby, even during the game (during the change of the special symbol), the player can perform the volume adjustment / luminance adjustment while referring to the set value displayed on the liquid crystal display device 42. Then, when the player changes the volume, the effect control CPU 900 controls to increase or decrease the volume of the sound output from the speaker 11 according to the changed content. Further, when the luminance is changed, the luminance of the decorative lamp LA that emits light is controlled to be increased or decreased according to the changed content. Thereby, the player can perform desired volume adjustment / brightness adjustment. Note that when the volume / brightness is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11.

  Thus, by changing the display of the volume adjustment / brightness adjustment screen between the game and the non-game (waiting for customers), the player displayed on the liquid crystal display device 42 knows the best or the player It is possible to prevent the display of whether or not the special gaming state (so-called “big hit”) is advantageous. Note that the volume / brightness adjustment screen displayed during the game is not limited to that shown in FIG. 20A, but the volume adjustment screen (see image P201) shown in FIG. Compared to during non-game (waiting for customers), such as a screen (see image P301) and a screen (see image P401) for notifying the player that volume adjustment / brightness adjustment can be performed using the front switch 14. (See FIGS. 17 (b), (c), (e), FIGS. 18 (b), (c), (e)) The display may be made smaller or displayed at the corners of the screen.

  Next, when the presentation control command DI_DATA (refer to FIG. 4) is transmitted from the main control board 60 to the effect control CPU 900 at the timing T7 shown in FIG. A liquid crystal control command LCD_CMD (see FIG. 4) for causing the liquid crystal display device 42 to display a screen for stopping the transmission is transmitted to the liquid crystal control board 120. In response, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a special symbol variation stop screen (see image P1), as shown in FIG.

  At this time, the volume adjustment / brightness adjustment is disabled as shown in FIG. 19, so that the effect control CPU 900 is informed on the liquid crystal display device 42 in order to notify the player of this fact as shown in FIG. , (B) A liquid crystal control command for erasing the volume / brightness adjustment screen (see images P200, P201, P300, P301, P400, and P401) and causing the volume / brightness adjustment impossible display (see image P9). LCD_CMD (see FIG. 4) is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display that the volume / brightness cannot be adjusted (see image P9), as shown in FIG.

  Thus, the volume adjustment / brightness adjustment cannot be performed when the special symbol that is the result of the game is stopped, so that the liquid crystal display device 42 can be adjusted to the volume as shown in FIGS. 20 (a) and 20 (b). The brightness adjustment screen (see images P200, P201, P300, P301, P400, and P401) is not displayed, so that it is possible to avoid a situation in which it becomes difficult to see the game result. This makes it possible to perform appropriate volume adjustment / luminance adjustment during the game.

  In other words, in the prior art, the volume / brightness adjustment can be performed when the game is stopped, but the volume / brightness adjustment cannot be performed during the game. Therefore, it is conceivable that volume adjustment / brightness adjustment can be performed during the game, but a display relating to the volume adjustment / brightness adjustment is displayed on the liquid crystal display device 42, so that the result of the game, such as when the special symbol is stopped, etc. There was a problem that it may affect the display of.

  Therefore, in the present embodiment, volume adjustment / brightness adjustment is disabled when the special symbol that is the result of the game is stopped. As a result, it is possible to avoid a situation in which it is difficult to see the result of the game, so that appropriate volume adjustment / luminance adjustment can be performed during the game.

  In the case where the gaming state is a certain change state (probability variation state where the winning lottery probability is higher than usual) and a short time state, as shown in FIG. 21B, a volume adjustment / brightness adjustment screen (image P201). , P301, P401) may not be erased, and only volume adjustment / brightness adjustment may be disabled. In the case of the probable change state and the short time state, the special symbol change cycle is fast, so if the display of the volume adjustment / brightness adjustment screen (see images P201, P301, P401) is turned off when the special symbol is stopped, the player becomes uncomfortable. To feel. The display of the volume adjustment / brightness adjustment screen may be images P200, P300, and P400 shown in FIG.

  By the way, in the present embodiment, a volume adjustment / brightness adjustment screen (see images P200, P201, P300, P301, P400, and P401) as shown in FIGS. 20 (a) and 20 (b) is displayed on the liquid crystal display device 42. The volume adjustment / brightness adjustment cannot be performed when the special symbol that is the result of the game is stopped, but the volume adjustment / brightness adjustment is made effective, and the liquid crystal display device 42 is displayed in FIGS. The volume adjustment / brightness adjustment screen (see images P200, P201, P300, P301, P400, and P401) as shown in FIG. Even in this way, it is possible to avoid a situation in which it is difficult to see the result of the game, so that appropriate volume adjustment / luminance adjustment can be performed during the game. Note that the volume adjustment / brightness adjustment screen may be displayed on the liquid crystal display device 42 when the change of the special symbol is started or when the game is not playing (waiting for customers).

  In addition, when the gaming state is a probable change state or a short time state, the change cycle of the special symbol is fast, so the volume adjustment / brightness adjustment may be enabled without being disabled.

  Next, when the effect control command DI_DATA (see FIG. 4) is transmitted from the main control board 60 to the effect control CPU 900 at the timing T8 shown in FIG. A liquid crystal control command LCD_CMD (see FIG. 4) for causing the liquid crystal display device 42 to display a screen for starting the transmission is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a special symbol variation screen (see image P10) as shown in FIG.

  At this time, since volume adjustment / brightness adjustment is possible, in order to notify the player of this, the effect control CPU 900 displays a volume adjustment / brightness adjustment screen (image P201, image P201) on the liquid crystal display device 42. A liquid crystal control command LCD_CMD (refer to FIG. 4) for displaying “P301, P401” is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a volume / brightness adjustment screen (see images P201, P301, and P401) as shown in FIG. Thereby, the player can know at an early stage that the volume adjustment / brightness adjustment is possible. The display of the volume adjustment / brightness adjustment screen may be images P200, P300, and P400 shown in FIG.

  At this time, when the player changes the volume, the effect control CPU 900 performs control so that the volume of the sound output from the speaker 11 is increased or decreased according to the change content. Further, when the luminance is changed, the luminance of the decorative lamp LA that emits light is controlled to be increased or decreased according to the changed content. Thereby, the player can perform desired volume adjustment / brightness adjustment. Note that when the volume / brightness is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11.

  By the way, in the present embodiment, as shown in FIG. 22, the volume adjustment / brightness adjustment screen (see images P201, P301, and P401) is displayed at the start of the change of the special symbol. 23, first, a special symbol variation screen (see image P10 in FIG. 23A) is displayed on the liquid crystal display device 42. After a predetermined time has elapsed, a volume adjustment / brightness adjustment screen (FIG. 23) is displayed. (B) (see images P201, P301, and P401). Even in this way, the player can quickly know that the volume adjustment / luminance adjustment is possible.

  On the other hand, when this special symbol variation is a variation related to a special gaming state (so-called “big hit”) advantageous to the player, a notice effect (not shown) is displayed on the liquid crystal display device 42, or When the player operates the front switch 14 without displaying a screen prompting the player to operate the front switch 14 when not displayed, the speaker 11 (see FIG. 1) When a so-called concealed button effect is generated, such as a big hit definite sound is output, the player can adjust the volume / brightness by operating the front switch 14, and also perform the concealed button effect operation. It can be carried out. Accordingly, it is possible to provide the player with a new gameability that some kind of effect occurs despite the volume adjustment / brightness adjustment being performed by the front switch 14. It should be noted that such volume control / brightness adjustment operations and production operations using the front switch 14 are only hidden button productions, and in the case of normal notice productions, only the volume adjustment / brightness adjustment operations are not used. A front switch 14 is used.

  In other words, in the prior art, the volume / brightness adjustment can be performed when the game is stopped, but the volume / brightness adjustment cannot be performed during the game. Therefore, it may be possible to adjust the volume / brightness during the game, but there is a problem that the front switch 14 cannot be used in the notice effect.

  Therefore, in the present embodiment, the volume adjustment / brightness adjustment operation and the effect operation by the front switch 14 are used together only for the so-called hidden button effect among the notice effects. This makes it possible to perform appropriate volume adjustment / luminance adjustment during the game.

  As described above, the hidden button effect is not limited to the case where a big hit confirmation sound such as “cue” is output from the speaker 11 (see FIG. 1), but a special gaming state advantageous to the player (so-called “big hit”). There are various methods such as a case where the special symbol has a high reliability and the decorative lamp LA disposed on the game board 4 is flashed.

  Next, when the presentation control command DI_DATA (refer to FIG. 4) is transmitted from the main control board 60 to the effect control CPU 900 at the timing T9 shown in FIG. A liquid crystal control command LCD_CMD (see FIG. 4) for causing the liquid crystal display device 42 to display a screen for stopping the transmission is transmitted to the liquid crystal control board 120. In response, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a special symbol variation stop screen (see image P100), as shown in FIG.

  At this time, the volume adjustment / brightness adjustment is disabled as shown in FIG. 19, so that the effect control CPU 900 is informed on the liquid crystal display device 42 in order to notify the player of this fact as shown in FIG. , (B) Liquid crystal control for turning off the volume / brightness adjustment screens (see images P200, P201, P300, P301, P400, and P401) and displaying a screen (see image P9) where the volume / brightness cannot be adjusted. A command LCD_CMD (see FIG. 4) is transmitted to the liquid crystal control board 120. In response to this, the liquid crystal control board 120 controls the liquid crystal display device 42 to display a screen (see image P9) incapable of volume / brightness adjustment, as shown in FIG.

  Next, when the presentation control command DI_DATA (see FIG. 4) indicating the start of the big hit is transmitted from the main control board 60 at the timing T10 shown in FIG. 19, the presentation control CPU 900 enables the volume adjustment / luminance adjustment. With this as an opportunity, the volume adjustment / brightness adjustment screen (see images P201, P301, and P401) shown in FIG. 24B is prevented from being displayed on the liquid crystal display device 42. When any one of the selection switches SW1 to SW4 is pressed once, a volume adjustment / brightness adjustment screen (see images P201, P301, and P401) shown in FIG. 24B is displayed on the liquid crystal display device 42. To control. Thereby, during the big hit, it is possible to meet the desire of the player who does not desire volume adjustment / brightness adjustment. The display of the volume adjustment / brightness adjustment screen may be images P200, P300, and P400 shown in FIG.

  At this time, when the player changes the volume, the effect control CPU 900 performs control so that the volume of the sound output from the speaker 11 is increased or decreased according to the change content. Further, when the luminance is changed, the luminance of the decorative lamp LA that emits light is controlled to be increased or decreased according to the changed content. Thereby, the player can perform desired volume adjustment / brightness adjustment. Note that when the volume / brightness is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11.

  By the way, when displaying the volume adjustment / brightness adjustment screen on the liquid crystal display device 42, when the first start holding ball number, the second start holding ball number, and the fourth symbol are displayed on the liquid crystal display device 42, It is preferable to display a volume adjustment / brightness adjustment screen on the liquid crystal display device 42 so as not to overlap the display.

<When game state is error>
Next, a case where the gaming state is an error will be described.

  FIG. 25 shows a table summarizing a case where the gaming state results in an error. In the error list ER_HY shown in FIG. 25, an error content table HY1 is described. The error contents described in the error content table HY1 will be described in order from the top. When the door opening sensor 55 (see FIG. 3) detects that the glass door frame 5 is opened, the main control board. From 60, an effect control command DI_DATA (see FIG. 4) indicating that the glass door frame 5 has been opened is transmitted. In response to this, the effect control CPU 900 transmits a liquid crystal control command LCD_CMD (see FIG. 4) for causing the liquid crystal display device 42 to display “the door is open” (see table HY2 of the liquid crystal display) to the liquid crystal control board 120. As a result, the message “the door is open” is displayed on the liquid crystal display device 42. Further, the effect control CPU 900 controls to turn off the decoration lamp LA arranged on the game board 4 (see FIG. 2) (see the table HY3 of the board lamp), and the effect button device 16 (see FIG. 1). The lamps are controlled to be turned off (refer to the frame lamp table HY4), and among the decorative lamps LA arranged on the front frame 3, the monochrome decorative lamp LA is controlled to be turned off (frame lamp table HY4). (Refer to) The three-color decoration lamp LA is controlled to blink in red (see the frame lamp table HY4). This blinking is controlled to blink for a predetermined time even after the glass door frame 5 is closed. Then, the production control CPU 900 performs control so that an error sound is output from the speaker 11 while the door is open, and no error sound is output after the door is closed (see voice table HY5).

  At this time, volume adjustment / brightness adjustment is possible (see Table HY6 of “Volume Adjustment” and “Brightness Adjustment”), but the volume output from the speaker 11 is output as an error volume (table of “Volume Mode”). The brightness of the decorative lamp LA is emitted with the brightness for error (see Table HY6 of “Luminance Mode”). Therefore, even if the player changes the volume, the volume of the sound output from the speaker 11 remains the error volume. Even if the luminance is changed, the luminance of the decorative lamp LA that emits light remains the error luminance. When the volume / brightness is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11, and the volume adjustment / brightness adjustment screen is also displayed on the liquid crystal display. Not displayed on device 42. Therefore, the player cannot confirm what volume / brightness has been changed during the error, but since the change content is stored in the effect control RAM 900a (see FIG. 4), the error is released. In this case, the sound output from the speaker 11 is output at the changed volume, and the brightness of the decorative lamp LA is emitted with the changed brightness. Thereby, the player can confirm what kind of volume / brightness has been changed.

  On the other hand, if any abnormality occurs in the big winning opening switch 47a (see FIG. 3) and the general winning opening switch 49a (see FIG. 3), the big winning opening switch 47a (see FIG. 3), the general winning opening from the main control board 60. An effect control command DI_DATA (see FIG. 4) indicating that some abnormality has occurred is transmitted to the switch 49a (see FIG. 3). In response to this, the production control CPU 900 transmits a liquid crystal control command LCD_CMD (see FIG. 4) for causing the liquid crystal display device 42 to display “winning mouth switch error” (see table HY2 of liquid crystal display) to the liquid crystal control board 120, Accordingly, a display of “winning mouth switch error” is displayed on the liquid crystal display device 42. Further, the effect control CPU 900 controls to turn off the decoration lamp LA arranged on the game board 4 (see FIG. 2) (see the table HY3 of the board lamp), and the effect button device 16 (see FIG. 1). The lamps are controlled to be turned off (refer to the frame lamp table HY4), and among the decorative lamps LA arranged on the front frame 3, the monochrome decorative lamp LA is controlled to be turned off (frame lamp table HY4). (Refer to) The three-color decoration lamp LA is controlled to blink in red (see the frame lamp table HY4). Then, the effect control CPU 900 performs control so that the fraud detection warning sound (see the voice table HY5) is output from the speaker 11.

  At this time, volume adjustment / brightness adjustment is possible (see Table HY6 of “Volume Adjustment” and “Brightness Adjustment”), but the volume output from the speaker 11 is output as an error volume (table of “Volume Mode”). The brightness of the decorative lamp LA is emitted with the brightness for error (see Table HY6 of “Luminance Mode”). Therefore, even if the player changes the volume, the volume of the sound output from the speaker 11 remains the error volume. Even if the luminance is changed, the luminance of the decorative lamp LA that emits light remains the error luminance. When the volume / brightness is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11, and the volume adjustment / brightness adjustment screen is also displayed on the liquid crystal display. Not displayed on device 42. Therefore, the player cannot confirm what volume / brightness has been changed during the error, but since the change content is stored in the effect control RAM 900a (see FIG. 4), the error is released. In this case, the sound output from the speaker 11 is output at the changed volume, and the brightness of the decorative lamp LA is emitted with the changed brightness. Thereby, the player can confirm what kind of volume / brightness has been changed.

  On the other hand, if any of the radio wave sensor 56 (see FIG. 3), the magnetic sensor 57 (see FIG. 3), and the vibration sensor 58 (see FIG. 3) is detected, the main control board 60 generates the illegal action. An effect control command DI_DATA (see FIG. 4) indicating that this has been done is transmitted. In response to this, the effect control CPU 900 causes the liquid crystal display device 42 to receive a “radio wave sensor error” (see table HY2 of the liquid crystal display), “magnetic sensor error” (see table HY2 of the liquid crystal display), and “vibration sensor error” (liquid crystal display). A liquid crystal control command LCD_CMD (see FIG. 4) for displaying any one of the display tables HY2) is transmitted to the liquid crystal control board 120, and the “radio wave sensor error”, “magnetic sensor error”, “ One of the “vibration sensor error” is displayed. Further, the effect control CPU 900 controls to turn off the decoration lamp LA arranged on the game board 4 (see FIG. 2) (see the table HY3 of the board lamp), and the effect button device 16 (see FIG. 1). The lamps are controlled to be turned off (refer to the frame lamp table HY4), and among the decorative lamps LA arranged on the front frame 3, the monochrome decorative lamp LA is controlled to be turned off (frame lamp table HY4). (Refer to) The three-color decoration lamp LA is controlled to blink in red (see the frame lamp table HY4). Then, the effect control CPU 900 performs control so that the fraud detection warning sound (see the voice table HY5) is output from the speaker 11.

  At this time, volume adjustment / brightness adjustment is possible (see Table HY6 of “Volume Adjustment” and “Brightness Adjustment”), but the volume output from the speaker 11 is output as an error volume (table of “Volume Mode”). The brightness of the decorative lamp LA is emitted with the brightness for error (see Table HY6 of “Luminance Mode”). Therefore, even if the player changes the volume, the volume of the sound output from the speaker 11 remains the error volume. Even if the luminance is changed, the luminance of the decorative lamp LA that emits light remains the error luminance. When the volume / brightness is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11, and the volume adjustment / brightness adjustment screen is also displayed on the liquid crystal display. Not displayed on device 42. Therefore, the player cannot confirm what volume / brightness has been changed during the error, but since the change content is stored in the effect control RAM 900a (see FIG. 4), the error is released. In this case, the sound output from the speaker 11 is output at the changed volume, and the brightness of the decorative lamp LA is emitted with the changed brightness. Thereby, the player can confirm what kind of volume / brightness has been changed.

  On the other hand, when the RAM clear switch 603 that can clear the main control RAM 602 that can be used by a game hall employee or the like is pressed, an effect control command DI_DATA (FIG. 5) indicating that the RAM clear switch 603 has been pressed by the main control board 60. 4) is transmitted. In response to this, the effect control CPU 900 displays a liquid crystal control command LCD_CMD (see FIG. 5) on the liquid crystal display device 42 to display a state where the special symbol (decorative symbol) is stopped with the state “731” (refer to the table HY2 of the liquid crystal display). 4) is transmitted to the liquid crystal control board 120, and the state where the special symbol (decorative symbol) is stopped in the state of "731" is displayed on the liquid crystal display device 42. In addition, the effect control CPU 900 performs control so that all of the decoration lamps LA arranged on the game board 4 (see FIG. 2) are lit (see the table lamp surface HY3), 3 The color decoration lamp LA is controlled to be fully lit in white (see table HY3 of the panel lamp), and the lamp of the effect button device 16 (see FIG. 1) is controlled to be fully lit in white (frame lamp table). HY4), and control is performed so that all of the decoration lamps LA arranged on the front frame 3 are lit (see Table HY4 of the frame lamp), and the three-color decoration lamps LA are turned white. To turn on all the lights (see Table HY4 of the frame lamp). Then, the effect control CPU 900 controls to output a sound (refer to the sound table HY5) indicating that the RAM clear switch 603 is pressed from the speaker 11.

  At this time, volume adjustment / brightness adjustment is not possible (see Table HY6 of “Volume Adjustment” and “Brightness Adjustment”), and an error volume is output from the speaker 11 (see Table HY6 of “Volume Mode”). The luminance of the lamp LA is emitted with error luminance (see Table HY6 of “Luminance Mode”).

  On the other hand, when a supply replenishment signal (status signal STAY_SIGNAL) is transmitted from the payout control board 70, the main control board 60 transmits an effect control command DI_DATA (see FIG. 4) indicating that replenishment has occurred. In response to this, the production control CPU 900 controls the liquid crystal control command LCD_CMD (refer to FIG. 4) to display on the liquid crystal display device 42 “Please call a clerk” (refer to the table HY2 of the liquid crystal display). The data is transmitted to the substrate 120, so that the liquid crystal display 42 displays "There are not enough spheres. Please call an attendant". Further, the effect control CPU 900 controls to turn off the decoration lamp LA arranged on the game board 4 (see FIG. 2) (see the table HY3 of the board lamp), and the effect button device 16 (see FIG. 1). The lamps are controlled to be turned off (refer to the frame lamp table HY4), and among the decorative lamps LA arranged on the front frame 3, the monochrome decorative lamp LA is controlled to be turned off (frame lamp table HY4). (Refer to) The three-color decorative lamp LA is controlled to blink in white (see the frame lamp table HY4). Note that the speaker 11 does not output a sound related to this error (see the voice table HY5).

  At this time, the volume can be adjusted (refer to Table HY6 in “Volume Adjustment”), but the luminance cannot be adjusted (see Table HY6 in “Brightness Adjustment”). Therefore, when the player changes the volume, the effect control CPU 900 performs control so as to increase or decrease the volume of the sound output from the speaker 11 in accordance with the change content (“volume mode”). Table HY6). Then, the brightness of the decorative lamp LA is controlled so as to emit light with the error brightness (see Table HY6 of “Luminance Mode”). Note that when the volume is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11, and a volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Is also not displayed.

  On the other hand, when a payout shortage error signal (status signal STAY_SIGNAL) is sent from the payout control board 70, the main control board 60 sends an effect control command DI_DATA (see FIG. 4) indicating that payout shortage has occurred. . In response to this, the production control CPU 900 displays a liquid crystal control command LCD_CMD (see FIG. 4) for causing the liquid crystal display device 42 to display “Please call a clerk” (see table HY2 of the liquid crystal display). As a result, the message “The ball cannot be paid out. Further, the effect control CPU 900 controls to turn off the decoration lamp LA arranged on the game board 4 (see FIG. 2) (see the table HY3 of the board lamp), and the effect button device 16 (see FIG. 1). The lamps are controlled to be turned off (refer to the frame lamp table HY4), and among the decorative lamps LA arranged on the front frame 3, the monochrome decorative lamp LA is controlled to be turned off (frame lamp table HY4). (Refer to) The three-color decorative lamp LA is controlled to blink in white (see the frame lamp table HY4). Note that the speaker 11 does not output a sound related to this error (see the voice table HY5).

  At this time, the volume can be adjusted (refer to Table HY6 in “Volume Adjustment”), but the luminance cannot be adjusted (see Table HY6 in “Brightness Adjustment”). Therefore, when the player changes the volume, the effect control CPU 900 performs control so as to increase or decrease the volume of the sound output from the speaker 11 in accordance with the change content (“volume mode”). Table HY6). Then, the brightness of the decorative lamp LA is controlled so as to emit light with the error brightness (see Table HY6 of “Luminance Mode”). Note that when the volume is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11, and a volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Is also not displayed.

  On the other hand, if any abnormality occurs in the special symbol 1 start port switch 44a (see FIG. 3), the special symbol 2 start port switch 45a (see FIG. 3), or the normal symbol start port switch 48a (see FIG. 3), the main control board From 60, the special symbol 1 starting port switch 44a (see FIG. 3), the special symbol 2 starting port switch 45a (see FIG. 3), and the normal symbol starting port switch 48a (see FIG. 3) indicate that some abnormality has occurred. A control command DI_DATA (see FIG. 4) is transmitted. In response to this, the effect control CPU 900 transmits a liquid crystal control command LCD_CMD (see FIG. 4) for causing the liquid crystal display device 42 to display “switch is disconnected” (see table HY2 of the liquid crystal display) to the liquid crystal control board 120. Accordingly, the display “Switch is disconnected” is displayed on the liquid crystal display device 42. Further, the effect control CPU 900 controls to turn off the decoration lamp LA arranged on the game board 4 (see FIG. 2) (see the table HY3 of the board lamp), and the effect button device 16 (see FIG. 1). The lamps are controlled to be turned off (refer to the frame lamp table HY4), and among the decorative lamps LA arranged on the front frame 3, the monochrome decorative lamp LA is controlled to be turned off (frame lamp table HY4). (Refer to) The three-color decorative lamp LA is controlled to blink in white (see the frame lamp table HY4). Note that the speaker 11 does not output a sound related to this error (see the voice table HY5).

  At this time, the volume can be adjusted (refer to Table HY6 in “Volume Adjustment”), but the luminance cannot be adjusted (see Table HY6 in “Brightness Adjustment”). Therefore, when the player changes the volume, the effect control CPU 900 performs control so as to increase or decrease the volume of the sound output from the speaker 11 in accordance with the change content (“volume mode”). Table HY6). Then, the brightness of the decorative lamp LA is controlled so as to emit light with the error brightness (see Table HY6 of “Luminance Mode”). Note that when the volume is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11, and a volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Is also not displayed.

  On the other hand, when the abnormal data is stored in the memory area in the effect control RAM 900a (see FIG. 4) in which the data of the motor for operating the movable accessory (not shown) is stored, the effect control CPU 900 displays the liquid crystal display device 42. A liquid crystal control command LCD_CMD (see FIG. 4) for displaying a “movable accessory error” (see table HY2 of the liquid crystal display) is transmitted to the liquid crystal control board 120, and the liquid crystal display device 42 is referred to as a “movable accessory error”. It will be displayed. Further, the effect control CPU 900 controls to turn off the decoration lamp LA arranged on the game board 4 (see FIG. 2) (see the table HY3 of the board lamp), and the effect button device 16 (see FIG. 1). The lamps are controlled to be turned off (refer to the frame lamp table HY4), and among the decorative lamps LA arranged on the front frame 3, the monochrome decorative lamp LA is controlled to be turned off (frame lamp table HY4). (Refer to) The three-color decorative lamp LA is controlled to blink in white (see the frame lamp table HY4). Note that the speaker 11 does not output a sound related to this error (see the voice table HY5).

  At this time, the volume can be adjusted (refer to Table HY6 in “Volume Adjustment”), but the luminance cannot be adjusted (see Table HY6 in “Brightness Adjustment”). Therefore, when the player changes the volume, the effect control CPU 900 performs control so as to increase or decrease the volume of the sound output from the speaker 11 in accordance with the change content (“volume mode”). Table HY6). Then, the brightness of the decorative lamp LA is controlled so as to emit light with the error brightness (see Table HY6 of “Luminance Mode”). Note that when the volume is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11, and a volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Is also not displayed.

  On the other hand, when a ball clogging signal (status signal STAY_SIGNAL) is transmitted from the payout control board 70, the main control board 60 transmits an effect control command DI_DATA (see FIG. 4) indicating that the ball clogging has occurred. In response, the effect control CPU 900 transmits a liquid crystal control command LCD_CMD (see FIG. 4) to the liquid crystal control board 120 to display “please pull out the sphere” (see table HY2 of the liquid crystal display) on the liquid crystal display device 42. Thus, the message “please remove the ball” is displayed on the liquid crystal display device 42. In addition, the effect control CPU 900 performs control so that a sound indicating that a clogged ball has occurred (see the sound table HY5) is output from the speaker 11 when the gaming state is “big hit” or “small win”. The effect control CPU 900 is a decoration lamp LA arranged on the game board 4 (see FIG. 2) regarding this error, a lamp of the effect button device 16 (see FIG. 1), and a decoration arranged on the front frame 3. The lamp LA is not turned on / off.

  At this time, the brightness can be adjusted (refer to Table HY6 of “Brightness Adjustment”), but the volume cannot be adjusted (refer to Table HY6 of “Volume Adjustment”). Therefore, when the player changes the luminance, the effect control CPU 900 performs control so as to increase or decrease the luminance of the decorative lamp LA that emits light according to the content of the change ("brightness mode" (See Table HY6). Then, an error volume is output from the speaker 11 (see Table HY6 of “Volume Mode”). When the brightness is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11, and a volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Is also not displayed.

  On the other hand, when the normal symbol start port switch 48a (see FIG. 3) detects the passage of the game ball a predetermined number of times, the main control board 60 causes the player to correct the launch position. DI_DATA (see FIG. 4) Is sent. In response to this, the effect control CPU 900 transmits to the liquid crystal control board 120 a liquid crystal control command LCD_CMD (see FIG. 4) for causing the liquid crystal display device 42 to display “please return to the left” (see the table HY2 of the liquid crystal display). Accordingly, the message “Please return to the left-handed” is displayed on the liquid crystal display device 42. In addition, the effect control CPU 900 controls the speaker 11 to output a sound (see sound table HY5) indicating that the launch position is corrected. The effect control CPU 900 is a decoration lamp LA arranged on the game board 4 (see FIG. 2) regarding this error, a lamp of the effect button device 16 (see FIG. 1), and a decoration arranged on the front frame 3. The lamp LA is not turned on / off.

  At this time, the brightness can be adjusted (refer to Table HY6 of “Brightness Adjustment”), but the volume cannot be adjusted (refer to Table HY6 of “Volume Adjustment”). Therefore, when the player changes the luminance, the effect control CPU 900 performs control so as to increase or decrease the luminance of the decorative lamp LA that emits light according to the content of the change ("brightness mode" (See Table HY6). Then, an error volume is output from the speaker 11 (see Table HY6 of “Volume Mode”). When the brightness is changed, a sound for notifying the player of the change (for example, a single sound such as “pico”) is not output from the speaker 11, and a volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Is also not displayed.

  Thus, when an error with high priority such as door opening, winning abnormality detection, radio wave detection, magnetism detection, vibration detection, etc. occurs, volume adjustment / brightness adjustment is possible, but during the error the speaker 11 is output at an error volume (see Table HY6 of “Volume Mode”), and the brightness of the decoration lamp LA is emitted at an error luminance (see Table HY6 of “Luminance Mode”). . However, since the change content itself is stored in the effect control RAM 900a (see FIG. 4), when the error is released, the sound output from the speaker 11 is output at the changed volume, and the decoration lamp LA The luminance is emitted with the changed luminance, so that the player can confirm what volume / luminance has been changed. As a result, even if an error occurs unintentionally during the volume adjustment / brightness adjustment, the error can be notified with an appropriate volume / brightness during the error, and the changed volume / brightness after the error is released. The game can be performed at the same time, so that appropriate volume adjustment / brightness adjustment can be performed during the game.

  In other words, in the prior art, the volume / brightness adjustment can be performed when the game is stopped, but the volume / brightness adjustment cannot be performed during the game. Therefore, it is conceivable that volume adjustment / brightness adjustment can be performed during a game. However, if volume adjustment / brightness adjustment is enabled when an error occurs during a game, an error can be notified with an appropriate volume / brightness. There was a problem that there was a possibility that it could not be done.

  Therefore, in this embodiment, although volume adjustment / brightness adjustment is possible, during an error, the volume output from the speaker 11 is output at the error volume, and the brightness of the decoration lamp LA is the error brightness. The change content itself is stored in the effect control RAM 900a (see FIG. 4), and when the error is canceled, the sound output from the speaker 11 is output at the changed volume, and the decoration lamp The luminance of LA emits light with the changed luminance. As a result, even if an error occurs unintentionally during the volume adjustment / brightness adjustment, the error can be notified with an appropriate volume / brightness during the error, and the changed volume / brightness after the error is released. The game can be performed at the same time, so that appropriate volume adjustment / brightness adjustment can be performed during the game.

  In this embodiment, the volume adjustment / brightness adjustment screen is not displayed on the liquid crystal display device 42 during an error. However, the volume adjustment is performed on the liquid crystal display device 42 during some errors or all errors. Only the brightness adjustment screen may be displayed. Thereby, the player cannot confirm the contents of the volume adjustment / brightness adjustment directly, but can check how the volume adjustment / brightness adjustment is performed on the screen.

<Description of processing contents (program outline) of effect control board 90>
Next, the processing contents will be described in more detail by specifically describing the processing contents (program outline) of the effect control board 90 with reference to FIGS. First, the effect control main process will be described with reference to FIG.

<Description of main processing>
As shown in FIG. 26, in the effect control main process, the effect control CPU 900 first initializes a register provided therein and sets the input / output direction of the input / output port. Further, the data transmitted from the output port set in the output direction is set to serial transfer (step S1).

  After the setting, the effect control CPU 900 initializes the memory area in the effect control RAM 900a (see FIG. 4) that stores the effect control command DI_DATA (see FIG. 4) received from the main control board 60 (see FIG. 3). (Step S2). Then, the effect control CPU 900 performs an interrupt permission setting process for the input port that receives the interrupt signal from the main control board 60 (step S3).

  Next, the effect control CPU 900 initializes a memory area in the effect control RAM 900a used as a work area and a stack area (step S4), and issues an initialization command to the sound LSI 902 (see FIG. 4). Thereby, the sound LSI 902 initializes a register provided therein (step S5).

  Next, the effect control CPU 900 confirms whether or not abnormal data is stored in a memory area in the effect control RAM 900a in which data of a motor that operates a movable accessory (not shown) is stored. If the abnormal data is stored by the confirmation, the movable accessory may have moved to a position other than the initial position. Therefore, the effect control CPU 900 instructs the movable accessory motor to return to the origin position. I do. Thereby, a movable accessory will return to an initial position. However, the production control CPU 900 confirms the position of the motor based on the data MOT_SEN transmitted from the motor sensor that detects the position of the motor of the movable accessory, and sets the error flag ERR_FLG to ON if it has not returned to the initial position. Process. If the position has returned to the initial position, processing for setting the error flag ERR_FLG to OFF is performed (step S6). By the way, the error flag ERR_FLG is added with a header (or footer) indicating which error content is (movable accessory error or error in which the glass door frame 5 is opened). The effect control CPU 900 confirms the ON / OFF state of the error flag ERR_FLG in step S12 to be described later, and performs processing so that the content is as shown in the error list ER_HY shown in FIG.

  Next, the effect control CPU 900 performs setting of a CTC (Counter Timer Circuit) having a function of creating a pulse output with a constant period and a function of time measurement provided therein. That is, the effect control CPU 900 sets the CTC time constant register so that a timer interrupt is periodically generated every 1 ms (step S7).

  After finishing the above processing, the effect control CPU 900 confirms whether or not it is the main loop update period. Specifically, the remainder when the main loop counter ML_CNT that counts in a loop from 0 to 31 is divided by 16 (that is, divided by 16) is confirmed, and if the remainder is 0 (step S8: YES) Then, the process proceeds to step S10, and if it is other than 0 (step S8: NO), a process of updating a random value used for the notice lottery or the like is performed (step S9). A method for incrementing (+1) the main loop counter ML_CNT will be described later.

  Next, the effect control CPU 900 performs a process of setting the light emission luminance of the plurality of decorative lamps LA mounted on the decorative lamp substrate 100 (see FIGS. 3 and 5) (step S10). This process will be described in more detail with reference to FIG.

<Description of brightness setting process>
First, the effect control CPU 900 performs error confirmation (step S50). That is, the production control CPU 900 checks whether or not the error flag ERR_FLG is set to ON, and determines that some error has occurred if the error flag ERR_FLG is set to ON (step S50: YES). The process proceeds to step S51.

  Next, the effect control CPU 900 confirms the header (or footer) of the error flag ERR_FLG and confirms the error content (step S51). If it is a clogged ball or an error in correcting the launch position (see error table HY1 of error list ER_HY shown in FIG. 25) (step S51: YES), the process proceeds to step S53. (Step S51: NO), the effect control CPU 900 uses the brightness setting value “3” (see the table TB50 of the brightness adjustment table BR_TBL shown in FIG. 10) for the error in the brightness error area in the effect control RAM 900a (see FIG. 4). Stored as a luminance setting value (step S52).

  Next, the effect control CPU 900 confirms the brightness adjustable flag BRI_FLG and confirms whether or not the brightness can be adjusted (step S53). If the brightness adjustable flag BRI_FLG is set to OFF, the effect control CPU 900 determines that the brightness cannot be adjusted (step S53: NO), and ends the brightness setting process.

  On the other hand, if the brightness adjustable flag BRI_FLG is set to ON, the effect control CPU 900 determines that the brightness can be adjusted (step S53: YES), and proceeds to the process of step S54. Note that the ON / OFF setting of the brightness adjustable flag BRI_FLG is executed in step S12 described later.

  Next, the effect control CPU 900 confirms whether or not the player has adjusted the brightness. That is, it is confirmed whether or not the upper selection switch SW1 or the lower selection switch SW2 of the front switch 14 has been pressed, that is, the upper selection switch SW1 or the lower selection switch SW2 received in the process of step S304 described later (see FIG. 30). The contact signal FSW_DATA is confirmed (step S54). Thereby, if neither the upper selection switch SW1 nor the lower selection switch SW2 is pressed, the effect control CPU 900 determines that the player has not adjusted the luminance (step S54: NO), and finishes the luminance setting process. .

  On the other hand, if either the upper selection switch SW1 or the lower selection switch SW2 is pressed, the effect control CPU 900 determines that the player has adjusted the luminance (step S54: YES), and the luminance setting adjusted by the player The value is stored in a memory area in the effect control RAM 900a (see FIG. 4), and the brightness setting process is finished. Specifically, if the upper selection switch SW1 is pressed, the current brightness setting value is incremented (+1), and if the lower selection switch SW2 is pressed, the current brightness setting value is decremented (−1). Then, it is stored in the memory area in the effect control RAM 900a (see FIG. 4) (step S55). However, when the current luminance setting value is “3”, if the upper selection switch SW1 is pressed, the luminance setting value becomes “1” (see FIG. 15), and when the current luminance setting value is “1”, If the lower selection switch SW2 is pressed, the luminance setting value does not change and remains “1”.

  Thus, when “3” is stored as the error luminance setting value in the luminance error area in the effect control RAM 900a (see FIG. 4), in step S11 (see FIG. 26) described later. Referring to the brightness adjustment table BR_TBL (see FIG. 10) stored in the effect control ROM 901, the brightness adjustment value 100% stored in the table TB51 is read. Then, with the brightness adjustment value 100%, a plurality of decoration lamps LA (see FIG. 5), decoration lamp output data LAMP_DATA (see FIG. 4) necessary to turn on or off the lamps of the effect button device 16, and the effect button lamps Data BU_LAMP_DATA (see FIG. 4) is generated and stored in the memory area in the effect control RAM 900a. Then, the decorative lamp output data LAMP_DATA stored in the memory area in the effect control RAM 900a is transmitted to the decorative lamp substrate 100 (see FIG. 3) in the process of step S308 described later (see FIG. 30). The plurality of decorative lamps LA are turned on / off at the error luminance setting value (see the table lamp table HY3 of the error list ER_HY shown in FIG. 25 and the frame lamp table HY4). Further, the effect button lamp data BU_LAMP_DATA stored in the memory area in the effect control RAM 900a is transmitted to the effect button device 16 (see FIG. 3) in the process of step S308 (see FIG. 30), which will be described later. The lamp of the effect button device 16 is turned on / off at the error luminance setting value (see the table HY4 of the frame lamp of the panel lamp of the error list ER_HY shown in FIG. 25).

  On the other hand, when the error brightness setting value is stored in the brightness error area in the effect control RAM 900a (see FIG. 4), the brightness setting value set during the error is stored in the memory area in the effect control RAM 900a. Will remain. On the other hand, when the error brightness setting value is not stored in the brightness error area in the effect control RAM 900a (see FIG. 4), the brightness setting stored in the memory area in the effect control RAM 900a is not limited to an error. Depending on the value, a plurality of decorative lamps LA and lamps of the effect button device 16 are turned on / off.

  In this way, when the error is canceled, the brightness of the decoration lamp LA and the lamp of the effect button device 16 is emitted with the changed brightness. It can be confirmed whether the brightness has been changed. As a result, even if an error occurs unintentionally during the brightness adjustment, the error can be notified with an appropriate brightness during the error, and the game can be played with the changed brightness after the error is released. This makes it possible to adjust the brightness appropriately during the game.

  On the other hand, if the error flag ERR_FLG is not set to ON (step S50: NO), the effect control CPU 900 clears the luminance error area in the effect control RAM 900a (see FIG. 4) (step S56).

  Next, the effect control CPU 900 checks the brightness adjustable flag BRI_FLG to check whether the brightness can be adjusted (step S57). If the brightness adjustable flag BRI_FLG is set to OFF, the effect control CPU 900 determines that the brightness cannot be adjusted (step S57: NO), and ends the brightness setting process.

  On the other hand, if the brightness adjustable flag BRI_FLG is set to ON, the effect control CPU 900 determines that the brightness can be adjusted (step S57: YES), and checks the setting screen display enabled flag SGI_FLG (step S58). If the setting screen display enable flag SGI_FLG is set to OFF, the effect control CPU 900 determines that the volume adjustment / brightness adjustment screen should not be displayed on the liquid crystal display device 42 (step S58: NO), and step S62. Move on to processing. The setting screen display enable flag SGI_FLG is set to ON / OFF in step S12 described later.

  On the other hand, if the setting screen display enable flag SGI_FLG is set to ON, the effect control CPU 900 determines that the volume adjustment / brightness adjustment screen can be displayed on the liquid crystal display device 42 (step S58: YES). It is checked whether a screen for volume adjustment / brightness adjustment is displayed on the liquid crystal display device 42 (step S59). That is, the effect control CPU 900 confirms the setting screen display flag SGC_FLG. If the setting screen display flag SGC_FLG is set to ON, it is determined that the volume / brightness adjustment screen is displayed on the liquid crystal display device 42 (step S59: YES), and the process proceeds to step S62.

  On the other hand, if the setting screen display flag SGC_FLG is set to OFF, it is determined that the volume adjustment / brightness adjustment screen is not displayed on the liquid crystal display device 42 (step S59: NO), and the front switch 14 is moved up, down, left and right. It is confirmed whether any of the selection switches SW1 to SW4 is pressed (step S60). That is, the contact signal FSW_DATA of the upper selection switch SW1, the lower selection switch SW2, the left selection switch SW3, and the right selection switch SW4 received in the process of step S304 described later (see FIG. 30) is confirmed, and the upper selection switch SW1, lower If none of the selection switch SW2, the left selection switch SW3, and the right selection switch SW4 is pressed (step S60: NO), the effect control CPU 900 ends the brightness setting process.

  On the other hand, if any one of the upper selection switch SW1, the lower selection switch SW2, the left selection switch SW3, and the right selection switch SW4 is pressed (step S60: YES), the effect control CPU 900 causes the liquid crystal display device 42 to adjust the volume. A liquid crystal control command LCD_CMD (see FIG. 4) that displays a brightness adjustment screen is generated and stored in the effect control RAM 900a (step S61). As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later, and thus the volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Will be displayed (FIGS. 17 (b), 17 (e), 18 (b), 18 (e), 20, 20 (b), 22, 23 (b), (Refer FIG.24 (b)). At this time, the effect control CPU 900 performs processing for turning on the setting screen display flag SGC_FLG.

  Next, the effect control CPU 900 reads the effect control command DI_DATA (see FIG. 4) stored in the memory area in the effect control RAM 900a (see FIG. 4), and this effect control command DI_DATA is being played by the player while the game is suspended. It is confirmed whether or not the command is a customer waiting command indicating that it is present (step S62). If it is a customer waiting command (step S62: YES), the demo timer DEMO_TIMER is confirmed (step S63). If the demo timer DEMO_TIMER is “0” (step S63: YES), the current brightness setting value stored in the memory area in the effect control RAM 900a is cleared, and the initial brightness setting value, that is, the brightness setting value “3”. (Refer to the table TB50 of the brightness adjustment table BR_TBL shown in FIG. 10) is stored in the memory area in the effect control RAM 900a (step S64). Thereby, even if the player goes down with the brightness adjustment value lowered, it can be returned to the initial value. The demo timer DEMO_TIMER is a timer that manages the times T1 to T3 and the times T3 to T6 shown in FIG.

  Next, the effect control CPU 900 generates a liquid crystal control command LCD_CMD (see FIG. 4) so that the volume adjustment / brightness adjustment screen is not displayed on the liquid crystal display device 42, and stores it in the effect control RAM 900a (step S65). Finish the setting process. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. Will not be displayed. At this time, the effect control CPU 900 performs processing for turning off the setting screen display flag SGC_FLG.

  On the other hand, if the demo timer DEMO_TIMER is not “0” (step S63: NO), the presentation control CPU 900 checks the power saving mode flag SLM_FLG (step S66). If the power saving mode flag SLM_FLG is set to ON, it is determined that power saving is in progress (step S66: YES), and the luminance setting value “1” (see FIG. 4) is displayed in the luminance power saving area in the effect control RAM 900a (see FIG. 4). 10 (see table TB50 of the brightness adjustment table BR_TBL shown in FIG. 10) is stored as a power-saving brightness setting value (step S67).

  On the other hand, if power saving mode flag SLM_FLG is set to OFF, effect control CPU 900 determines that power saving is not in progress (step S66: NO), and clears the luminance power saving region in effect control RAM 900a (see FIG. 4) ( Step S68). Note that the ON / OFF setting of the power saving mode flag SLM_FLG is executed in step S12 described later.

  Next, the effect control CPU 900 confirms whether or not the player has adjusted the brightness. That is, it is confirmed whether or not the upper selection switch SW1 or the lower selection switch SW2 of the front switch 14 has been pressed, that is, the upper selection switch SW1 or the lower selection switch SW2 received in the process of step S304 described later (see FIG. 30). The contact signal FSW_DATA is confirmed (step S69). Thus, if neither the upper selection switch SW1 nor the lower selection switch SW2 is pressed, the effect control CPU 900 determines that the player has not adjusted the brightness (step S69: NO), and proceeds to the process of step S80. Transition.

  On the other hand, if either the upper selection switch SW1 or the lower selection switch SW2 is pressed, the effect control CPU 900 determines that the player has adjusted the luminance (step S69: YES), and the luminance setting adjusted by the player The value is stored in a memory area in the effect control RAM 900a (see FIG. 4). Specifically, if the upper selection switch SW1 is pressed, the current brightness setting value is incremented (+1), and if the lower selection switch SW2 is pressed, the current brightness setting value is decremented (−1). Then, it is stored in the memory area in the effect control RAM 900a (see FIG. 4) (step S70). However, when the current luminance setting value is “3”, if the upper selection switch SW1 is pressed, the luminance setting value becomes “1” (see FIG. 15), and when the current luminance setting value is “1”, If the lower selection switch SW2 is pressed, the luminance setting value does not change and remains “1”.

  Next, the effect control CPU 900 clears the value of the demo timer DEMO_TIMER and resets it (for example, resets it to 180 seconds) (step S71). As a result, it is possible to reduce the situation where the demo timer DEMO_TIMER becomes “0” during the player brightness setting, and the brightness setting value set by the player is cleared. When the demo timer DEMO_TIMER is reset, the period from timing T1 to T3 and the period from timing T3 to T6 become longer.

  Thus, when “1” is stored as the power saving luminance setting value in the luminance power saving area in the effect control RAM 900a (see FIG. 4), in step S11 (see FIG. 26) described later. Referring to the brightness adjustment table BR_TBL (see FIG. 10) stored in advance in the effect control ROM 901, the brightness adjustment value 30% stored in the table TB51 is read out. Then, with the brightness adjustment value of 30%, a plurality of decoration lamps LA (see FIG. 5), decoration lamp output data LAMP_DATA (see FIG. 4) necessary to turn on or off the lamps of the effect button device 16, and effect button lamps Data BU_LAMP_DATA (see FIG. 4) is generated and stored in the memory area in the effect control RAM 900a. Then, the decorative lamp output data LAMP_DATA stored in the memory area in the effect control RAM 900a is transmitted to the decorative lamp substrate 100 (see FIG. 3) in the process of step S308 described later (see FIG. 30). The plurality of decorative lamps LA are turned on / off at the power saving brightness setting value (see timings T3 to T6 shown in FIG. 16). In addition, the effect button lamp data BU_LAMP_DATA stored in the memory area in the effect control RAM 900a is transmitted to the effect button device 16 (see FIG. 3) in the process of step S308 (see FIG. 30) described later. The lamp of the effect button device 16 is turned on / off at the power saving luminance setting value (see timings T3 to T6 shown in FIG. 16).

  On the other hand, when the power saving luminance setting value is stored in the luminance power saving area in the effect control RAM 900a (see FIG. 4), the luminance setting value set during power saving is stored in the memory area in the effect control RAM 900a. Will remain. On the other hand, when the power saving luminance setting value is not stored in the luminance power saving area in the effect control RAM 900a (see FIG. 4), the luminance setting stored in the memory area in the effect control RAM 900a is not limited to during power saving. Depending on the value, a plurality of decorative lamps LA and lamps of the effect button device 16 are turned on / off.

  In this way, when the power saving mode is canceled, the brightness of the decorative lamp LA and the lamp of the effect button device 16 is emitted with the changed brightness. It can be confirmed whether the brightness has been changed to a proper level. When the brightness is changed, the brightness of the decorative lamp LA that emits light only when the brightness is changed and the brightness of the lamp of the effect button device 16 (see FIG. 3) are increased or decreased. You may make it.

  On the other hand, the effect control CPU 900 reads the effect control command DI_DATA (see FIG. 4) stored in the memory area in the effect control RAM 900a (see FIG. 4), and this effect control command DI_DATA is being played by the player while the game is suspended. If it is not a customer waiting command indicating that there is a certain event (step S62: NO), the luminance power saving area in the effect control RAM 900a (see FIG. 4) is cleared (step S72).

  Next, the effect control CPU 900 checks the value of the reset timer RST_TIMER (step S73). If the value of the reset timer RST_TIMER is not “0” (step S73: NO), 1 is subtracted from the value of the reset timer RST_TIMER (step S74), and the value of the reset timer RST_TIMER is confirmed again (step S75). If the value of the reset timer RST_TIMER is “0” (step S75: YES), a liquid crystal control command LCD_CMD (see FIG. 4) that does not display the volume adjustment / brightness adjustment screen on the liquid crystal display device 42 is generated. The data is stored in the control RAM 900a (step S76), and the luminance setting process is finished. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. Will not be displayed. At this time, the effect control CPU 900 performs processing for turning off the setting screen display flag SGC_FLG.

  On the other hand, if the value of the reset timer RST_TIMER is “0” (step S73: YES) or the value of the reset timer RST_TIMER is not “0” (step S75: NO), the effect control CPU 900 allows the player to adjust the brightness. Confirm whether or not. That is, it is confirmed whether or not the upper selection switch SW1 or the lower selection switch SW2 of the front switch 14 has been pressed, that is, the upper selection switch SW1 or the lower selection switch SW2 received in the process of step S304 described later (see FIG. 30). The contact signal FSW_DATA is confirmed (step S77). As a result, if neither the upper selection switch SW1 nor the lower selection switch SW2 is pressed, the effect control CPU 900 determines that the player has not adjusted the brightness (step S77: NO), and proceeds to the process of step S80. Transition.

  On the other hand, if either the upper selection switch SW1 or the lower selection switch SW2 is pressed, the effect control CPU 900 determines that the player has adjusted the luminance (step S77: YES), and the luminance setting adjusted by the player The value is stored in a memory area in the effect control RAM 900a (see FIG. 4). Specifically, if the upper selection switch SW1 is pressed, the current brightness setting value is incremented (+1), and if the lower selection switch SW2 is pressed, the current brightness setting value is decremented (−1). Then, it is stored in the memory area in the effect control RAM 900a (see FIG. 4) (step S78). However, when the current luminance setting value is “3”, if the upper selection switch SW1 is pressed, the luminance setting value becomes “1” (see FIG. 15), and when the current luminance setting value is “1”, If the lower selection switch SW2 is pressed, the luminance setting value does not change and remains “1”.

  Next, the effect control CPU 900 clears the value of the reset timer RST_TIMER and resets it (for example, resets it to 5 seconds) (step S79).

  By the way, this reset timer RST_TIMER manages the display time of the volume adjustment / luminance adjustment screen displayed on the liquid crystal display device 42. The upper selection switch SW1, the lower selection switch SW2, the left selection switch SW2, If neither the selection switch SW3 nor the right selection switch SW4 is pressed, the volume / brightness adjustment screen displayed on the liquid crystal display device 42 is erased. Note that the point where the value of the reset timer RST_TIMER is reset by pressing the left selection switch SW3 and the right selection switch SW4 will be described in the process of step S14 described later (see FIGS. 26 and 28). .

  Thus, after finishing the processing as described above, the effect control CPU 900 confirms whether or not the decision switch SW5 of the front switch 14 has been pressed, that is, received in the processing of step S304 (see FIG. 30) described later. The contact signal FSW_DATA of the decision switch SW5 is confirmed (step S80). Thereby, if the determination switch SW5 is not pressed (step S80: NO), the luminance setting process is ended.

  On the other hand, if determination switch SW5 is pressed (step S80: YES), effect control CPU 900 issues a liquid crystal control command LCD_CMD (see FIG. 4) that does not display the volume adjustment / brightness adjustment screen on liquid crystal display device. It produces | generates and stores in production | presentation control RAM900a (step S81), and a luminance setting process is complete | finished. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. Will not be displayed. At this time, the effect control CPU 900 performs processing for turning off the setting screen display flag SGC_FLG.

<Description of main processing>
Thus, after finishing the process of step S10, the effect control CPU 900 stores the data relating to the light determined in step S13 described later and the memory area of the effect control RAM 900a (see FIG. 4) in step S10. The brightness setting value or the error brightness setting value stored in the brightness error area of the effect control RAM 900a (see FIG. 4) or for power saving stored in the brightness power saving area of the effect control RAM 900a (see FIG. 4) The brightness setting value is read out, and a plurality of brightness adjustment values stored in the table TB51 are mounted on the decorative lamp substrate 100 with reference to the brightness adjustment table BR_TBL (see FIG. 10) stored in the effect control ROM 901. Decoration lamp output data LAMP_DA required to turn on or off the decoration lamp LA Generates A, it performs a process of writing in the memory area of the attraction control the RAMs 900a. More specifically, if the error flag ERR_FLG is set to ON, the power-saving mode flag SLM_FLG is used by using the error luminance setting value stored in the luminance error area in the effect control RAM 900a (see FIG. 4). Is set to ON, the power saving luminance setting value stored in the luminance power saving area in the effect control RAM 900a (see FIG. 4) is used, and otherwise, the effect control RAM 900a (see FIG. 4) is used. The brightness setting value stored in the memory area is used. However, the header (or footer) of the error flag ERR_FLG is confirmed, and if it is a clogged ball or a launch position correction error (see the table HY1 of the error contents of the error list ER_HY shown in FIG. 25), the effect control RAM 900a (FIG. Use the brightness setting value stored in the memory area. In addition, when the brightness is changed during power saving, the power saving mode flag SLM_FLG is set to ON to increase or decrease the brightness of the decorative lamp LA that emits light only when the brightness is changed, Further, when either the upper selection switch SW1 or the lower selection switch SW2 is pressed, the power-saving luminance setting value stored in the luminance power-saving area in the effect control RAM 900a (see FIG. 4) is used. When the lamp of the effect button device 16 is turned on, the brightness adjustment value stored in the table TB51 is turned on with reference to the brightness adjustment table BR_TBL (see FIG. 10) stored in the effect control ROM 901. Production button lamp data BU_LAMP_DATA is generated and written into a memory area in the production control RAM 900a.

  Next, the effect control CPU 900 reads the effect control command DI_DATA (see FIG. 4) stored in the memory area in the effect control RAM 900a, and stores an effect pattern corresponding to the content in the effect control ROM 901 in advance. It is decided by lottery from a large number of production patterns. Then, the liquid crystal control command LCD_CMD corresponding to the determined effect pattern is stored in the memory area in the effect control RAM 900a.

  By the way, when the production control command DI_DATA is a command indicating that the player is suspending the game, the production control CPU 900 waits for a player waiting screen (FIGS. 17 (a) and 18 (a)). The liquid crystal control command LCD_CMD for causing the liquid crystal display device 42 to display a) is generated and stored in the memory area in the effect control RAM 900a. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 described later (see FIG. 30), so that the liquid crystal display device 42 waits for the player to wait for the player. Will be displayed (see FIG. 17A and FIG. 18A).

  On the other hand, when the effect control command DI_DATA is a command indicating that the player is suspending the game, the effect control CPU 900 sets a predetermined value (for example, a value that counts 180 seconds) to the demo timer DEMO_TIMER. Count down. If the effect control command DI_DATA indicating that the player is playing until 0 is not stored in the memory area in the effect control RAM 900a (see timing T3 shown in FIG. 16), the rear switch 15 (FIG. 6 (a)), that is, the adjustment signal BSW_DATA received in the process of step S304 (see FIG. 30) described later is confirmed. Thereby, if the back switch 15 is adjusted to any one of “3” to “5” (see FIG. 6), the effect control CPU 900 sets the power saving mode flag SLM_FLG to ON. Then, a liquid crystal control command LCD_CMD for causing the liquid crystal display device 42 to display the power saving screen (see image P60) shown in FIG. 18C is generated and stored in the memory area in the effect control RAM 900a. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 described later (see FIG. 30), so that the liquid crystal display device 42 is shown in FIG. A power saving screen (see image P60) is displayed. If the demonstration timer DEMO_TIMER is 0 and the effect control command DI_DATA indicating that the player is playing is not stored in the memory area in the effect control RAM 900a (see timing T3 shown in FIG. 16), the demo timer DEMO_TIMER A predetermined value (for example, a value that counts 180 seconds) is set again, and the countdown is performed.

  On the other hand, if the back switch 15 is not adjusted to any of “3” to “5” (see FIG. 6), the effect control CPU 900 sets the power saving mode flag SLM_FLG to OFF. Then, a liquid crystal control command LCD_CMD for causing the liquid crystal display device 42 to display the screen shown in FIG. 17C (see image P6) is generated and stored in the memory area in the effect control RAM 900a. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 described later (see FIG. 30), so that the liquid crystal display device 42 is shown in FIG. A screen (see image P6) is displayed.

  On the other hand, the effect control CPU 900 sets the setting screen display enable flag SGI_FLG to ON and the setting screen display flag SGC_FLG when the effect control command DI_DATA is a command indicating that the player is suspending the game. Is set to OFF (see timing T1 shown in FIG. 16), the brightness adjustable flag BRI_FLG is set to ON (see timing T1 shown in FIG. 16), and a volume adjustable flag MOI_FLG described later is set to ON (FIG. 16). Timing T1 shown in FIG. When the setting screen display flag SGC_FLG is set to OFF, the effect control CPU 900 generates a liquid crystal control command LCD_CMD (see FIG. 4) so that the volume adjustment / brightness adjustment screen is not displayed on the liquid crystal display device 42. The effect is stored in the effect control RAM 900a (see FIG. 4). As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. Will not be displayed. However, if the player presses any one of the upper selection switch SW1, the lower selection switch SW2, the left selection switch SW3, and the right selection switch SW4 on the front switch 14, a screen for volume adjustment / luminance adjustment is displayed on the liquid crystal display device 42. It is displayed (see step S60 shown in FIG. 27, step S112 shown in FIG. 28 described later).

  On the other hand, when the effect control command DI_DATA is a command indicating that the player is suspending the game, the effect control CPU 900 sets a predetermined value (for example, a fade-out timer FAO_TIMER that manages a fade-out time of BGM, which will be described later). Set the value to count 30 seconds) and count down. If the effect control command DI_DATA indicating that the player is playing is not stored in the memory area in the effect control RAM 900a until the fade-out timer FAO_TIMER becomes 0 (see timing T2 shown in FIG. 16), the setting screen The display enable flag SGI_FLG is set to ON, and a liquid crystal control command LCD_CMD (see FIG. 4) is generated so that a volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42, and an effect control RAM 900a (see FIG. 4) is generated. Store in. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later, and thus the volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Will be displayed. At this time, the setting screen display flag SGC_FLG is set to ON.

  On the other hand, at the timing T4 shown in FIG. 16 in the countdown of the demo timer DEMO_TIMER, the effect control CPU 900 sets the setting screen display enable flag SGI_FLG to ON and sets the setting screen display flag SGC_FLG to OFF. At this time, the effect control CPU 900 generates a liquid crystal control command LCD_CMD (see FIG. 4) that does not display the volume adjustment / brightness adjustment screen on the liquid crystal display device 42, and stores it in the effect control RAM 900a (see FIG. 4). To do. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. Will not be displayed. However, if the player presses any one of the upper selection switch SW1, the lower selection switch SW2, the left selection switch SW3, and the right selection switch SW4 on the front switch 14, a screen for volume adjustment / luminance adjustment is displayed on the liquid crystal display device 42. It is displayed (see step S60 shown in FIG. 27, step S112 shown in FIG. 28 described later).

  Also, the production control CPU 900 generates a liquid crystal control command LCD_CMD for causing the liquid crystal display device 42 to display the screens shown in FIGS. 17D and 18D (see image P7) at the timing T4 shown in FIG. It is stored in a memory area in the effect control RAM 900a. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. The screen shown in FIG. 18D (see image P7) will be displayed.

  Then, the countdown of the demo timer DEMO_TIMER further proceeds, and at the timing T5 shown in FIG. 16, the effect control CPU 900 sets the setting screen display enable flag SGI_FLG to ON, and a volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. A liquid crystal control command LCD_CMD (see FIG. 4) to be displayed is generated and stored in the effect control RAM 900a (see FIG. 4). As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later, and thus the volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Will be displayed. At this time, the setting screen display flag SGC_FLG is set to ON.

  On the other hand, if the power saving mode flag SLM_FLG is set to OFF, a liquid crystal control command LCD_CMD for displaying the screen (see image P1) shown in FIG. 17E on the liquid crystal display device 42 is generated, and the memory in the effect control RAM 900a is displayed. Store in the area. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 described later (see FIG. 30), so that the liquid crystal display device 42 shown in FIG. A screen (see image P1) will be displayed. If the power saving mode flag SLM_FLG is set to ON, a liquid crystal control command LCD_CMD for causing the liquid crystal display device 42 to display the screen (see image P1, image P8) shown in FIG. Store in the memory area. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 described later (see FIG. 30). A screen (see image P1 and image P8) is displayed.

  On the other hand, the effect control CPU 900 sets the power saving mode flag SLM_FLG to OFF when the effect control command DI_DATA (see FIG. 4) indicating the start of variation of the special symbol is stored in the memory area in the effect control RAM 900a (see FIG. 4). Then, the brightness adjustable flag BRI_FLG is set to ON (see timings T6 and T8 shown in FIG. 19), and a volume adjustable flag MOI_FLG described later is set to ON (see timings T6 and T8 shown in FIG. 19). Then, a liquid crystal control command LCD_CMD for causing the liquid crystal display device 42 to display a screen (see the image P10 in FIGS. 20, 22, and 23) showing the variation of the special symbol is generated and stored in the memory area in the effect control RAM 900a. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later, so that the screen showing the special symbol variation on the liquid crystal display device 42. (See the image P10 in FIGS. 20, 22, and 23).

  On the other hand, when the effect control command DI_DATA (see FIG. 4) indicating suspension of the special symbol change is stored in the memory area in the effect control RAM 900a (see FIG. 4), the effect control CPU 900 turns off the brightness adjustable flag BRI_FLG. (See timings T7 and T9 shown in FIG. 19), and a later-described volume adjustable flag MOI_FLG is set to OFF (see timings T7 and T9 shown in FIG. 19). Then, a liquid crystal control command LCD_CMD for causing the liquid crystal display device 42 to display a screen (see the image P1 in FIG. 21 and the image P100 in FIG. 24) indicating the change stop of the special symbol is generated and stored in the memory area in the effect control RAM 900a. . As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later, and the liquid crystal display device 42 is instructed to stop changing the special symbol. A screen (see image P1 in FIG. 21 and image P100 in FIG. 24) is displayed. Furthermore, when the volume control / brightness adjustment screen is not displayed on the liquid crystal display device 42, the effect control CPU 900 sets the setting screen display enable flag SGI_FLG to OFF. At this time, the effect control CPU 900 does not display the volume adjustment / brightness adjustment screen on the liquid crystal display device 42, and displays the screen indicating the volume / brightness adjustment impossible (image P9 shown in FIGS. 21A and 24A). A liquid crystal control command LCD_CMD (see FIG. 4) for displaying (see) is generated and stored in the effect control RAM 900a (see FIG. 4). As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later, and thus the volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device. Is not displayed, and a screen indicating that volume / brightness adjustment is impossible (see image P9 shown in FIGS. 21A and 24A) is displayed. At this time, the setting screen display flag SGC_FLG is set to OFF.

  On the other hand, when the effect control command DI_DATA (see FIG. 4) indicating the start of the big hit is stored in the memory area in the effect control RAM 900a (see FIG. 4), the effect control CPU 900 sets the brightness adjustable flag BRI_FLG to ON. (Refer to timing T10 shown in FIG. 19). A volume adjustment enable flag MOI_FLG described later is set to ON (see timing T10 shown in FIG. 19). Further, the setting screen display enable flag SGI_FLG is set to ON.

  On the other hand, if the production control command DI_DATA is an error command indicating fraud or abnormality, the production control CPU 900 performs processing for setting the error flag ERR_FLG to ON. At this time, specific error contents are added to the header (or footer) of the error flag ERR_FLG according to the contents of the effect control command DI_DATA. Then, the production control CPU 900 generates a liquid crystal control command LCD_CMD for causing the liquid crystal display device 42 to display a screen corresponding to the content of the error flag ERR_FLG (see the liquid crystal display table HY2 shown in FIG. 25). It is stored in a memory area in the effect control RAM 900a. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 described later (see FIG. 30), so that the liquid crystal display device 42 responds to the contents of the error flag ERR_FLG. The screen (see the error list ER_HY liquid crystal display table HY2 shown in FIG. 25) is displayed. In the event of an error, the production control CPU 900 sets the setting screen display enable flag SGI_FLG to OFF, and generates a liquid crystal control command LCD_CMD (see FIG. 4) that does not display the volume adjustment / brightness adjustment screen on the liquid crystal display device 42. The effect control RAM 900a (see FIG. 4) is stored. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later, and thus the volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Disappears. At this time, the effect control CPU 900 sets the setting screen display flag SGC_FLG to OFF.

  When the error flag ERR_FLG is an error indicating door opening, winning abnormality detection, radio wave detection, magnetism detection, or vibration detection, the effect control CPU 900 sets the brightness adjustable flag BRI_FLG to ON and a volume adjustable flag described later. MOI_FLG is set to ON (see table HY6 of “volume adjustment” and “brightness adjustment” in error list ER_HY shown in FIG. 25). If the error flag ERR_FLG is a RAM clear error, the effect control CPU 900 sets the brightness adjustable flag BRI_FLG to OFF and sets a volume adjustable flag MOI_FLG described later to OFF (error list ER_HY shown in FIG. 25). (See Table HY6 of “Volume adjustment” and “Brightness adjustment”). Further, if the error flag ERR_FLG is an error of replenishment, shortage of payout, disconnection detection, movable accessory abnormality, the effect control CPU 900 sets the brightness adjustable flag BRI_FLG to OFF and sets a volume adjustable flag MOI_FLG described later. It is set to ON (see table HY6 of “volume adjustment” and “brightness adjustment” in error list ER_HY shown in FIG. 25). Furthermore, when the error flag ERR_FLG is a ball clogging or launch position correction error, the effect control CPU 900 sets the brightness adjustable flag BRI_FLG to ON and sets the volume adjustable flag MOI_FLG described later to OFF (FIG. 25). (Refer to Table HY6 of “Volume Adjustment” and “Luminance Adjustment” in the error list ER_HY shown in FIG. 8) (step S12).

  Next, the effect control CPU 900 generates light-related data and sound-related control signals according to the determined effect pattern. Then, it is also determined whether or not there is an effect that causes the player to press the effect button device 16 in the determined effect pattern. Furthermore, the operation content of a motor (not shown) for operating the movable accessory and the operation content of the solenoid are determined (step S13). Note that the data regarding the determined light is used in the next process of step S11.

  Next, the effect control CPU 900 transmits a control signal related to the determined sound to the sound LSI 902 (see FIG. 4). Then, the sound LSI 902 reads out BGM or sound effect corresponding to the control signal from the sound ROM 903. As a result, the sound LSI 902 performs processing based on the read sound data, and performs processing of outputting the sound source data to the speaker 11 (step S14). This process will be described in more detail with reference to FIG.

<Description of sound output processing>
First, the effect control CPU 900 performs error confirmation (step S100). That is, the effect control CPU 900 checks whether or not the error flag ERR_FLG is set to ON, and determines that some error has occurred if the error flag ERR_FLG is set to ON (step S100: YES). The process proceeds to step S101.

  Next, the effect control CPU 900 confirms the header (or footer) of the error flag ERR_FLG and confirms the error content (step S101). If it is out of replenishment, payout shortage, disconnection detection, error of movable accessory (see table HY1 of error contents of error list ER_HY shown in FIG. 25) (step S101: YES), the process proceeds to step S103, If it is an error other than that (step S101: NO), the production control CPU 900 outputs the number of SACs determined in advance in the program to the sound LSI 902 (see FIG. 4) in order to obtain the volume for the error. The sound LSI 902 accesses the volume output value table VL_TBL shown in FIG. 7 or the volume output value table VL_TBL_A shown in FIG. 9 stored in the sound ROM 903 to read the volume output data corresponding to the number of SACs, and the number of SACs. The volume output data in the speaker 11 corresponding to the above and the internal register address (C0H) of the sound LSI 902 are read out, and the end code (FFH) is read out. As a result, the sound LSI 902 outputs sound source data AMOR / L (see FIG. 4) of the sound adjusted to the volume for error based on the volume output data in the speaker 11 read from the sound ROM 903 to the speaker 11 (shown in FIG. 25). (Refer to the voice table HY5 of the error list ER_HY) (step S102).

  Next, the effect control CPU 900 confirms the volume adjustable flag MOI_FLG and confirms whether or not the volume can be adjusted (step S103). If the volume adjustable flag MOI_FLG is set to OFF, the effect control CPU 900 determines that the volume cannot be adjusted (step S103: NO), and ends the sound output process.

  On the other hand, if the volume adjustable flag MOI_FLG is set to ON, the effect control CPU 900 determines that the volume can be adjusted (step S103: YES), and checks whether or not the player has adjusted the volume. That is, it is confirmed whether the left selection switch SW3 or the right selection switch SW4 of the front switch 14 has been pressed, that is, the left selection switch SW3 or the right selection switch SW4 received in the process of step S304 (see FIG. 30) described later. The contact signal FSW_DATA is confirmed (step S104). Thus, if neither the left selection switch SW3 nor the right selection switch SW4 is pressed, the effect control CPU 900 determines that the player has not adjusted the volume (step S104: NO), and ends the sound output process. .

  On the other hand, if either the left selection switch SW3 or the right selection switch SW4 is pressed, the effect control CPU 900 determines that the player has adjusted the volume (step S104: YES), and the header of the error flag ERR_FLG (or The footer is confirmed, and the error content is confirmed (step S105). In the case of an error indicating door opening, winning abnormality detection, radio wave detection, magnetism detection, or vibration detection (step S105: YES), the volume setting value adjusted by the player is stored in the memory area in the effect control RAM 900a (see FIG. 4). Then, the sound output process is finished. Specifically, if the left selection switch SW3 is pressed, the current volume setting value is decremented (−1), and if the right selection switch SW4 is pressed, the current volume setting value is incremented (+1). (Step S106). The volume setting value can be set from “−2” to “+2” (the initial value (reference value) is “0”). When the current volume setting value is “+2”, right selection is performed. If the switch SW4 is pressed, the volume setting value becomes “−2” (see FIG. 13). If the left selection switch SW3 is pressed when the current volume setting value is “−2”, the volume setting value is It does not change and remains "-2".

  On the other hand, if it is not an error indicating door opening, winning abnormality detection, radio wave detection, magnetism detection, or vibration detection (step S105: NO), the presentation control CPU 900 uses the volume setting value adjusted by the player as shown in FIG. b), the number of SACs stored in the simple access code table SAC_TBL, or the number of SACs of the table TB22 stored in the volume output increase / decrease value table VO_REG_TBL shown in FIG. The increase / decrease value of the volume output data stored in the TB 24 is read and output to the sound LSI 902 (see FIG. 4). The sound LSI 902 accesses the volume output value table VL_TBL shown in FIG. 7 or the volume output value table VL_TBL_A shown in FIG. 9 stored in the sound ROM 903 to read the volume output data corresponding to the number of SACs, and the number of SACs. The volume output data in the speaker 11 corresponding to the above and the internal register address (C0H) of the sound LSI 902 are read out, and the end code (FFH) is read out. Thus, the sound LSI 902 adjusts the volume based on the volume output data in the speaker 11 read from the sound ROM 903, and outputs the sound source data AMOR / L (see FIG. 4) of the sound adjusted to the volume to the speaker 11 (step S107), the sound output process is finished.

  Thus, the volume setting value set during a specific error (high priority error) is stored in the memory area in the effect control RAM 900a, and the sound is output from the speaker 11 at the error volume. By doing so, even if an error occurs unintentionally during volume adjustment, the error can be reported at an appropriate volume during the error, and after the error is released, the game is played at the changed volume. Therefore, it is possible to adjust the sound volume appropriately during the game.

  On the other hand, if the error flag ERR_FLG is set to OFF, it is determined that no error has occurred (step S100: NO), and the effect control CPU 900 stores the current value stored in the memory area in the effect control RAM 900a. Based on the volume setting value, the number of SACs stored in the simple access code table SAC_TBL shown in FIG. 6B, or the number of SACs in the table TB22 stored in the volume output increase / decrease value table VO_REG_TBL shown in FIG. Table TB23. The increase / decrease value of the volume output data stored in the TB 24 is read and output to the sound LSI 902 (see FIG. 4). The sound LSI 902 accesses the volume output value table VL_TBL shown in FIG. 7 or the volume output value table VL_TBL_A shown in FIG. 9 stored in the sound ROM 903 to read the volume output data corresponding to the number of SACs, and the number of SACs. The volume output data in the speaker 11 corresponding to the above and the internal register address (C0H) of the sound LSI 902 are read out, and the end code (FFH) is read out. Accordingly, the sound LSI 902 adjusts the volume based on the volume output data in the speaker 11 read from the sound ROM 903, and outputs the sound source data AMOR / L (see FIG. 4) of the sound adjusted to the volume to the speaker 11 (step). S108).

  Next, the effect control CPU 900 confirms the volume adjustable flag MOI_FLG and confirms whether or not the volume can be adjusted (step S109). If the volume adjustable flag MOI_FLG is set to OFF, the effect control CPU 900 determines that the volume cannot be adjusted (step S109: NO), and proceeds to the process of step S137.

  On the other hand, if volume adjustment enable flag MOI_FLG is set to ON, effect control CPU 900 determines that the volume can be adjusted (step S109: YES), and checks setting screen display enable flag SGI_FLG (step S110). If the setting screen display enable flag SGI_FLG is set to OFF, the effect control CPU 900 determines that the volume adjustment / luminance adjustment screen should not be displayed on the liquid crystal display device 42 (step S110: NO), and step S114. Move on to processing.

  On the other hand, if the setting screen display enabled flag SGI_FLG is set to ON, the effect control CPU 900 determines that the volume adjustment / brightness adjustment screen can be displayed on the liquid crystal display device 42 (step S110: YES). It is checked whether a screen for volume adjustment / brightness adjustment is displayed on the liquid crystal display device 42 (step S111). That is, the effect control CPU 900 confirms the setting screen display flag SGC_FLG. If the setting screen display flag SGC_FLG is set to ON, it is determined that the volume / brightness adjustment screen is displayed on the liquid crystal display device 42 (step S111: YES), and the process proceeds to step S114.

  On the other hand, if the setting screen display flag SGC_FLG is set to OFF, it is determined that the volume adjustment / luminance adjustment screen is not displayed on the liquid crystal display device 42 (step S111: NO), and the front switch 14 is moved up, down, left, right. It is confirmed whether any of the selection switches SW1 to SW4 is pressed (step S112). That is, the contact signal FSW_DATA of the upper selection switch SW1, the lower selection switch SW2, the left selection switch SW3, and the right selection switch SW4 received in the process of step S304 described later (see FIG. 30) is confirmed, and the upper selection switch SW1, lower If none of the selection switch SW2, the left selection switch SW3, and the right selection switch SW4 is pressed (step S112: NO), the effect control CPU 900 proceeds to the process of step S137.

  On the other hand, if any of the upper selection switch SW1, the lower selection switch SW2, the left selection switch SW3, and the right selection switch SW4 is pressed (step S112: YES), the effect control CPU 900 causes the liquid crystal display device 42 to adjust the volume. A liquid crystal control command LCD_CMD (see FIG. 4) for displaying a brightness adjustment screen is generated and stored in the effect control RAM 900a (step S113). As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later, and thus the volume adjustment / brightness adjustment screen is displayed on the liquid crystal display device 42. Will be displayed (FIGS. 17 (b), 17 (e), 18 (b), 18 (e), 20, 20 (b), 22, 23 (b), (Refer FIG.24 (b)). At this time, the effect control CPU 900 performs processing for turning on the setting screen display flag SGC_FLG.

  Next, the effect control CPU 900 reads the effect control command DI_DATA (see FIG. 4) stored in the memory area in the effect control RAM 900a (see FIG. 4). It is confirmed whether or not the command is a customer waiting command indicating that it exists (step S114). If it is a customer waiting command (step S114: YES), the fade-out timer FAO_TIMER is confirmed (step S115). If the fade-out timer FAO_TIMER is not “0” (step S115: NO), it is confirmed whether or not the player has adjusted the volume. That is, it is confirmed whether the left selection switch SW3 or the right selection switch SW4 of the front switch 14 has been pressed, that is, the left selection switch SW3 or the right selection switch SW4 received in the process of step S304 (see FIG. 30) described later. The contact signal FSW_DATA is confirmed (step S116). Thus, if neither the left selection switch SW3 nor the right selection switch SW4 is pressed, the effect control CPU 900 determines that the player has not adjusted the volume (step S116: NO), and the sound LSI 902 (FIG. 4). Command) to gradually decrease the volume and fade out, and the process proceeds to step S135. As a result, the sound LSI 902 gradually decreases the volume of the BGM and fades out.

  On the other hand, if either the left selection switch SW3 or the right selection switch SW4 is pressed, the effect control CPU 900 determines that the player has adjusted the volume (step S116: YES), and the volume setting adjusted by the player. Based on the value, the number of SACs stored in the simple access code table SAC_TBL shown in FIG. 6B or the number of SACs in the table TB22 stored in the volume output increase / decrease value table VO_REG_TBL shown in FIG. 8 and the table TB23 . The increase / decrease value of the volume output data stored in the TB 24 is read and output to the sound LSI 902 (see FIG. 4). The sound LSI 902 accesses the volume output value table VL_TBL shown in FIG. 7 or the volume output value table VL_TBL_A shown in FIG. 9 stored in the sound ROM 903 to read the volume output data corresponding to the number of SACs, and the number of SACs. The volume output data in the speaker 11 corresponding to the above and the internal register address (C0H) of the sound LSI 902 are read out, and the end code (FFH) is read out. Accordingly, the sound LSI 902 adjusts the volume based on the volume output data in the speaker 11 read from the sound ROM 903, and outputs the sound source data AMOR / L (see FIG. 4) of the sound adjusted to the volume to the speaker 11 (step). S118).

  Next, the effect control CPU 900 clears the value of the fade-out timer FAO_TIMER and resets it (for example, resets it to 30 seconds) (step S119). Thereby, the period of the timings T1 to T2 shown in FIG. 16 is lengthened, so that the player can adjust the volume while listening to the BGM output from the speaker 11.

  Next, the effect control CPU 900 clears the value of the demo timer DEMO_TIMER, resets it (for example, resets to 180 seconds) (step S120), and proceeds to the processing of step S135. As a result, the demo timer DEMO_TIMER becomes “0” during the player's volume setting, thereby reducing the situation in which the volume setting value set by the player is cleared. When the demo timer DEMO_TIMER is reset, the period of the timings T1 to T3 becomes longer.

  On the other hand, if the fade-out timer FAO_TIMER is “0” (step S115: YES), the demo timer DEMO_TIMER is confirmed (step S121). If the demo timer DEMO_TIMER is “0” (step S121: YES), the effect control CPU 900 confirms the volume setting value stored in the memory area in the effect control RAM 900a (step S122). If this volume setting value is “0” or more, that is, any one of “0”, “1”, and “2”, it is determined that the current volume is not lower than the initial value (step S122: NO), A liquid crystal control command LCD_CMD (see FIG. 4) that does not display the volume adjustment / brightness adjustment screen on the liquid crystal display device 42 is generated, stored in the effect control RAM 900a (step S124), and the process proceeds to step S135. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. Will not be displayed. At this time, the effect control CPU 900 performs processing for turning off the setting screen display flag SGC_FLG.

  On the other hand, if the volume setting value is smaller than “0”, that is, if either “−1” or “−2”, it is determined that the current volume is smaller than the initial value (step S122: YES), The effect control CPU 900 sets the volume setting value to “0” and the adjustment content of the rear switch 15 (see FIG. 6A), that is, the adjustment signal received in the process of step S304 (see FIG. 30) described later. The number of SACs corresponding to BSW_DATA is read from the table TB3 stored in the simple access code table SAC_TBL shown in FIG. 6B or the table TB22 stored in the volume output increase / decrease value table VO_REG_TBL shown in FIG. Output to the sound LSI 902 (see FIG. 4). The sound LSI 902 accesses the volume output value table VL_TBL shown in FIG. 7 or the volume output value table VL_TBL_A shown in FIG. 9 stored in the sound ROM 903 to read the volume output data corresponding to the number of SACs, and the number of SACs. The volume output data in the speaker 11 corresponding to the above and the internal register address (C0H) of the sound LSI 902 are read out, and the end code (FFH) is read out. Accordingly, the sound LSI 902 adjusts the volume based on the volume output data in the speaker 11 read from the sound ROM 903, and outputs the sound source data AMOR / L (see FIG. 4) of the sound adjusted to the volume to the speaker 11 (step). S123). Thereby, even if the player turns down the volume and leaves, it can be restored to the initial volume.

  Next, the production control CPU 900 generates a liquid crystal control command LCD_CMD (see FIG. 4) that does not display the volume adjustment / brightness adjustment screen on the liquid crystal display device 42, and stores it in the production control RAM 900a (step S124). The process proceeds to S135. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. Will not be displayed. At this time, the effect control CPU 900 performs processing for turning off the setting screen display flag SGC_FLG.

  On the other hand, if the demo timer DEMO_TIMER is not “0” (step S121: NO), it is confirmed whether or not the player has adjusted the volume. That is, it is confirmed whether the left selection switch SW3 or the right selection switch SW4 of the front switch 14 has been pressed, that is, the left selection switch SW3 or the right selection switch SW4 received in the process of step S304 (see FIG. 30) described later. The contact signal FSW_DATA is confirmed (step S125). Thus, if neither the left selection switch SW3 nor the right selection switch SW4 is pressed, the effect control CPU 900 determines that the player has not adjusted the volume (step S125: NO), and proceeds to the process of step S135. Transition.

  On the other hand, if either the left selection switch SW3 or the right selection switch SW4 is pressed, the effect control CPU 900 determines that the player has adjusted the volume (step S125: YES), and the volume setting adjusted by the player is made. Based on the value, the number of SACs stored in the simple access code table SAC_TBL shown in FIG. 6B or the number of SACs in the table TB22 stored in the volume output increase / decrease value table VO_REG_TBL shown in FIG. 8 and the table TB23 . The increase / decrease value of the volume output data stored in the TB 24 is read and output to the sound LSI 902 (see FIG. 4). The sound LSI 902 accesses the volume output value table VL_TBL shown in FIG. 7 or the volume output value table VL_TBL_A shown in FIG. 9 stored in the sound ROM 903 to read the volume output data corresponding to the number of SACs, and the number of SACs. The volume output data in the speaker 11 corresponding to the above and the internal register address (C0H) of the sound LSI 902 are read out, and the end code (FFH) is read out. Accordingly, the sound LSI 902 adjusts the volume based on the volume output data in the speaker 11 read from the sound ROM 903, and outputs the sound source data AMOR / L (see FIG. 4) of the sound adjusted to the volume to the speaker 11 (step). S126).

  Next, the effect control CPU 900 clears the value of the demo timer DEMO_TIMER, resets it (for example, resets to 180 seconds) (step S127), and proceeds to the process of step S135. As a result, the demo timer DEMO_TIMER becomes “0” during the player's volume setting, thereby reducing the situation in which the volume setting value set by the player is cleared. When the demo timer DEMO_TIMER is reset, the period from the timing T3 to T6 becomes longer.

  On the other hand, the effect control CPU 900 reads the effect control command DI_DATA (see FIG. 4) stored in the memory area in the effect control RAM 900a (see FIG. 4), and this effect control command DI_DATA is being played by the player while the game is suspended. If it is not a customer waiting command indicating that there is any (step S114: NO), the value of the reset timer RST_TIMER is confirmed (step S128). If the value of the reset timer RST_TIMER is not “0” (step S128: NO), the value of the reset timer RST_TIMER is decremented by 1 (step S129), and the value of the reset timer RST_TIMER is confirmed again (step S130). If the value of the reset timer RST_TIMER is “0” (step S130: YES), a liquid crystal control command LCD_CMD (see FIG. 4) that does not display the volume adjustment / brightness adjustment screen on the liquid crystal display device 42 is generated. The data is stored in the control RAM 900a (step S131), and the process proceeds to step S137. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. Will not be displayed. At this time, the effect control CPU 900 performs processing for turning off the setting screen display flag SGC_FLG.

  On the other hand, if the value of the reset timer RST_TIMER is “0” (step S128: YES) or the value of the reset timer RST_TIMER is not “0” (step S130: NO), the effect control CPU 900 allows the player to adjust the volume. Confirm whether or not. That is, it is confirmed whether the left selection switch SW3 or the right selection switch SW4 of the front switch 14 has been pressed, that is, the left selection switch SW3 or the right selection switch SW4 received in the process of step S304 (see FIG. 30) described later. The contact signal FSW_DATA is confirmed (step S132). Thus, if neither the left selection switch SW3 nor the right selection switch SW4 is pressed, the effect control CPU 900 determines that the player has not adjusted the volume (step S132: NO), and proceeds to the process of step S135. Transition.

  On the other hand, if either the left selection switch SW3 or the right selection switch SW4 is pressed, the effect control CPU 900 determines that the player has adjusted the volume (step S132: YES), and the volume setting adjusted by the player is made. Based on the value, the number of SACs stored in the simple access code table SAC_TBL shown in FIG. 6B or the number of SACs in the table TB22 stored in the volume output increase / decrease value table VO_REG_TBL shown in FIG. 8 and the table TB23 . The increase / decrease value of the volume output data stored in the TB 24 is read and output to the sound LSI 902 (see FIG. 4). The sound LSI 902 accesses the volume output value table VL_TBL shown in FIG. 7 or the volume output value table VL_TBL_A shown in FIG. 9 stored in the sound ROM 903 to read the volume output data corresponding to the number of SACs, and the number of SACs. The volume output data in the speaker 11 corresponding to the above and the internal register address (C0H) of the sound LSI 902 are read out, and the end code (FFH) is read out. Accordingly, the sound LSI 902 adjusts the volume based on the volume output data in the speaker 11 read from the sound ROM 903, and outputs the sound source data AMOR / L (see FIG. 4) of the sound adjusted to the volume to the speaker 11 (step). S133).

  Next, the effect control CPU 900 clears the value of the reset timer RST_TIMER and resets it (for example, resets it to 5 seconds) (step S134).

  Thus, after finishing the processing as described above, the effect control CPU 900 confirms whether or not the determination switch SW5 of the front switch 14 has been pressed, that is, received in the processing of step S304 (see FIG. 30) described later. The contact signal FSW_DATA of the decision switch SW5 is confirmed (step S135). Thereby, if the determination switch SW5 is not pressed (step S135: NO), the process proceeds to step S137.

  On the other hand, if determination switch SW5 is pressed (step S135: YES), effect control CPU 900 issues a liquid crystal control command LCD_CMD (see FIG. 4) that does not display the volume adjustment / brightness adjustment screen on liquid crystal display device 42. Generated and stored in the effect control RAM 900a (step S136). As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. Will not be displayed. At this time, the effect control CPU 900 performs processing for turning off the setting screen display flag SGC_FLG.

  Next, the effect control CPU 900 confirms the adjustment content of the back switch 15 (see FIG. 6A), that is, the adjustment signal BSW_DATA received in the process of step S304 (see FIG. 30) described later, and the previous content. It is confirmed whether or not they match (step S137). If they match, the effect control CPU 900 determines that the rear switch 15 (see FIG. 6A) has not been changed at all (step S137: NO), and ends the sound output process.

  On the other hand, if they do not match, the effect control CPU 900 determines that the rear switch 15 (see FIG. 6A) has been changed (step S137: YES), and clears the volume setting value to “0”. In addition, the adjustment content of the rear switch 15 (see FIG. 6A), that is, the number of SACs corresponding to the adjustment signal BSW_DATA received in the process of step S304 (see FIG. 30) described later is shown in FIG. 6B. The table TB3 stored in the simple access code table SAC_TBL shown in FIG. 8 or the table TB22 stored in the volume output increase / decrease value table VO_REG_TBL shown in FIG. 8 is read and output to the sound LSI 902 (see FIG. 4). The sound LSI 902 accesses the volume output value table VL_TBL shown in FIG. 7 or the volume output value table VL_TBL_A shown in FIG. 9 stored in the sound ROM 903 to read the volume output data corresponding to the number of SACs. The volume output data in the speaker 11 corresponding to the number of SACs and the internal register address (C0H) of the sound LSI 902 are read out, and the end code (FFH) is read out. Accordingly, the sound LSI 902 adjusts the volume based on the volume output data in the speaker 11 read from the sound ROM 903, and outputs the sound source data AMOR / L (see FIG. 4) of the sound adjusted to the volume to the speaker 11 (step). S138).

  Next, the effect control CPU 900 generates a liquid crystal control command LCD_CMD (see FIG. 4) that does not display the volume adjustment / brightness adjustment screen on the liquid crystal display device 42, and stores it in the effect control RAM 900a (step S139). Finish the output process. As a result, the liquid crystal control command LCD_CMD is transmitted to the liquid crystal control board 120 (see FIG. 3) in the process of step S306 (see FIG. 30), which will be described later. Will not be displayed. At this time, the effect control CPU 900 performs processing for turning off the setting screen display flag SGC_FLG.

  Thus, the volume adjustment / brightness adjustment can be performed during the game as described above. However, since the volume adjustment can be performed by the front switch 14 and the rear switch 15, While both the players can make adjustments, the brightness adjustment is made with the front switch 14, so that only the player can make adjustments. This makes it possible to appropriately adjust the volume and brightness during the game. Furthermore, by optimizing the function relating to volume adjustment / brightness adjustment, it is not necessary to mount components for the volume adjustment / brightness adjustment function, thereby suppressing an increase in cost.

  In other words, in the prior art, the volume / brightness adjustment can be performed when the game is stopped, but the volume / brightness adjustment cannot be performed during the game.

  Therefore, in the present embodiment, the volume adjustment / brightness adjustment can be performed during the game, while the volume adjustment can be adjusted for both the employees of the game hall and the player, and the brightness adjustment is performed. , Only the player can adjust. This makes it possible to appropriately adjust the volume and brightness during the game.

<Description of main processing>
Thus, after finishing the process of step S14, the effect control CPU 900 generates solenoid data SOL_DATA corresponding to the solenoid operation content determined in step S13, and the generated solenoid data SOL_DATA is stored in the effect control RAM 900a. Store in the memory area (step S15).

  Next, the effect control CPU 900 accesses the sound LSI 902 and confirms whether or not any error has occurred due to noise or the like when the sound LSI 902 decodes the sound data or the like regarding the processing of step S14 (step S16). ).

  Thus, after finishing the process of step S16, the effect control CPU 900 returns to the process of step S8 again and repeats the processes of steps S8 to S16.

<Description of command reception interrupt processing>
Next, with reference to FIG. 29, a process when an effect control command DI_DATA and an effect interrupt signal DI_IRQ are transmitted from the main control board 60 during execution of such effect control main process will be described.

  As shown in FIG. 10, when the effect control CPU 900 receives the effect interrupt signal DI_IRQ, the effect control CPU 900 executes a save process for saving the contents of each register to the stack area in the effect control RAM 900a (step S200). Thereafter, the effect control CPU 900 reads the register of the input port that has received the effect control command DI_DATA (step S201), and calculates a pointer indicating the address address of the command transmission / reception memory area in the effect control RAM 900a (step S202).

  Then, the effect control CPU 900 again reads the register of the input port that has received the effect control command DI_DATA (step S203), and whether or not the value read in step S201 matches the value read in step S203. Confirm. If they do not match (step S204: NO), the process proceeds to step S207, and if they match (step S204: YES), the effect control command received from the main control board 60 at the address address corresponding to the calculated pointer. DI_DATA is stored (step S205). The stored production control command DI_DATA is read out by the production control CPU 900 during the process of step S12 shown in FIG.

  Next, the effect control CPU 900 updates the pointer indicating the address address of the command transmission / reception memory area in the effect control RAM 900a (step S206), and restores the register saved in the process of step S200 (step S207). As a result, the process returns to the effect control main process shown in FIG.

<Explanation of timer interrupt processing>
Next, with reference to FIG. 30, a process when a timer interrupt for every 1 ms set in the process (see FIG. 26) of step S7 of the effect control main process occurs will be described.

  As shown in FIG. 30, when the timer interrupt occurs every 1 ms, the effect control CPU 900 executes a save process for saving the contents of each register to the stack area in the effect control RAM 900a (step S300). After that, the effect control CPU 900 refreshes the input / output port registers provided in the effect control CPU 900 (step S301).

  Subsequently, the effect control CPU 900 transmits the solenoid data SOL_DATA stored in the memory area in the effect control RAM 900a in step S15 shown in FIG. 26 by serial transfer from the output port. Thereby, the movable accessory which is not illustrated will operate | move. Furthermore, the effect control CPU 900 transmits the motor data MOT_DATA stored in the memory area in the effect control RAM 900a by serial transfer from the output port. As a result, a movable accessory (not shown) operates (step S302). The method for generating the motor data MOT_DATA will be described in detail in step S307 described later.

  Next, the effect control CPU 900 receives a signal from the effect button device 16. That is, the effect control CPU 900 receives the effect button sensor BU_SEN (see FIG. 4) indicating whether or not the effect button device 16 has been pressed (step S303). When the effect button device 16 has been pressed by the player, the effect control CPU 900 determines an effect pattern that takes into account that the effect button device 16 has been pressed when performing the process of step S13 shown in FIG. It will be.

  Next, the effect control CPU 900 receives signals from the front switch 14 and the back switch 15. That is, the production control CPU 900 receives the contact signal FSW_DATA (see FIG. 4) of the up / down / left / right selection switches SW1 to SW4 or the decision switch SW5 of the front switch 14, and receives the adjustment signal BSW_DATA (see FIG. 4) of the back switch 15. (Step S304).

  Next, the effect control CPU 900 confirms the position of the motor based on the detection data transmitted from the motor sensor that detects the position of the motor (not shown) of the movable accessory (step S305).

  Next, as described above, the effect control CPU 900 generates the liquid crystal control command LCD_CMD generated in the processing of step S10, step S12, and step S14 shown in FIG. 26 and stored in the memory area in the effect control RAM 900a. (Refer to FIG. 3) and a liquid crystal control interrupt signal LCD_IRQ is transmitted to the liquid crystal control board 120 (step S306). As a result, a desired screen is displayed on the liquid crystal display device 42.

  Next, the production control CPU 900 generates motor data MOT_DATA corresponding to the operation content of the motor that operates the movable accessory determined in step 13 shown in FIG. 26 based on the position of the motor confirmed in step S305. Above, it stores in the memory area in presentation control RAM900a (step S307). The motor data MOT_DATA stored in the memory area in the effect control RAM 900a is transmitted by serial transfer from the output port in the process of step S302 at the time of the next 1 ms timer interruption.

  Next, the effect control CPU 900 transmits the decoration lamp output data LAMP_DATA stored in the memory area in the effect control RAM 900a in the process of step S11 shown in FIG. 26 to the decoration lamp substrate 100 (see FIG. 5) by serial transfer from the output port. At the same time, a decorative lamp output data control signal LAMP_CLK for controlling the decorative lamp output data LAMP_DATA is transmitted from the output port to the decorative lamp substrate 100 (step S308). As a result, the decoration lamp output data LAMP_DATA and the decoration lamp output data control signal LAMP_CLK for controlling the decoration lamp output data LAMP_DATA are output to the decoration lamp driving drivers 1001a to 1001c (see FIG. 5) via the buffer 1000 (see FIG. 5). Is done. In response to this, the decorative lamp driving drivers 1001a to 1001c perform driving control to turn on or turn off the plurality of decorative lamps LA, so that a desired lamp effect is performed. In the case where effect button lamp data BU_LAMP_DATA (see FIG. 5) for lighting a lamp (not shown) built in the effect button device 16 is stored in the memory area in the effect control RAM 900a, the effect is displayed. The button lamp data BU_LAMP_DATA is transmitted to the effect button device 16. Thereby, a lamp (not shown) built in the effect button device 16 is turned on.

  Next, the effect control CPU 900 reads the effect control command DI_DATA stored in the memory area in the effect control RAM 900a, and the first identification lamp 46a (see FIG. 2 and FIG. 3) corresponding to the effect control command DI_DATA. 2 Data for turning on or off the identification lamp 46b (see FIGS. 2 and 3) is generated. That is, the production control CPU 900 generates first identification lamp data ID1_LAMP_DATA and second identification lamp data ID2_LAMP_DATA, transmits the generated first identification lamp data ID1_LAMP_DATA to the first identification lamp 46a, and second identification lamp data ID2_LAMP_DATA. It transmits to the 2nd identification lamp 46b (step S309). As a result, the first identification lamp 46a or the second identification lamp 46b is turned on or off, so that the player knows whether the special symbol 1 or the special symbol 2 is fluctuating, whether it is a win or a loss. be able to.

  Next, the effect control CPU 900 increments (+1) the main loop counter ML_CNT that counts in a loop from 0 to 31 used in the process of step S8 shown in FIG. 26, and divides the incremented value by 16 (that is, 16 (Division by) is performed (step S310). Then, the effect control CPU 900 restores the register saved in the process of step S300 (step S311). As a result, the process returns to the effect control main process shown in FIG.

  Thus, according to the present embodiment described above, volume / brightness adjustment can be appropriately performed during the game.

  In the present embodiment, the volume can be adjusted by the left selection switch SW3 and the right selection switch SW4 of the front switch 14, but not limited thereto, the upper selection switch SW1, lower of the front switch 14 You may enable it to adjust with selection switch SW2. In addition, the brightness can be adjusted with the upper selection switch SW1 and the lower selection switch SW2 of the front switch 14, but not limited thereto, the adjustment is made with the left selection switch SW3 and the right selection switch SW4 of the front switch 14. You may be able to do it.

  In this embodiment, when the value of the fade-out timer FAO_TIMER is reset, it is reset when the volume is adjusted. However, it may be reset when the luminance is adjusted. That is, the processing in steps S115 to S120 shown in FIG. 28 may be provided in FIG. Needless to say, however, step S116 and step S118 are volume adjustments, and therefore are changed to luminance adjustments.

1 Pachinko machine 11 Speaker 14 Front switch (operating means)
15 Back switch 42 Liquid crystal display device (display means)
900 Production control CPU
901 Production control ROM
FAO_TIMER Fade Out Timer DEMO_TIMER Demo Timer

Claims (3)

A gaming machine that executes a lottery process resulting from a predetermined signal and displays an image effect corresponding to the lottery result on a display means,
A speaker that outputs sound according to the gaming state;
A game hall side operation means capable of operating the sound volume setting value on the game hall side;
A player-side operation means capable of operating a set value of the sound volume by the player;
Demo production execution means for executing a demonstration production display executed during non-games;
After the confirmation content indicating whether or not the lottery result is in the special game state is displayed on the display means, the image effect corresponding to the new lottery result is not displayed. After the player becomes operable, the display unit displays a volume-adjustable notification image for notifying that the setting value of the sound volume can be operated by the player-side operation unit. demonstration effect display executed by the demonstration effect execution means to means is displayed, and a display erasing means made to erase the display of the volume adjustment possible notification image, was closed,
By the operation of the sound volume setting value by the player side operation means, a volume adjustment image indicating the sound volume according to the sound volume setting value is displayed on the display means,
Although the maximum value of the sound volume that can be set by the player-side operation means is varied according to the set value of the sound volume by the game hall-side operation means, at least displayed on the display means during the game When the volume adjustment image is displayed on the display means so as not to overlap some of the changing symbols, the number of image stages indicating the volume in the volume adjustment image even if the maximum value of the sound volume is different A gaming machine that is displayed on the display means so as to be the same . The sound volume setting value that can be set by the game hall side operation means obtains the sound volume setting value from the volume output table,
The set value of the sound volume that can be set by the player side operation means reflects an increase value or a decrease value with respect to the set value of the sound volume acquired from the volume output table. Item 1. A gaming machine according to Item 1. The display erasure unit erases the display of the volume adjustable notification image after a predetermined period of time has elapsed since the demonstration effect display executed by the demonstration effect execution unit is displayed on the display unit, and then the volume adjustment is performed again. The gaming machine according to claim 1 or 2 , wherein a possible notification image is displayed.

Images