JP2015051325A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine enabled to minimize the load of a data storage region and to prevent the information necessary for a performance from being lost.SOLUTION: A performance time-varying image formed of a plurality of performance images is stored, and at least a portion of the performance time-varying image for a display request is used to form a display performance time-varying image to be used in the performance in the display request, so that the reproduction time of the display performance time-varying image is adjusted to the image display time designated for that performance. At this time, the reproduction time of the display performance time-varying image is adjusted to an image display time by thinning out another performance image different from the designated performance image which is designated to be contained without fail in the performance.

Description

  The present invention relates to a gaming machine.

  In a gaming machine that uses a game medium to perform a game, a lottery process for determining the acquisition state of the game medium is performed by entering the game medium into an area called a starting point for a bonus lottery process. By winning, you can get a lot of game media. At this time, in the gaming machine, various effects are performed in order to provide a high interest to the player.

  The effect image used for the effect at this time is generated by combining the effect image stored in advance and the material image data constituting the effect image.

  When such an effect image is displayed, it may be necessary to display it in a time shorter than the display time of the created effect image. In such a case, a reduction process is performed by thinning out any of the frame data constituting the effect image.

  This reduction processing does not use the stored movie data itself, but requires processing, so that a load is applied to the gaming machine when the movie data is displayed.

  The prior art disclosed in the following Patent Document 1 describes that the data capacity can be reduced by not using a plurality of texture images. As an example, paragraphs [1116] to [1121] Discloses a technique for reducing the data capacity by expressing a distorted image by using an expanded image and a contracted image.

JP 2011-125417 A

  In the prior art disclosed in this Patent Document 1, a process different from the original process (a process of displaying an image using a plurality of texture images shown in Patent Document 1) (an expanded image shown in Patent Document 1) The data capacity is reduced by performing processing for expressing a distorted image by using a contracted image. That is, the data capacity cannot be reduced when the original processing is performed.

  In order to reduce the data capacity or to display in a time shorter than the display time of the effect image, if the reduction process as described above is performed, an important frame image for effect in the effect image before the reduction process May be lost.

  Accordingly, an object of the present invention is to provide a gaming machine that can minimize the load on the data storage area and prevent the loss of information necessary for production.

  In order to achieve the above object, an invention according to claim 1 is used for an effect performed in a game using a game medium, and an effect moving image storage means for storing an effect moving image composed of a plurality of effect images, When a display request for the effect moving image is requested, at least a part of the effect moving image corresponding to the display request stored in the effect moving image storage unit is used to generate a display effect moving image used for the effect in the display request. Time adjustment control for adjusting the reproduction time of the display effect moving image generated by the generating means to the image display time specified for the effect performed using the effect moving image requested to be displayed Control means; and display control means for controlling display of the display effect moving image adjusted to the image display time by time adjustment control by the time adjustment control means. The time adjustment control means, when displaying the display effect moving image in an image display time shorter than the playback time of the display effect moving image generated by the generating means, the effect that constitutes the display effect moving image The reproduction time of the display effect moving image is set to the image display time by thinning out another effect image different from the designated effect image that is specified to be included in the effect of displaying the display effect moving image. adjust.

  According to the present invention, it is possible to minimize the load on the data storage area and prevent the loss of information necessary for production.

The front view of the gaming machine in the embodiment of the present invention. The perspective view of the state which open | released the glass frame provided in the front surface of the game machine in embodiment of this invention. The perspective view of the back surface side of the gaming machine in the embodiment of the present invention. The block diagram which shows the whole structure of the game machine in embodiment of this invention. The figure which shows an example of the determination table which performs the hit determination for every special symbol and normal symbol performed in the gaming machine in the embodiment of the present invention. The figure which shows an example of the symbol determination table which determines the stop symbol of the special symbol in the gaming machine in the embodiment of the present invention. The figure which shows an example of the big hit game completion | finish setting data table for determining the game state after the big hit game performed with the game machine in embodiment of this invention is complete | finished. The figure which shows an example of the special electric accessory operating mode determination table for determining the big winning opening opening mode determination table. The figure which shows the structure of the special prize opening release mode determination table determined using the special electric accessory operation mode determination table shown in FIG. The figure which shows the fluctuation pattern determination table which determines the fluctuation pattern of a special symbol. The figure which shows an example of the fluctuation pattern determination table for determining the fluctuation aspect of the production | presentation symbol displayed in a 1st liquid crystal display device and a 2nd liquid crystal display device. The block diagram which shows the structure of the frame buffer used in the image control board of the game machine in embodiment of this invention. The figure which shows the animation information used in the image control board of the game machine in embodiment of this invention. An example of a display list including drawing control commands used on an image control board of a gaming machine according to an embodiment of the present invention. The flowchart which shows the detailed flow of the main process performed with the main control board of the game machine in embodiment of this invention. The flowchart which shows the detailed flow of the timer interruption process performed with the main control board of the game machine in embodiment of this invention. The flowchart which shows the detailed flow of the special figure special electric control process performed with the main control board of the game machine in embodiment of this invention. The flowchart which shows the detailed flow of the special symbol memory | storage determination process performed with the main control board of the game machine in embodiment of this invention. The flowchart which shows the detailed flow of the main process performed with the presentation control board of the gaming machine in the embodiment of the present invention. The flowchart which shows the detailed flow of the timer interruption process performed with the presentation control board of the gaming machine in the embodiment of the present invention. The flowchart which shows the detailed flow of the command analysis process performed with the presentation control board of the gaming machine in the embodiment of the present invention. The flowchart which shows the continuation of the flowchart which shows the detailed flow of the command analysis process performed with the presentation control board of the gaming machine in the embodiment of the present invention. The flowchart which shows the detailed flow of the main process performed in the image control board of the game machine in embodiment of this invention. The flowchart which shows the detailed flow of the interruption process (drawing completion interruption process) performed in liquid crystal control CPU of the game machine in embodiment of this invention. The flowchart which shows the detailed flow of the image display time adjustment control processing performed in the liquid crystal control CPU which the game machine in embodiment of this invention comprises. The figure which shows the table information which designated the designated image frame (designated effect image). The figure which shows the reproduction | regeneration information matched with the original movie data 1 and this original movie data 1. FIG. The figure which shows an example of the image data (reproduction frame data) produced | generated until the production | generation image reproduced | regenerated by a time adjustment process is produced | generated. The figure which shows the reproduction information matched with the original movie data 2 and this original movie data 2. FIG. The figure which shows an example of the image data (reproduction frame data) produced | generated until the production | generation image reproduced | regenerated by a time adjustment process is produced | generated. The figure which shows the "reproduction | regeneration frame data 2" produced | generated using the reproduction | regeneration information 2 with respect to the original movie data 1. FIG. The figure which shows the "reproduction | regeneration frame data 2" produced | generated using the reproduction | regeneration information 2 with respect to the original movie data 1. FIG. The figure which shows the "reproduction | regeneration frame data 2" produced | generated using the reproduction | regeneration information 2 with respect to the original movie data 1. FIG. The figure which shows an example of the reproduction | regeneration movie data produced by the time adjustment process performed in liquid crystal control CPU which the gaming machine in embodiment of this invention comprises. The figure which imaged the process process of the time adjustment process performed in liquid crystal control CPU which the gaming machine in embodiment of this invention comprises.

  Hereinafter, an embodiment of a gaming machine according to the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is an example of a device configuration diagram of a gaming machine 1 configured by applying the gaming machine according to the embodiment of the present invention. FIG. 2 shows the gaming machine 1 in a state where the glass frame of the present invention is opened. FIG. 3 is a perspective view of the back side of one gaming machine 1.

  The gaming machine 1 includes an outer frame 60 attached to an island facility of a game store, and a glass frame 50 that is rotatably supported by the outer frame 60 (see FIGS. 1 and 2). Further, the outer frame 60 is provided with a game board 2 in which a game area 6 in which game balls flow down is formed. In the glass frame 50, an operation handle 3 for launching a game ball toward the game area 6 by being rotated, an audio output device 32 including a speaker, an effect lighting device 34 having a plurality of lamps, An effect button 35 for changing the effect mode by pressing operation and a cross key 36 capable of pressing operation in at least two directions (usually four directions) are provided.

  Further, the glass frame 50 is provided with a tray 40 for storing a plurality of game balls, and the tray 40 has a downward slope so that the game balls flow down toward the operation handle 3. (See FIG. 2). A receiving opening for receiving a game ball is provided at the end of the downward slope of the tray 40, and the game ball received in the receiving opening is driven by the ball feed solenoid 4b, so that the glass frame 50 One game ball is sent to the ball feed opening 41 provided on the back surface one by one.

  Then, the game ball sent out to the ball feed opening 41 is guided to the end of the downward slope of the launch rail 42 by the launch rail 42 having a downward slope toward the launching member 4c. A stopper 43 for stopping and stopping the game ball is provided above the end of the firing rail 42 that is inclined downward, and the game ball sent out from the ball feed opening 41 is the end of the downward inclination of the launch rail 42. One game ball is stopped at the section (see FIG. 2).

  Then, when the player rotates the operation handle 3, the launch volume 3b directly connected to the operation handle 3 also rotates, and the launch intensity of the game ball is adjusted by the launch volume 3b, and the launch is performed with the adjusted launch intensity. The launch member 4c directly connected to the solenoid 4a for rotation rotates. As the launch member 4c rotates, the launch ball 4c launches the game ball stored at the end of the downward slope of the launch rail 42, and the game ball is launched into the game area 6.

  When the game ball fired as described above rises between the rails 5a and 5b from the launch rail 42 and exceeds the ball return prevention piece 5c, the game ball reaches the game area 6 and then freely falls within the game area 6. . At this time, the game ball falls unpredictably by a plurality of nails and windmills provided in the game area 6.

  The game area 6 is provided with a plurality of general winning awards 12.

  Each of these general winning ports 12 is provided with a general winning port detecting switch 12a. When the general winning port detecting switch 12a detects a winning of a game ball, a predetermined winning ball (for example, ten game balls) is provided. To be paid out.

  Further, in the area below the center of the game area 6, there are a first start port 14 and a second start port 15 that constitute a start area into which game balls can enter, and a second large area in which game balls can enter. A winning opening 17 is provided.

  The second start port 15 includes a pair of second start port movable pieces 15b, and the pair of second start port movable pieces 15b is maintained in a closed state. The pair of second start opening movable pieces 15b are controlled to move to the “second mode” in which the pair is opened.

  At this time, when the second start port 15 is controlled to the second mode, the pair of second start port movable pieces 15b function as a tray, and a game ball wins the second start port 15. It becomes easy. That is, when the second start port 15 is in the first mode, there is no game ball winning opportunity, and when it is in the second mode, the game ball winning opportunity is increased as compared to the first mode.

  Here, the first start port 14 is provided with a first start port detection switch 14a for detecting the entrance of a game ball, and the second start port 15 is provided with a second start port detection switch for detecting the entrance of a game ball. 15a is provided. When the first start port detection switch 14a or the second start port detection switch 15a detects the entry of a game ball, a special symbol determination random number value is acquired, and a right acquisition lottery (to be described later) Hereinafter, “Lottery for jackpot” is performed.

  In addition, when the first start port detection switch 14a or the second start port detection switch 15a detects the entry of a game ball, the predetermined start port detection switch 12a has a predetermined value in the same manner as when the general winning port detection switch 12a detects the winning of a game ball. Prize balls (for example, three game balls) are paid out.

  In addition, the second grand prize winning port 17 is configured by an opening formed in the game board 2.

  A movable piece 17b for the second big prize opening is provided at the right end of the second big prize opening 17, and the second big prize prize is moved by moving one of the movable pieces 17b for the second big prize opening as a fulcrum. An open state that makes it easy to win the mouth 17 and a closed state that cannot win a prize are controlled.

  When the movable piece 17b for the second big prize opening is opened, the movable piece 17b for the second big prize opening functions as a tray for guiding the game ball into the second big prize opening 17, and the game ball is the second. It is possible to enter the big winning opening 17. The second big prize opening 17 is provided with a second big prize opening detection switch 17a. When the second big prize opening detection switch 17a detects the entry of a game ball, a predetermined prize ball ( For example, 15 game balls) are paid out.

  Furthermore, in the area on the right side of the game area 6, there are provided a normal symbol gate 13 constituting a normal area through which game balls can pass and a first grand prize opening 16 through which game balls can enter.

  For this reason, if the operation handle 3 is rotated largely and a game ball is not launched with a greater force than the game ball is launched in the left area of the game area 6, the game will be displayed in the normal symbol gate 13 and the first big prize opening 16. The ball is configured not to pass or win.

  In particular, even if the short game state, which will be described later, is entered, if the game ball flows down to the left side of the game area 6, the game ball will not normally pass through the symbol gate 13, so that it is at the second start port 15. The pair of second start opening movable pieces 15b are not opened, and it is difficult for a game ball to win the second start opening 15.

  The normal symbol gate 13 is provided with a gate detection switch 13a for detecting the passage of the game ball. When the gate detection switch 13a detects the passage of the game ball, the normal symbol determination random number value is acquired, which will be described later. “Normal lottery” is performed. This normal symbol gate 13 is also provided in the area on the right side of the game area.

  The first grand prize opening 16 is normally kept closed by the first big prize opening opening / closing door 16b, and it is impossible to enter a game ball. In contrast, when a special game, which will be described later, is started, the first grand prize opening opening / closing door 16b is opened, and the first big prize opening opening / closing door 16b puts the game ball in the first big winning opening 16; It functions as a receiving tray that guides the game ball and can enter the first grand prize opening 16. The first grand prize opening 16 is provided with a first big prize opening detection switch 16a. When the first big prize opening detection switch 16a detects the entry of a game ball, a predetermined prize ball (for example, 15 Game balls).

  Furthermore, at the bottom of the game area 6, the player does not enter any of the general winning opening 12, the first starting opening 14, the second starting opening 15, the first major winning opening 16, and the second major winning opening 17. An out port 11 is provided for discharging the game balls.

  In addition, a decoration member 7 that affects the flow of the game ball is provided in the center of the game area 6. A first liquid crystal display device 31 (hereinafter also referred to as “main liquid crystal”) configured by an LCD (Liquid Crystal Display) or the like is provided at a substantially central portion of the decorative member 7, and the first liquid crystal display device. A decoration device 33 a is provided above 31. A second liquid crystal display device 37 (33b) (hereinafter also referred to as “sub liquid crystal”) having a size smaller than that of the first liquid crystal display device 31 is provided above the first liquid crystal display device 31.

  The decoration device 33a and the second liquid crystal display device 37 (33b) are driven by the effect drive device 33. That is, the second liquid crystal display device 37 (33b) has a function and a drive for displaying the effect image. It has the function to do. The second liquid crystal display device 37 (33 b) displays an effect image by a signal from the image control board 150 and is driven by the effect driving device 33.

  In FIG. 1 and FIG. 1, an example of the second liquid crystal display device 37 having a size (4.3 inches) smaller than the size (19 inches) of the first liquid crystal display device 31 is shown as an example. The second liquid crystal display device 37 may be larger in size than the first liquid crystal display device 31.

  The first liquid crystal display device 31 displays a demo image during standby when no effects are being performed, or displays an image according to the progress of the game. Among them, three effect symbols 38 for informing a lottery lottery result to be described later are displayed, and a combination of specific effect symbols 38 (for example, 777) is stopped and displayed as a result of the jackpot lottery. A big hit is announced.

  More specifically, when a game ball enters the first start port 14 or the second start port 15, the three effect symbols 38 are displayed in a variable manner by scroll display (rotation display), and a predetermined time has elapsed. Later, the scrolling is stopped, and the effect design 38 is stopped and displayed. Further, by displaying an effect image composed of characters or the like during the variation display of the effect symbol 38, a high expectation that the player may win a big hit is given to the player.

  The decoration device 33a or the like driven by the effect drive device 33 gives a player a sense of expectation by an operation mode using the effect image.

  The decoration device 33a driven by the effect drive device 33 can move in the vertical direction simultaneously with the second liquid crystal display device 37 (33b) (of course, it is not limited to the vertical direction and can be moved in the vertical and horizontal directions). Thus, the movement in the vertical direction moves to the front surface of the first liquid crystal display device 31. The decoration device 33a is equipped with an effect lighting device 34 and lights up in conjunction with the movement of the decoration device 33a or independently.

  Similarly to the decoration device 33a, the second liquid crystal display device 37 (33b) can be moved by being driven by the effect drive device 33, and the second liquid crystal display device 37 shown in FIG. Is shown in a state of being stored in a horizontally-oriented manner with the up and down direction.

  In the state of this horizontal orientation, the second liquid crystal display device 37 moves to the front surface of the substantially central portion of the first liquid crystal display device by the lowering operation.

  Furthermore, in addition to the above-described various production devices, the audio output device 32 outputs BGM (background music), SE (sound effects), etc., and produces productions using sound. The illumination direction and the emission color of the light are changed to produce effects by illumination, and are provided at a plurality of positions.

  In the lower right of the game area 6, a first special symbol display device 20, a second special symbol display device 21, a normal symbol display device 22, a first special symbol hold indicator 23, a second special symbol hold indicator 24, a normal A symbol hold indicator 25 is provided.

  The first special symbol display device 20 informs the result of the jackpot lottery performed when a game ball has entered the first start port 14, and is a plurality of lighting composed of LEDs or the like. It is comprised by the member. One or more predetermined lighting members blink according to the result of the lottery lottery, and the lighting members in the blinking state are lit simultaneously with the stop display of the effect symbol 38.

  The first special symbol display device 20 can also be configured by a 7-segment LED. That is, a plurality of special symbols corresponding to the jackpot lottery result are provided, and the lottery result is notified to the player by displaying the special symbol corresponding to the jackpot lottery result on the first special symbol display device 20. I am doing so. For example, “7” is displayed when the jackpot is won, and “−” is displayed when the player wins. “7” and “−” displayed in this way are special symbols, but these special symbols are not displayed immediately, but are displayed in a stopped state after being displayed for a predetermined time. .

  Here, the “successful lottery” means that when a game ball enters the first starting port 14 or the second starting port 15, a special symbol determining random number value is acquired, and the acquired special symbol determining random value is acquired. Is a random number value corresponding to “big hit” or a random number value corresponding to “small hit”. The jackpot lottery result is not immediately notified to the player, and the first special symbol display device 20 displays a variation such as blinking of the special symbol, and when the predetermined variation time has passed, the jackpot lottery result The special symbol corresponding to is stopped and displayed so that the player is notified of the lottery result.

  The second special symbol display device 21 is for notifying a lottery result of a jackpot that is performed when a game ball enters the second start port 15, and the display mode is the above-described first display mode. This is the same as the special symbol display mode in the special symbol display device 20.

  Further, in this embodiment, “big hit” means that a right to win a big hit game is obtained in a big win lottery performed on condition that a game ball has entered the first start port 14 or the second start port 15 Say what you did. In the “hit game”, a round game in which the first big prize opening 16 or the second big prize opening 17 is opened is performed a predetermined number of times (for example, 15 times). A predetermined time is set for the maximum opening time of the first grand prize port 16 or the second grand prize port 17 in each round game, and during this time, the first grand prize port 16 or the second grand prize port 17 is set. When a predetermined number of game balls (for example, nine) enter, one round game is completed.

  In other words, the “big hit game” is a game in which a game ball can enter the first grand prize winning opening 16 or the second big winning prize opening 17 and the player can acquire a winning ball according to the winning prize.

  The normal symbol display device 22 is for notifying the lottery result of the normal symbol that is performed when the game ball passes through the normal symbol gate 13. As will be described in detail later, when the winning symbol is won by the normal symbol lottery, the normal symbol display device 22 is turned on, and then the second start port 15 is controlled to the second mode for a predetermined time.

  Here, “normal symbol lottery” means that when a game ball passes through the normal symbol gate 13, the normal symbol determination random number value is acquired, and the acquired normal symbol determination random value corresponds to “winning”. This is a process for determining whether or not a random value. The lottery result of the normal symbol is not always notified immediately after the game ball passes through the normal symbol gate 13, but the normal symbol display device 22 displays a variation such as blinking of the normal symbol. When the fluctuation time elapses, the normal symbol corresponding to the lottery result of the normal symbol is stopped and displayed so that the player is notified of the lottery result.

  Furthermore, if a game ball enters the first start port 14 or the second start port 15 during special symbol fluctuation display or a special game to be described later, and if a big win lottery cannot be performed immediately, a certain condition The right to win a jackpot will be withheld.

  More specifically, the random number value for special symbol determination acquired when the game ball enters the first start port 14 is stored as the first hold, and when the game ball enters the second start port 15 The acquired special symbol determination random number value is stored as the second hold.

  For both of these holds (first hold and second hold), the upper limit hold number is set to four, and the hold numbers are respectively set to the first special symbol hold indicator 23 and the second special symbol hold indicator 24. Is displayed.

  When there is one first hold, the leftmost LED of the first special symbol hold indicator 23 lights up, and when there are two first holds, the leftmost end of the first special symbol hold indicator 23 The two LEDs turn on. When there are three first holds, three LEDs blink from the leftmost end of the first special symbol hold indicator 23 and the right LED is lit. When there are four first holds, the first Four LEDs blink from the leftmost end of the special symbol hold indicator 23.

  The second special symbol hold indicator 24 also displays the number of second hold on hold in the same manner as described above.

  The upper limit reserved number of normal symbols is also set to four, and the reserved number of normal symbols is displayed in the same manner as the first special symbol hold indicator 23 and the second special symbol hold indicator 24. Displayed on the instrument 25.

  The glass frame 50 supports a glass plate 52 that covers the game area 6 so as to be visible in front of the game board 2 (player side). The glass plate 52 is detachably fixed to the glass frame 50.

  The glass frame 50 is connected to the outer frame 60 via a hinge mechanism 51 on one end side in the left-right direction (for example, the left side facing the gaming machine 1). The end side (for example, the right side facing the gaming machine 1) can be rotated in a direction to release from the outer frame 60. The glass frame 50 covers the game board 2 together with the glass plate 52, and can be opened like a door with the hinge mechanism 51 as a fulcrum to open the inner part of the outer frame 60 including the game board 2.

  On the other end side of the glass frame 50, a lock mechanism for fixing the other end side of the glass frame 50 to the outer frame 60 is provided. The fixing by the lock mechanism can be released by a dedicated key. The glass frame 50 is also provided with a door opening switch 133 that detects whether or not the glass frame 50 is opened from the outer frame 60.

  On the back surface of the gaming machine 1, as shown in FIG. 3, a main control board 110, an effect control board 120, a payout control board 130, a power supply board 170, a game information output terminal board 30, and the like are provided. The power supply board 170 is provided with a power plug 171 for supplying power to the gaming machine 1 and a power switch (not shown).

  Next, control means for controlling the progress of the game will be described using the block diagram of the entire gaming machine 1 in FIG.

  The main control board 110 is a main control means for controlling the basic operation of the game, and receives various detection signals from the first start port detection switch 14a, etc., and the first special symbol display device 20 and the first big winning port opening / closing solenoid. The game is controlled by driving 16c and the like.

  The main control board 110 includes at least a one-chip microcomputer 110m including a main CPU 110a, a main ROM 110b, and a main RAM 110c, an input port for main control, and an output port (not shown).

  The main control input port includes a payout control board 130, a general winning port detection switch 12a for detecting that a game ball has entered the general winning port 12, and a game ball having entered the normal symbol gate 13. Gate detection switch 13a to detect, first start port detection switch 14a to detect that a game ball has entered the first start port 14, and second start to detect that a game ball has entered the second start port 15 The mouth detection switch 15a, the first grand prize opening detection switch 16a that detects that a game ball has entered the first grand prize opening 16, and the second that detects that a game ball has entered the second grand prize opening 17 A big prize opening detection switch 17a is connected. Various signals are input to the main control board 110 through the main control input port.

  The output port for main control includes a payout control board 130, a start port opening / closing solenoid 15c for opening / closing the pair of second start port movable pieces 15b of the second start port 15, and a first big prize opening opening / closing door 16b. The first large winning opening / closing solenoid 16c for operating the second large winning opening / closing solenoid 17c for operating the movable piece 17b for the second large winning opening, the first special symbol display device 20 for displaying special symbols, and the second special symbol. Display device 21, normal symbol display device 22 for displaying normal symbols, first special symbol hold indicator 23 and second special symbol hold indicator 24 for displaying the number of reserved symbols for special symbols, and the number of reserved balls for normal symbols The normal symbol hold display 25 and the game information output terminal board 30 for outputting an external information signal are connected. Various signals are output from the main control output port.

  The main CPU 110a reads out a program stored in the main ROM 110b based on an input signal from each detection switch or timer, performs arithmetic processing, directly controls each device or display, or determines the result of the arithmetic processing. In response, a command is transmitted to another board.

  The main CPU 110a can perform a jackpot lottery on the holding ball before the lottery process on the holding ball and pre-acquire (pre-read) the lottery result. The image is sent to the image control board 150 via the control board 120.

  The main ROM 110b of the main control board 110 stores a game control program and data and tables necessary for determining various games. For example, (1) a jackpot determination table referred to in the jackpot lottery, (2) a hit determination table referred to in the normal symbol lottery, (3) a symbol determination table for determining a special symbol stop symbol, and (4) a jackpot end Big hit game end setting data table for determining the subsequent gaming state, (5) Special electric accessory actuating mode determination table for determining the opening / closing conditions of the opening / closing doors of the first big winning opening 16 and the second big winning opening 17 , (6) a big prize opening opening determination table for specifying the opening manner of the first big winning opening 16 and the second big winning opening 17, (6) a variation pattern determining table for determining a variation pattern of special symbols, and the like. ing.

  Note that the above-described table is merely an example of characteristic tables among the tables in the present embodiment, and a number of other tables and programs (not shown) are provided for the progress of the game. ing.

  Next, details of various tables stored in the main ROM 110b of the main control board 110 will be described with reference to FIGS.

  FIG. 5 is a diagram showing an example of a determination table for performing a hit determination for each special symbol and normal symbol performed in the gaming machine according to the embodiment of the present invention.

  FIG. 5 (a-1) and FIG. 5 (a-2) are diagrams showing a jackpot determination table used for the “big winner lottery”.

  FIG. 5A-1 is a jackpot determination table (a jackpot determination table for the first special symbol display device) referred to in the first special symbol display device 20, and FIG. It is a jackpot determination table (a jackpot determination table for the second special symbol display device) referred to in the special symbol display device 21. In the tables of FIG. 5 (a-1) and FIG. 5 (a-2), although the winning probabilities for small hits are different, the jackpot probabilities are the same.

  Specifically, the big hit determination table is for determining “big hit”, “small hit”, or “losing” based on the current probability gaming state and the acquired random numbers for determining special symbols.

  For example, according to the jackpot determination table for the first special symbol display device shown in FIG. 5 (a-1), in the low probability gaming state, all the special symbol determinations “7” and “8” are performed. On the other hand, when the random number value is determined to be a jackpot, all the 20 special symbol determination random numbers “7” to “26” are determined to be a jackpot when the gaming state is a high probability game state.

  Further, according to the jackpot determination table for the first special symbol display device shown in FIG. 5 (a-1), the special symbol determination for either the low probability gaming state or the high probability gaming state. When the random number values are all four special symbol determination random values of “50”, “100”, “150”, and “200”, it is determined as “small hit”. Although not shown, when the random number is other than the special symbol determination random number shown above, it is determined as “lost”.

  Accordingly, since the random number range of the special symbol determination random number value is “0” to “598”, the probability of being determined as “big hit” in the low-probability gaming state is “1 / 299.5” and high The probability of being determined as “big hit” in the probability gaming state is “1 / 29.9”, which is approximately 10 times.

  Further, in the first special symbol display device 20, the probability of being determined as “small hit” is “1 / 149.75” regardless of whether the gaming state is the low probability gaming state or the high probability gaming state.

  Next, FIG. 5B is a diagram showing a hit determination table used for “ordinary symbol lottery”.

  Specifically, the winning determination table is for determining “winning” or “losing” based on the presence / absence of the short-time gaming state and the acquired random number for normal symbol determination.

  For example, according to the hit determination table shown in FIG. 5B, in the non-short-time gaming state, one normal symbol determination random value of “0” is determined to be a win, while in the short-time gaming state. In some cases, it is determined that all 65535 normal symbol determining random numbers from “0” to “65534” are hits. Although not shown, if the random number is other than the normal symbol determining random number shown above, it is determined as “lost”.

  Accordingly, since the random number range of the normal symbol determination random number value is “0” to “65535”, the probability of being determined as “winning” in the non-time saving gaming state is “1/65536”, and the time saving gaming state The probability of being determined as “winning” at the time of is “65535/65536”.

  FIG. 6 is a diagram showing a symbol determination table for determining a special symbol stop symbol.

  FIG. 6A is a symbol determination table that is referred to in order to determine a stop symbol at the time of a big hit, and FIG. 6B is a symbol that is referred to in order to determine a stop symbol at the time of a big hit. FIG. 6C is a symbol determination table that is referred to in order to determine a symbol to be stopped when a loss occurs.

  Specifically, according to the symbol determination table shown in FIG. 6, a special ball display device type (a type of a start opening in which a game ball has won) and a game ball at the first start port 14 or the second start port 15. The special symbol type (stop symbol data) is determined based on the jackpot symbol random number value or the small bonus symbol random number value acquired when the ball is entered.

  For example, the first special symbol display device 20 refers to the symbol determination table shown in FIG. 6A in the case of “big hit”, and if the acquired big hit symbol random number value is “55”, the stopped symbol data As “03” (special symbol 3 (first probability variation 3)).

  Further, in the first special symbol display device 20, when “small hit”, the symbol determination table shown in FIG. 6B is referred to, and if the acquired random number value for small hit symbol is “50”, it is stopped. The symbol data is determined as “08” (special symbol B (small hit B)).

  In the case of “losing”, the symbol determination table shown in FIG. 6C is referred to, and “00” (special symbol 0 (losing)) is determined as stop symbol data. That is, in the case of “losing”, any random number value is determined as stop symbol data of “00”.

  Then, at the time of starting the change of the special symbol, an effect designating command is generated as special symbol information based on the determined special symbol type (stop symbol data). Here, the production symbol designation command is composed of data of “2 bytes” as a unit command, and includes “1 byte” of MODE data for identifying the control command and the contents of the control command to be executed. It consists of “1 byte” worth of DATA data. The same applies to a variation pattern designation command described later.

  As will be described later, the game state after the jackpot game (see FIG. 7) and the type of jackpot game (see FIG. 8) are determined by the type of special symbol (stop symbol data). It can be said that the type determines the gaming state after the jackpot game ends and the type of jackpot game.

  FIG. 7 is a jackpot game end setting data table for determining the gaming state after the jackpot game ends.

  Based on the special symbol type (stop symbol data) and the state stored in the game state buffer, the high probability game flag setting, the number of high probability games (X ), A short-time game flag, and a short-time count (J) are set.

  Here, the “gaming state buffer” is information indicating the gaming state at the time of winning the big hit. The gaming state includes a combination of a short-time gaming state (or a non-short-time gaming state) and a high probability gaming state (or low probability gaming state).

  Specifically, if the gaming state buffer is “00H”, it indicates the gaming state information of the low-probability gaming state and the non-short-time gaming state in which both the short-time gaming flag and the high-probability gaming flag are not set. If the gaming state buffer is “01H”, the short-time gaming flag is not set, but the high-probability gaming flag indicates gaming state information of the high-probability gaming state and the non-short-time gaming state that are set. If the gaming state buffer is “02H”, it indicates gaming state information of a low-probability gaming state and a short-time gaming state in which the short-time gaming flag is set but the high-probability gaming flag is not set. If the game state buffer is “03H”, it indicates the game state information of the high-probability gaming state and the short-time gaming state in which both the short-time gaming flag and the high-probability gaming flag are set.

  In the jackpot game end setting data table shown in FIG. 7, even if the type of the same special symbol, the setting of the short-time game flag and the number of short-time games (J) are made different based on the information stored in the game state buffer. Is possible.

  Specifically, when the type of the special symbol is special symbol 3 (corresponding to stop symbol data 03, first probability variation jackpot “3”), regarding the high probability game flag and the high probability game number (X), Regardless of the information stored in the state buffer, the high probability game flag is set after the jackpot game ends, and the high probability game count (X) is set to “10000 times”.

  On the other hand, regarding the short-time game flag and the short-time number of times (J), if information (“00H” or “01H”) indicating a game state in which the short-time game flag is not set is stored in the game state buffer, Does not set the short-time game flag, and sets the short-time number (J) to “0”. On the other hand, if information (“02H” or “03H”) indicating the gaming state in which the short-time gaming flag is set is stored in the gaming state buffer, the short-time gaming flag is set after the big hit game is finished. , The number of time reduction (J) is set to “10000 times”.

  Thereby, the number of time reductions (J) can be changed according to the gaming state at the time of winning the jackpot, and the player can be interested in the gaming state at the time of winning the jackpot.

  FIG. 8 is a special electric accessory actuating mode determination table for determining the special winning opening opening mode determining table.

  With reference to the special electric accessory operating mode determination table shown in FIG. 8, the special winning opening opening mode determination table is determined based on the type of special symbol (stop symbol data).

  As will be described later, since the jackpot game is executed based on the jackpot opening mode determination table, it can be said that the jackpot opening mode determination table indicates the type of jackpot game.

  Further, the special electric accessory actuating mode determination table shown in FIG. 8 is characterized in that, in the second special symbol display device 21 that is actuated when a game ball enters the second starting port 15, the “short hit table” is used. "Is not determined.

  This is because, in the non-short-time gaming state, almost no gaming ball enters the second starting port 15, but “short hit” is determined when a gaming ball enters the second starting port 15. This is because even if the short-time gaming state is provided, the player's willingness to play may be reduced.

  In the present embodiment, the second special symbol display device 21 is configured not to determine the “short hit table”. Of course, the second special symbol display device 21 also determines the “short hit table”. You may comprise. However, in the case of determining the “short hit table” in the second special symbol display device 21, compared with the first special symbol display device 20 that is activated when a game ball enters the first start port 14, By configuring the “short hit table” to be difficult to determine for the reasons described above, it is possible to prevent a decrease in game motivation.

  FIG. 9 is a diagram showing a configuration of the big prize opening opening mode determination table determined in FIG. 8, and the first big winning hole opening / closing door 16b or the second big winning hole is used according to the big winning hole opening mode determination table. The opening / closing conditions of the movable piece 17b are determined.

  FIG. 9A shows a big winning opening opening determination table group for jackpots that is referred to in the jackpot game, and is composed of a long winning table, a short winning table, and an advanced winning table.

  FIG. 9B shows a big winning opening releasing mode determination table group for small hits determined at the small hit game.

  Then, a long hit game is executed based on the long hit table, a short hit game is executed based on the short hit table, a development game as described later is executed based on the developed hit table, The small hit game is executed based on the winning opening opening mode determination table.

  In the big winning opening opening determination table for jackpot shown in FIG. 9 (a), the type of the big winning opening to be opened (the first big winning opening 16 or the second big winning opening 17) and the one big win game The maximum number of round games (R), the specified number indicating the maximum number of winnings in the big winning opening in one round, the start interval time from the start of the big hit game to the execution of the first round game, and in each round game Maximum number of times of opening of the grand prize opening (K), opening time of the big winning opening for one opening of each round game, and closing time of the big winning opening for one opening of each round game And the closing interval time of the big prize opening from the end of one round game to the execution of the next round game, and the end interval time from the end of the last round game to the end of the jackpot game Are 憶.

  On the other hand, in the large winning opening opening determination table for small hits shown in FIG. 9B, the type of the large winning opening to be opened (the first large winning opening 16 or the second large winning opening 17), The maximum number of times of opening (K) in a single small hit game, a specified number indicating the maximum number of winning points in a single winning game, and the first large winning opening is opened from the start of the small hit game Until the end of the small hit game from the end of the closing time of the last prize winning opening and the closing time of the last prize winning opening The interval time is stored.

  Here, according to the long winning table of the big winning prize opening opening determination table for jackpot shown in FIG. 9A, the first big winning opening opening / closing door 16b is operated, and the first winning prize opening / closing door 16b is located on the right side of the game area 6. The grand prize winning opening 16 can be opened up to a maximum of “approximately 29 seconds” per round.

  However, when the specified number (9) of game balls have won the first grand prize opening 16 before the opening time has passed “approximately 29 seconds”, the operation of the first grand prize opening opening / closing door 16b is terminated. The game for one round will end.

  Here, the short win table of the big winning prize opening manner determination table for jackpots shown in FIG. 9A and the big winning opening release mode determination table for small hits shown in FIG. 9B are the maximum number of round games ( R), the maximum number of times of opening (K), the closing interval time, and the closing time of the big winning opening at each opening number, there are data differences, but the same second big winning opening 17 performs the same opening / closing operation (second large) The winning opening 17 repeats “opening for 0.052 seconds” and closing for “2.0 seconds” for “15 times”), and the player is “short win game” or “small hit game” from the appearance. Cannot be determined.

  Thereby, it is possible to cause the player to guess whether the game is “short hit game” or “small hit game”.

  In this embodiment, the opening time in the “short hit game” and the opening time in the “small hit game” are set to the same opening time (“0.052 seconds”), and the closing time in the “short hit game” An example is shown in which the closing time in the “small hit game” is set to the same closing time (“2 seconds”).

  Of course, the present invention is not limited to this, and a configuration in which a time difference that the player cannot discriminate between “short win game” and “small hit game” may be provided.

  In addition, the per-development table of the big winning prize opening mode determination table for jackpot shown in FIG. 9A is also the above-described short winning game and small winning game until the third big winning opening is opened (K = 3). The second grand prize opening 17 performs the same opening / closing operation (the second big prize opening 17 repeats an opening time of “0.052 seconds” and a closing time of “2.0 seconds”), and the player looks Therefore, it is not possible to determine whether the game is “game per development, game per short, or game per short”.

  However, from the opening of the fourth grand prize opening (maximum number of round games (R) = "2", maximum number of big winning openings (K) = "1"), the opening of the big prize opening for games per development The time becomes longer ("approximately 29 seconds"), and the game per development can be discriminated from the short win game and the small hit game.

  For this reason, a game that first causes the player to recognize that the game is a short hit game or a small hit game, and then causes the player to recognize that the game ball is a jackpot game that can be acquired (this game is referred to as “game per development”). It can be performed.

  In this embodiment, until the opening of the big prize opening where the game per development becomes indistinguishable from the short hit game and the small hit game, the opening time of the big prize opening of the game per development is reduced to the short win game and the small hit game. The opening time is set to the same opening time ("0.052 seconds") and the closing time of the big winning opening for games per development is the closing time of the big winning opening for short win games and small hit games And the same closing time ("2 seconds"). However, even if the game is not set at the same time, a difference in time in which the player cannot determine whether the game per development, the game per short hit, or the game per small hit may be provided.

  In addition, the short opening time (“0.052 seconds”) of “short win game” and “small hit game” and the short opening time (“0.052 seconds”) of the first half of “game per development” are as described above. Thus, even if the movable piece 17b for the second big prize opening is actuated, it is necessary to win the second big prize opening 17 because it is shorter than the time for which one game ball is fired ("approximately 0.6 seconds"). Is difficult.

  For this reason, it can be said that the opening mode of “short hit game” and “small hit game” and the opening mode of the first half of “game per development” are “unfavorable opening mode” for the player.

  On the other hand, the long release time of “game per long” (“approximately 29 seconds”) and the long release time of the latter half of “game per development” (“approximately 29 seconds”) are the time (one game ball is fired) ( It is longer than “approximately 0.6 seconds”), and can be said to be an “advantageous release mode” for the player.

  Further, according to the jackpot big winning opening opening determination table shown in FIG. 9A, the maximum number of round games (R) at the time of all jackpots regardless of the long win game, the short win game, or the development game. ) Is set to the same number of times. For this reason, there is no need to provide a display device for identifying the number of round games as in the prior art.

  FIG. 10 is a diagram showing a variation pattern determination table for determining a variation pattern of special symbols as will be described later.

  Specifically, according to the special symbol variation pattern determination table shown in FIG. 10, the special symbol display device that operates (the type of the starting opening that the game ball won), the jackpot determination result, the special symbol to stop, and the short-time gaming state Based on the presence / absence, the number of special symbol hold (U1 or U2), the reach determination random number value, and the special symbol variation random value, the variation pattern of the special symbol is determined.

  Then, based on the determined special symbol variation pattern, the special symbol variation time is determined, and the special symbol variation pattern designation command for transmitting the special symbol information to the effect control board 120 is specified. An example of this variation pattern designation command is shown in FIG.

  Therefore, it can be said that the “special symbol variation pattern” defines at least the jackpot determination result and the special symbol variation time. In addition, since a reach is always performed when a big hit or a small hit, the reach determination random number value is not referred to when a big hit or a small win. The reach determination random number value and the special figure variation random value are set to 100 random numbers (0 to 99).

  Here, the special symbol variation pattern designation command is composed of “1 byte” of MODE data for identifying the command classification and “1 byte” of DATA data indicating the content (function) of the command. Yes.

  When the MODE data is “E6H”, a special symbol variation pattern designation command (of the first special symbol display device 20) corresponding to the winning of the game ball at the first start port 14 is shown. "E7H" indicates a special symbol variation pattern designation command corresponding to the winning of a game ball in the second start port 15 (second special symbol display device 21).

  Further, the special symbol variation pattern determination table shown in FIG. 10 is set so that the variation time of the special symbol is shortened when the jackpot determination result is lost and the game is in the short-time gaming state. For example, when the jackpot determination result is a loss and the number of held balls is “2”, if the game is in the short-time game state, the variation time is “3000 ms” with a probability of “95%” based on the reach determination random value. Pattern “9” (shortening variation) is determined. On the other hand, when in the non-time saving gaming state, a variation pattern in which the variation time exceeds “3000 ms” is determined.

  In this manner, the variation time is set to be short when the time-saving gaming state is entered.

  The table as described above is stored in the main ROM 110b of the main control board 110.

  Subsequently, the main RAM 110c of the main control board 110 functions as a data work area during the arithmetic processing of the main CPU 110a and has a plurality of storage areas.

  As an example of the storage area at this time, for example, in the main RAM 110c, the normal symbol hold number (G) storage area, the normal symbol hold storage area, the normal symbol data storage area, the first special symbol hold number (U1) storage area, Second special symbol holding number (U2) storage area, first special symbol random value storage area, second special symbol random value storage area, round game number (R) storage area, number of times released (K) storage area, first large Number of balls (C) storage area, game state storage area (high probability game flag storage area and time-short game flag storage area), high probability game number (X) counter of the winning opening 16 and the second grand prize opening 17 Various timer counters are provided, such as a short time (J) counter, a game state buffer, a stop symbol data storage area, a transmission data storage area for effects, a special symbol time counter, and a special game timer counter. That. Note that the above-described storage area is merely an example, and many other storage areas are provided.

  The game information output terminal board 30 is a board for outputting an external information signal generated in the main control board 110 to a hall computer or the like of the game shop. The game information output terminal board 30 is connected to the main control board 110 by wiring, and is provided with a connector for connecting external information to a hall computer or the like of a game store.

  The power supply board 170 is provided with a backup power supply composed of a capacitor, supplies a power supply voltage to the gaming machine 1 and monitors a power supply voltage supplied to the gaming machine 1, and when the power supply voltage becomes a predetermined value or less, An interruption detection signal is output to the main control board 110. More specifically, when the power interruption detection signal becomes high level, the main CPU 110a enters an operable state, and when the power interruption detection signal becomes low level, the main CPU 110a enters an operation stop state. The backup power source is not limited to a capacitor, and for example, a battery may be used, and a capacitor and a battery may be used in combination.

  The effect control board 120 mainly controls each effect such as during a game or standby.

  The effect control board 120 includes a sub CPU 120a, a sub ROM 120b, and a sub RAM 120c, and is connected to the main control board 110 so as to be communicable in one direction from the main control board 110 to the effect control board 120. .

  The sub CPU 120a reads out a program stored in the sub ROM 120b based on a command transmitted from the main control board 110 or an input signal from the effect button detection switch 35a, the cross key detection switch 36a, and the timer, and performs arithmetic processing. And corresponding data (such as an effect pattern designation command to be described later) is transmitted to the lamp control board 140 or the image control board 150 based on this processing.

  The sub RAM 120c functions as a data work area during the arithmetic processing of the sub CPU 120a.

  For example, when the sub CPU 120a in the effect control board 120 receives the fluctuation pattern designation command indicating the fluctuation pattern of the special symbol from the main control board 110, the contents of the received fluctuation pattern designation command are analyzed and the first liquid crystal display device 31 is analyzed. The voice output device 32, the effect drive device 33, the effect illumination device 34, and data for causing the second liquid crystal display device 37 to execute a predetermined effect (such as an effect pattern designation command to be described later) are specified. Then, the specified data (effect pattern designation command or the like) is transmitted to the image control board 150 or the lamp control board 140.

  FIG. 11 shows an example of a table used when an effect pattern designation command is specified based on the variation pattern designation command at this time.

  The sub ROM 120b of the effect control board 120 stores a program for effect control, data necessary for determining various games, and a table.

  For example, an effect pattern determination table for determining an effect pattern based on a variation pattern designation command received from the main control board 110, an effect symbol determination table for determining a combination of effect symbols 38 to be stopped and displayed, etc. are stored in the sub ROM 120b. It is remembered.

  In the production pattern determination table at this time, after the jackpot lottery is in the reach state, and the reach performance in the reach state suggests that the jackpot lottery result is “losing”, the revival and the jackpot lottery result is “ In addition to storing the effect pattern (revival jackpot effect pattern) for effecting “big hit”, the effect pattern for effecting switching the game state (game mode) is stored. Note that the above-described table is merely an example of characteristic tables among the tables in the present embodiment, and a number of other tables and programs (not shown) are provided for the progress of the game. ing.

  The effect control board 120 creates an effect pattern designation command using an effect pattern determination table as shown in FIG. 11 and sends it to the lamp control board 140 and the image control board 150.

  The sub RAM 120c of the effect control board 120 functions as a data work area when the sub CPU 120a performs arithmetic processing, and has a plurality of storage areas.

  The sub RAM 120c is provided with a game state storage area, an effect mode storage area, an effect pattern storage area, an effect symbol storage area, and the like. Note that the above-described storage area is merely an example, and many other storage areas are provided.

  FIG. 11 is a diagram showing a variation effect pattern determination table for determining the variation mode of the effect symbol 38 displayed on the first liquid crystal display device 31 and the second liquid crystal display device 37.

  The variation effect pattern designation command shown in FIG. 11 is information received from the main control board 110, and the effect random number 1 (0 to 99) is an effect generated by a random number generator (not shown). The sub CPU 120a determines a variation effect pattern (and an effect pattern designation command in the variation effect pattern) based on these pieces of information.

  In FIG. 11, even when the sub CPU 120a receives the variation pattern designation command of the same special symbol, the variation control pattern can be determined based on the random number value 1 for the effect. The number of special pattern variation pattern designation commands stored in the main control board 110 is reduced compared to the variation effect pattern stored in 120.

  As a result, the storage capacity of the main control board 110 can be reduced, and a variety of effects can be achieved.

  The “variation effect pattern” refers to the effect contents (first liquid crystal display device 31, sound output device 32, effect drive device 33, effect illumination device 34, second liquid crystal display device 37) performed during the change of the special symbol. ) In a specific production mode. For example, in the first liquid crystal display device 31 and the second liquid crystal display device 37, the display mode of the background, the display mode of the character, and the variation mode of the production symbol 38 are determined by this variation effect pattern.

  In addition, the “reach” in the present embodiment refers to a state in which a part of the combination of the effect symbols 38 that informs the transition to the special game is stopped and the other effect symbols 38 are performing the variable display. . For example, when a combination of three effect symbols 38 of “777” is set as a combination of the effect symbols 38 informing that a transition to a jackpot game is made, the two effect symbols 38 are stopped and displayed at “7”. The state in which the remaining effect symbols 38 are variably displayed is called “reach”.

  In this way, when the sub CPU 120a determines the variation effect pattern based on the variation effect pattern designation command and the effect random number 1, the sub CPU 120a identifies the effect pattern designation command corresponding to the variation effect pattern and determines the image. The information is transmitted to the liquid crystal control CPU 150a of the control board 150.

  Specifically, in the effect pattern designation command, “1 command” is composed of 2 bytes of data, and “1 byte” of MODE data for identifying the control command classification and the control command to be executed. It consists of “1 byte” of DATA data indicating the contents.

  In addition, as an effect pattern designation command corresponding to the change effect pattern shown in FIG. 11, “MODE” is set to “A1H” in the case of a change effect pattern based on the change pattern of the special symbol in the first special symbol display device 20. Furthermore, in the case of the variation effect pattern based on the variation pattern of the special symbol in the second special symbol display device 21, “MODE” is set as “B1H”, and “DATA” is set according to the identification number of the variation effect pattern. The

  Although illustration is omitted, in addition to the effect pattern specifying command corresponding to the variable effect pattern, the MODE setting value is changed, and “effect pattern specifying command corresponding to the demo effect pattern (MODE = 01H)”, "Effect pattern designation command corresponding to hit start effect pattern (MODE = 0H)", "Effect pattern designation command corresponding to jackpot effect pattern (MODE = 03H)", "Effect pattern designation command corresponding to hit end effect pattern ( MODE = 04H) ”and the like, and the sub CPU 120a transmits the various effect pattern designation commands to the image control board 150.

  Subsequently, the payout control board 130 shown in FIG. 4 performs payout control of the game ball.

  The payout control board 130 includes a one-chip microcomputer including a payout CPU, a payout ROM, and a payout RAM (not shown), and is connected to the main control board 110 so as to be capable of bidirectional communication.

  The payout CPU reads out the program stored in the payout ROM based on the input signals from the payout ball count detection switch 132, the door opening switch 133, and the timer for detecting whether or not the game ball has been paid out, and performs arithmetic processing. At the same time, based on the processing, the corresponding data is transmitted to the main control board 110.

  Further, a payout motor 131 of a payout device for paying out a predetermined number of game balls from the game ball storage unit is connected to the output side of the payout control board 130. The payout CPU reads out a predetermined program from the payout ROM based on the payout number designation command transmitted from the main control board 110, performs arithmetic processing, and controls the payout motor 131 of the payout device to give a predetermined game ball. Pay out.

  At this time, the payout RAM functions as a data work area at the time of calculation processing of the payout CPU.

  The lamp control board 140 controls the lighting of the effect lighting device 34 provided on the game board 2 and controls the driving of the motor for changing the light irradiation direction. Further, energization control is performed on a drive source such as a solenoid or a motor that operates the decoration device 33a. The lamp control board 140 is connected to the effect control board 120 and performs the above-described controls based on various commands transmitted from the effect control board 120.

  The image control board 150 is connected to the first liquid crystal display device 31, the audio output device 32, and the second liquid crystal display device 37, and the first liquid crystal display is based on various commands transmitted from the effect control board 120. Image display control in the device 31 and the second liquid crystal display device 37 and audio output control in the audio output device 32 are performed.

  The image control board 150 performs liquid crystal control CPU 150 a, liquid crystal control RAM 150 b, liquid crystal control ROM 150 c, CGROM 151, crystal oscillator 152, in order to perform image display control of effect images displayed on the first liquid crystal display device 31 and the second liquid crystal display device 37. A VRAM 153, an image control unit (VDP (Video Display Processor)) 2000 (hereinafter referred to as “VDP2000”), and a sound control circuit 3000 that performs control to output sound information from the sound output device 32 are provided.

  The liquid crystal control CPU 150a creates a display list, which will be described later, based on the “effect pattern designation command” received from the effect control board 120, and transmits this display list to the VDP 2000. Thus, the VDP 2000 is a video engine that can display an effect image using a plurality of frames (also referred to as “frame images”), and is stored in the CGROM 151 based on the display list received from the liquid crystal control CPU 150a. The effect image (frame image) is generated using the image data.

  The VDP 2000 instructs the first liquid crystal display device 31 and / or the second liquid crystal display device 37 to continuously display the generated effect image.

  Thereby, the first liquid crystal display device 31 and / or the second liquid crystal display device 37 displays an effect moving image in which frame images generated by the VDP 2000 are continuously displayed.

  The frame image generated at this time is image data that is an actual image generated based on the display image from the material image data stored in the CGROM 151.

  When liquid crystal control CPU 150a receives an effect pattern designation command from effect control board 120, it generates a display list based on the effect pattern designation command.

  At this time, in the VDP 2000, as described above, the display list is received from the liquid crystal control CPU 150a as the display instruction of the effect image, and the frame image based on the display list is used as the work area by using the image data read from the CGROM 151. Are generated and displayed on the liquid crystal display device.

  The liquid crystal control CPU 150 a further instructs the sound control circuit 3000 to output predetermined sound data to the sound output device 32 based on the effect pattern designation command received from the effect control board 120.

  The liquid crystal control RAM 150b is built in the liquid crystal control CPU 150a, functions as a data work area when the liquid crystal control CPU 150a performs arithmetic processing, and temporarily stores data read from the liquid crystal control ROM 150c.

  The liquid crystal control ROM 150c is configured by a mask ROM or the like, and includes a control processing program of the liquid crystal control CPU 150a, a display list generation program for generating a display list, an animation pattern for displaying an animation of an effect pattern, an animation The scene information, the specific effect information related to the specific effect, and the like are stored.

  This animation pattern is referred to when displaying the animation of the production pattern, and stores the combination of animation scene information included in the production pattern, the display order of each animation scene information, and the like. In the animation scene information, a wait frame (display time), target data (sprite identification number, transfer source address, etc.), parameters (sprite display position, transfer destination address, etc.), drawing method, and effect image are displayed. Information such as information specifying a display device is stored.

  An example of this animation information is shown in FIG. 13 and will be described below.

  The general-purpose board 39 is provided between the image control board 150 and the first liquid crystal display device 31 and the second liquid crystal display device 37, and converts the image data into a predetermined image format and outputs it when displaying the image data. have.

  The general-purpose board 39 has a bridge function for converting to an image format corresponding to the performance of the first liquid crystal display device 31 and the second liquid crystal display device 37 for displaying image data. For example, SXGA (1280 dots × 1080) Dot) 19-inch main liquid crystal connected as the first liquid crystal display device 31, and XGA (1024 dots × 768 dots) 17-inch main liquid crystal connected as the first liquid crystal display device 31. Absorb differences.

  Subsequently, the CGROM 151 is composed of a flash memory, an EEPROM, an EPROM, a mask ROM, and the like, and compresses image data (sprite, movie), etc. composed of a collection of pixel information in a predetermined range of pixels (for example, 32 pixels × 32 pixels). And remember. The pixel information is composed of color number information for designating a color number for each pixel and an α value indicating the transparency of the image.

  The CGROM 151 is read out in units of image data by the VDP 2000, and image processing is performed in units of image data of this frame.

  Further, the CGROM 151 stores palette data in which color number information for designating color numbers and display color information for actually displaying colors are associated with each other without being compressed.

  Note that the CGROM 151 may have a configuration in which only a part of the image data is compressed without being compressed. As a movie compression method, various known compression methods such as MPEG4 can be used.

  The crystal oscillator 152 outputs a pulse signal (V blank interrupt signal) to the VDP 2000 approximately every 16.6 milliseconds. The VDP 2000 divides this pulse signal to control the system clock. A synchronization signal or the like for synchronizing with the liquid crystal display device 31 or the second liquid crystal display device 37 is generated.

  The VRAM 153 is composed of an SRAM that can write or read image data at high speed. The VRAM 153 is configured by a memory map as shown in FIG.

  FIG. 12 is an example of a configuration diagram illustrating a configuration of a frame buffer used in the image control board 150 of the gaming machine according to the embodiment of the present invention.

  FIG. 12A shows a case where image data is displayed using either the first liquid crystal display device 31 or the second liquid crystal display device 37, and in particular, only the first liquid crystal display device 31 has the image control board 150. In other words, the second liquid crystal is not a configuration in which the first liquid crystal display device 31 and the second liquid crystal display device 37 are connected as shown in FIG. It is a memory map in the structure when not having the display device 37.

  The memory map shown in FIG. 12A includes an image data development area 153b consisting of arbitrary areas, a display list storage area 153a, a main liquid crystal first frame buffer area 153c, a main liquid crystal second frame buffer area 153d, and other areas. It is configured.

  The image data development area 153b is an area for storing image data expanded by an expansion circuit (described later) included in the VDP 2000. The display list storage area 153a temporarily stores the display list output from the liquid crystal control CPU 150a. This is the area to be stored in

  The main liquid crystal first frame buffer area 153c and the main liquid crystal second frame buffer area 153d display effect images to be displayed on the first liquid crystal display device 31 based on the display list stored in the display list storage area 153a. This is a work area for drawing.

  Incidentally, pallet data etc. are memorize | stored in other area | regions, for example.

  The two frame buffers, the first liquid crystal frame buffer area 153c and the main liquid crystal second frame buffer area 153d, are divided into a "drawing frame buffer" and a "display frame buffer" each time drawing is started. It switches alternately. That is, when one frame buffer functions as a drawing frame buffer, the other frame buffer functions as a display frame buffer.

  FIG. 12B shows a case where the image data received from the image control board 150 is displayed on both the first liquid crystal display device 31 and the second liquid crystal display device 37, that is, as shown in FIG. As shown, the memory map in the configuration in which the first liquid crystal display device 31 and the second liquid crystal display device 37 are connected.

  12B, similarly to the memory map shown in FIG. 12A, the image data development area 153b, the display list storage area 153a, the main liquid crystal first frame buffer area 153c, and the main liquid crystal A second frame buffer area 153d and other areas are provided, and a sub-liquid crystal first frame buffer 153e and a sub-liquid crystal second frame buffer 153f are further provided.

  The image data development area 153b, the display list storage area 153a, the main liquid crystal first frame buffer area 153c, the main liquid crystal second frame buffer area 153d, and the other areas are the same as described above. The frame buffer 153e and the second sub-liquid crystal frame buffer 153f are work areas for drawing effect images to be displayed on the second liquid crystal display device 37 based on the display list stored in the display list storage area 153a.

  The two frame buffers, the first sub-liquid crystal frame buffer 153e and the sub-liquid crystal second frame buffer 153f, alternate between a “drawing frame buffer” and a “display frame buffer” every time drawing is started. It will be switched. That is, when one frame buffer functions as a drawing frame buffer, the other frame buffer functions as a display frame buffer.

  In addition to the above, the first liquid crystal display device 31 as shown in FIG. 12B may be configured without the second liquid crystal display device 37, that is, with only the first liquid crystal display device 31. It is also possible to use a memory map having a frame buffer of the second liquid crystal display device 37.

  In this case, the frame buffers of the sub-liquid crystal first frame buffer 153e and the sub-liquid crystal second frame buffer 153f are not used as work areas.

  Subsequently, the VDP 2000 is a so-called image processor. Based on an instruction from the liquid crystal control CPU 150a, for the first liquid crystal display device 31, a main liquid crystal first frame buffer area 153c and a main liquid crystal second frame buffer area 153d For the second liquid crystal display device 37, the image data is read from the “display frame buffer” in the frame buffer of either the sub-liquid crystal first frame buffer 153e or the sub-liquid crystal second frame buffer 153f.

  Based on the read image data, a video signal (LVDS signal, RGB signal, etc.) is generated and output to the first liquid crystal display device 31 and / or the second liquid crystal display device 37 for display.

  The VDP 2000 includes a control register (not shown), a CG bus I / F, a CPU I / F, a clock generation circuit, an expansion circuit, a drawing circuit, a display circuit, and a memory controller, which are connected by a bus.

  The control register is a register for the VDP 2000 to control drawing and display, and drawing control and display control are performed by writing and reading data to and from the control register. The liquid crystal control CPU 150a can write and read data to and from the control register via the CPU I / F.

  This control register is a "system control register" that performs basic settings necessary for the operation of the VDP2000, a "data transfer register" that performs settings necessary for data transfer, and a setting for controlling drawing "Drawing register" for performing the settings, "Bus interface register" for performing settings necessary for bus access, "Decompression register" for performing settings necessary for decompressing compressed images, and settings for controlling display There are six types of registers, “display registers”.

  The CG bus I / F is an interface circuit for communication with the CGROM 151, and image data from the CGROM 151 is input to the VDP 2000 via the CG bus I / F.

  The CPU I / F is an interface circuit for communication with the liquid crystal control CPU 150a. The liquid crystal control CPU 150a outputs a display list to the VDP 2000, accesses a control register, and accesses the VDP 2000 via the CPU I / F. Various interrupt signals from are input to the liquid crystal control CPU 150a.

  The data transfer circuit performs data transfer between various devices. Specifically, data transfer between the liquid crystal control CPU 150a and the VRAM 153, data transfer between the CGROM 151 and the VRAM 153, and data transfer between various storage areas (including the frame buffer) of the VRAM 153 are performed.

  The clock generation circuit receives a pulse signal (V blank interrupt signal) from the crystal oscillator 152 and generates a system clock that determines the operation processing speed of the VDP2000. Also, a synchronization signal generation clock is generated, and the synchronization signal is output to the first liquid crystal display device 31 via the display circuit.

  The decompression circuit is a circuit for decompressing the image data compressed in the CGROM 151, and stores the decompressed image data in the image data development area 153b.

  The drawing circuit is a circuit that performs sequence control based on a display list composed of drawing control commands.

  The display circuit includes a main display liquid crystal first frame buffer region 153c, a main liquid crystal second frame buffer region 153d, a sub liquid crystal first frame buffer 153e, and a sub liquid crystal second frame buffer 153f in the VRAM 153. From the image data (digital signal) stored in the frame buffer functioning as a “frame buffer”, a video signal indicating the color data of the image is generated as a video signal.

  The display circuit is a circuit that outputs the generated video signal to the first liquid crystal display device 31 and the second liquid crystal display device 37. Further, the display circuit also outputs a synchronizing signal (vertical synchronizing signal, horizontal synchronizing signal, etc.) for synchronizing with the first liquid crystal display device 31, and synchronizing signal (for synchronizing with the second liquid crystal display device 37). Vertical sync signals, horizontal sync signals, etc.) are also output.

  When there is an instruction to switch the frame buffer from the liquid crystal control CPU 150a, the memory controller performs control to switch roles between the “drawing frame buffer” and the “display frame buffer”.

  The sound control circuit 3000 is provided with an audio ROM (not shown) in which a large number of audio data is stored. The sound control circuit 3000 is based on an audio output instruction command transmitted from the effect control board 120. While reading a predetermined program, the audio output control in the audio output device 32 is performed.

  FIG. 13 is a diagram showing animation information used on the image control board 150 of the gaming machine according to the embodiment of the present invention.

  The animation pattern shown in FIG. 13 (a) includes the timing of displaying the effect image in addition to the object that is the configuration information constituting the effect image displayed on the first liquid crystal display device 31 and the second liquid crystal display device 37. This is information specifying a scene as a scene, and is image forming information for forming an effect image to be displayed at the time of effect.

  A group (hereinafter also referred to as “animation group”) is formed by bundling one or a plurality of the animation patterns. For example, in FIG. 13A, a background group for displaying a background animation, a notice A notice group A for displaying the animation of the character used for A, a notice group B for displaying the animation of the character used for notice B, a reach group for displaying the animation of the reach character, and an animation of the big hit effect are displayed. The effect symbol group for displaying the animation of the big hit effect group for the effect symbol 38 is shown.

  Of course, these are merely examples of groups, and many other groups are provided.

  This animation group is stored in the liquid crystal control ROM 150c.

  When the liquid crystal control CPU 150a receives the effect pattern designation command from the sub CPU 120a in the effect control board 120, whether or not the original movie data and the reproduction information (also referred to as “reproduction position information”) are associated with the effect pattern designation command. Judging.

  This original movie data indicates moving image data stored in the CGROM 151, and is data for displaying a plurality of frame images in succession. The reproduction information is information for designating a reproduction position in the original movie data, and includes a reproduction start position for reproduction (simply referred to as “first designated position”) and a reproduction end position for termination of reproduction (simply referred to as “first”). At least one combination is designated.

At this time, the first designated position and the second designated position can be designated by a frame image ID (frame image ID) that identifies the original movie data, and depending on the reproduction time when the original movie data is reproduced and displayed from the beginning. It can be specified.

  The first designated position and the second designated position designate a frame image whose reproduction time that is reproduced when the original movie data is reproduced as a first designated position, and designate a frame image whose reproduction time is late as a second designation. In addition to being able to be designated as a position, a frame image with a slow reproduction time when the original movie data is reproduced can be designated as a first designated position, and a frame image with a fast reproduction time is designated as a second. It can also be specified as a position.

  As in the latter case, when the first designated position and the second designated position are designated, when the first designated position and the second designated position are reproduced by the processing described later, the first designated position and the second designated position are changed as in the former. Compared to the designated case, the rewind display will be performed.

  When the liquid crystal control CPU 150a determines that the original movie data and the reproduction information are associated with the effect pattern designation command, the liquid crystal control CPU 150a creates a display list as shown in FIG. 14C and transmits the display list to the VDP 2000. .

  The liquid crystal control ROM 150c stores a table (not shown) in which at least one original movie data and reproduction information are associated with a specific effect pattern specifying command, and the effect pattern specification received from the effect control board 120 is stored. When a command is specified in the table, a display list is created using the original movie data and reproduction information stored in association with the effect pattern specifying command.

  A plurality of original movie data and reproduction information may be associated with the display list created at this time. Details will be described later with reference to FIG.

  On the other hand, if the liquid crystal control CPU 150a does not determine that the original movie data and the reproduction information are associated with the effect pattern designation command, the display list is created using animation information as shown in FIG. .

  At this time, the liquid crystal control CPU 150a determines one or a plurality of animation groups to be executed based on the received effect pattern designation command, and determines an animation pattern from each animation group.

  13 (b) to 13 (d) and 13 (e), when the effect pattern designation command “A1H07H” is received among the effect pattern designation commands designated in the effect pattern determination table shown in FIG. An example of the determined animation pattern is shown in FIG.

  This effect pattern designation command (A1H07H) is a command for instructing to perform a normal variation effect with a variation effect pattern of “variation effect pattern 7” as shown in the variation pattern designation command table of FIG. It is an animation group to which the constituent elements used when performing the normal variation effect belong, and specifies at least one of the animation groups separated for each role used for the variation effect.

  That is, the liquid crystal control ROM 150c stores an animation group correspondence table (not shown) in which an effect pattern designation command and an animation group used for the effect pattern of the effect pattern designation command are associated with each other. The animation group to be used for the production pattern designation command is determined using this animation group correspondence table.

  For example, when receiving the effect pattern designation command (A1H07H) corresponding to the variable effect pattern “7”, the liquid crystal control CPU 150a determines four groups of “background group, notice A group, notice B group, effect symbol group”. The animation pattern can be determined from each of these anime groups.

  As an example, “animation pattern 1” is determined from the background group, “anime pattern 11” is determined from the notice A group, “anime pattern 21” is determined from the notice B group, and “anime pattern 501” is determined from the directing design group. To decide.

  As shown in FIGS. 13 (b) to 13 (d) and 13 (e), the animation pattern includes a combination of animation scene information, a display order of each animation scene information, information specifying a display device to be displayed, and the like. Is remembered.

  For example, in the animation pattern of the effect symbol group shown in FIG. 13E, “sub liquid crystal (second liquid crystal display device 37)” is designated in the information designating the display device to be displayed. The scene 501 is executed, the animation scene 511 is executed second after the animation scene 501, and the effect image of the animation pattern is displayed on the sub liquid crystal (second liquid crystal display device 37).

  The liquid crystal control RAM 150 b has a “scene switching counter” that counts and updates every frame, and this “scene switching counter” counts 540 while the first animation scene 501 is being executed. As a result, the animation scene is switched to the second animation scene 511.

  When “60” (for 60 frames) is counted by the “scene switching counter” while the second animation scene 511 is being executed, the animation scene of the animation pattern of the effect symbol group ends.

  Note that “one frame” is the update timing of the display device (update timing of the vertical synchronization signal). For example, when the first liquid crystal display device 31 displays 60 frames per second, “1/60”. One frame is updated every second (about 16.6 ms).

  In the above example, one frame is updated every "1/60 seconds (about 16.6 ms)". However, the present invention is not limited to this, and "1/30 seconds (about 33. The configuration may be such that one frame is updated every 3 ms). In this case, the display device displays 30 frames per second.

  Each animation scene stores animation scene information. As animation information, a weight frame (display time) updated for each frame, target data (sprite identification number, transfer source address, etc.), parameters, and the like. (Sprite display position, transfer destination address, etc.), a drawing method, information for designating a display device for displaying the effect image, and the like are stored.

  For example, in the animation scene shown in FIG. 13 (e), first, the first symbol, the second symbol, the third symbol, and the fourth symbol are given coordinates (the first symbol is coordinates (x30, y30), the second symbol. Is displayed at coordinates (x40, y40), the third symbol at coordinates (x50, y50), and the fourth symbol at coordinates (x60, y60) for 20 frames (approximately 0.33 seconds).

  Then, the first symbol, the second symbol, the third symbol, and the fourth symbol are different coordinates (the first symbol is coordinates (x31, y31), the second symbol is coordinates (x41, y41), the third symbol is coordinates ( x51, y51), the 4th symbol continues to be displayed for 15 frames (about 0.25 seconds) at coordinates (x61, y61)).

  Similarly, when the first symbol, the second symbol, the third symbol, and the fourth symbol continue to be displayed at the designated coordinates for the predetermined frame, the first symbol, the second symbol, the third symbol, The animation is such that the symbol and the fourth symbol are moved and displayed.

  In addition, in each of the “background group, notice A group, notice B group” animation patterns shown in FIGS. 13B to 13D, “main liquid crystal (first liquid crystal display) in the information designating the display device to be displayed. Device 31) "is designated, animation scene 1 is executed for" 600 "frames in the background group as shown in FIG. 13 (b), and animation-scene 0 is shown in FIG. 13 (c) in the notice A group. After executing “120” frame, the animation scene 11 is executed for “180” frame. In the notice B group, as shown in FIG. 13D, after the animation scene 0 is executed for “180” frame, the animation scene 21 is “ The 240 "frame is executed, and the effect image of the animation pattern is displayed on the main liquid crystal (first liquid crystal display device 31).

  As described above, as shown in FIG. 13B to FIG. 13D, “animation pattern 1 of the background group, animation pattern 11 from the notice A group, animation pattern 21 from the notice B group, and Are determined and the animations of these animation patterns are executed in parallel in time series, whereby an effect image based on the animation pattern is displayed on the main liquid crystal (first liquid crystal display device 31). As shown in FIG. 13 (e), the animation pattern “animation pattern 501 from the production pattern group” is determined, and the animation pattern is executed to execute the animation pattern on the sub liquid crystal (second liquid crystal display device 37). An effect image based on is displayed.

  As a result, images of BG1 (mountains) and BG2 (clouds) continue to be displayed in the display area of the first liquid crystal display device 31 from the start to the end of the animation pattern, and 2 seconds from the start of the animation pattern. An image that performs animation for displaying the notice of character A after (120 frames) is displayed for 3 seconds (180 frames), and 4 images that perform animation for displaying the notice of character B after 3 seconds (180 frames) from the start of the animation pattern. Seconds (240 frames) are displayed.

  These images are displayed in an overlapping manner in the display area of the first liquid crystal display device 31, and the first drawn image is overwritten by an image drawn later and cannot be visually recognized as an image. Become.

  Furthermore, in the display area of the second liquid crystal display device 37, an image for performing the animation of the normal variation display of the effect symbol is performed for 9 seconds (540 frames), and then temporarily stopped for 1 second (60 frames) (stop time). The image that performs the animation is displayed. In addition, although the example which displays only an effect design is shown on the 2nd liquid crystal display device 37, it does not limit to this, For example, the animation pattern 1 which consists of the background group displayed in the 1st liquid crystal display device 31, and an effect The animation pattern 501 may be displayed in parallel in time series from the symbol group.

  FIG. 14 is an example of a display list composed of a group of drawing control commands, and shows an example of a display list for each display device to be displayed.

  FIG. 14A is an example of a first display list that is image forming information for forming an effect image to be displayed on the first liquid crystal display device 31. FIG. 14B is an example of a second display list that is image forming information for forming an effect image to be displayed on the second liquid crystal display device 37. Further, FIG. 14C is an example of a display list created when the liquid crystal control CPU 150a determines that the original movie data and the reproduction information are associated with the effect pattern designation command.

  When the liquid crystal control CPU 150a determines that the original movie data and the reproduction information are not associated with the effect pattern designation command received from the effect control board 120, the animation information as shown in FIG. 13 described above is displayed. 14A and 14B show a display list that is generated by determining an animation pattern based on the original.

  The display lists shown in FIGS. 14A and 14B indicate that a display list is generated for each unit frame according to the number of display devices.

  The liquid crystal control CPU 150a outputs each of the generated display lists to the VDP 2000.

  Here, the display list generation method is such that the liquid crystal control CPU 150a changes the contents of the animation scene at the current number of frames based on the “frame counter” indicating the current frame and the determined animation pattern (animation scene). The display list for the current number of frames is generated by generating the drawing control command according to the priority (drawing order) of each animation group.

  Below, the example of the display list which comprises the effect image displayed in the 1st liquid crystal display device 31 is shown.

  In FIG. 14A, as the priority order of the animation group shown in FIG. 13A, the background group is associated with the lowest “priority 9” data, and the notice A group has “priority order 8”. ”Data,“ priority 7 ”data is associated with the notice B group, and… (omitted)…. The highest priority data is associated with the jackpot presentation group It is assumed that

  Further, in FIG. 14B, as the priority order of the animation group shown in FIG. 13A, data of “priority order 2” having a low priority order is associated with the background group, It is assumed that “priority 1” data having a high priority is associated. In the example shown in FIG. 14B, in the above case, the animation pattern 1 consisting of the background group and the animation pattern 501 from the effect design group are displayed on the second liquid crystal display device 37 in chronological order in parallel. An example of a display list is shown. Of course, when only the animation pattern 1 composed of the background group is displayed, the display list designating only the animation scene 501 of the effect design group, that is, the “background group” in the animation group column of FIG. The display list does not include the specified record.

  In FIG. 14 (a), as shown in FIGS. 13 (b) to 13 (d), the background group anime pattern 1, the notice A group from the anime pattern 11, and the notice B group It is assumed that a plurality of anime patterns with the anime pattern 21 have been determined. In FIG. 14B, as shown in FIG. 13E above, the anime pattern 1 of the background group and the animation pattern from the effect design group are displayed. Assume that a plurality of animation patterns 501 are determined.

  Next, as a display list corresponding to the effect image displayed on the first liquid crystal display device 31, the animation in the current frame counter (current number of frames) is selected from the animation pattern 1 of the lowest priority animation group (background group). Drawing control commands are generated sequentially according to the contents of the scene, and when drawing control commands are generated up to the highest priority anime group (big hit effect group) among the determined anime groups, drawing ends at the end. A display list as shown in FIG. 14A is completed by generating a command.

  Next, as a display list corresponding to the effect image displayed on the second liquid crystal display device 37, the animation pattern 1 of the animation group (background group) with the lower priority and the animation scene in the current frame counter (current number of frames). When the drawing control command for the animation group with higher priority (direction design group) is generated among the determined anime groups, the drawing end command is finally sent. The display list as shown in FIG. 14B is completed by generating.

  The display lists as shown in FIGS. 14A and 14B are generated with reference to necessary data by the liquid crystal control CPU 150a.

  In this way, the liquid crystal control CPU 150a outputs to the VDP 2000 the display lists (first display list and second display list) for each display device in which the drawing control command group is grouped for each predetermined frame (one frame). The drawing circuit constituting the VDP 2000 performs a drawing process for drawing the effect image for each display list, and displays the effect image subjected to the drawing process on the corresponding display device (the first liquid crystal display device 31 or the second liquid crystal display device 37). To do.

  On the other hand, the display list shown in FIG. 14 (c) includes the original movie data and the reproduction information designated in response to the production pattern designation command, and an effect image (reproduction to be described later) displayed based on these information. This is information that designates the variable display time of the effect image) for each combination of the original movie data and the reproduction information. This indicates original movie data and reproduction information stored in association with the effect pattern designation command received from the effect control board 120 in the liquid crystal control CPU 150a.

  The fluctuation display time at this time is time information designated based on the fluctuation time determined by the fluctuation pattern designation command received by the effect control board 120 from the main control board 110, and the total of the fluctuation display time is this fluctuation. Time information is set for each combination of original movie data and reproduction information so as to be time.

  Then, the VDP 2000 that has received the display list as shown in FIG. 14C reads the original movie data and reproduction information specified in the display list from the CGROM 151.

  In this VDP2000, “time adjustment control” is performed for adjusting the reproduction time of the original movie data using information of “first designated position” and “second designated position” designated in the reproduction information for the read original movie data. Process.

  In this time adjustment control process, using the “first designated position” and the “second designated position” designated in the reproduction information, an effect image from the first designated position to the second designated position is generated to reproduce the reproduction time. The time is adjusted. In this time adjustment processing, processing is performed using information of a designated image frame (designated effect image) as shown in FIG.

  The designated image frame information shown in FIG. 26 indicates table information in which a designated image frame is associated with a combination of original movie data and reproduction information.

  Even when the time adjustment control process is performed, this designated image frame information must be included in the effect image when displaying the effect image (playback frame data described later) reproduced using the original movie data. This is information specified as a frame image requiring time and information specified by time information.

  Of course, the frame ID for identifying the frame image may be designated.

  In the example shown in FIG. 26, two “original movie data 1” and “original movie data 2” are shown as the original movie data, and reproduction information for each of these original movie data is shown.

  That is, “reproduction information 1” and “reproduction information 2” are associated with “original movie data 1”, and “reproduction information 1” and “reproduction information 3” are associated with “original movie data 2”. It is associated. Therefore, in FIG. 26, designated image frames are designated for the four combinations.

  For “original movie data 1” and “playback information 1”, “frame images designated by time information of 0 to 3 seconds and 120 to 125 seconds” are designated as designated image frames. The image frame is always displayed in the effect image (reproduction frame data) to be reproduced. For “original movie data 1” and “playback information 2”, “frame images designated by time information of 3 to 8 seconds and 85 to 90 seconds” are designated as designated image frames. This designated image frame is always displayed in the effect image (reproduction frame data) to be reproduced. Furthermore, for “original movie data 2” and “playback information 1”, “frame images designated by time information of 0 to 3 seconds and 120 to 125 seconds” are designated as designated image frames. This designated image frame is always displayed in the effect image (reproduction frame data) to be reproduced. For “original movie data 2” and “playback information 3”, “frame images designated by time information of 0 to 5 seconds and 80 to 90 seconds” are designated as designated image frames. This designated image frame is always displayed in the effect image (reproduction frame data) to be reproduced.

  Since the image selected as the designated image frame is “playback movie data” to be described later, the playback movie data created using the original movie data and the playback information is shown in the remarks, and the playback movie data The variable display time is also shown in the remarks.

  Subsequently, the VDP 2000 is adjusted so that the designated image frame is always displayed by the time adjustment control process, and arranges other frame images other than the designated image frame, that is, thins out the frame image. As a result, an effect image to be displayed designated based on the display list is generated.

  The detailed flow of this time adjustment control process is shown in FIG.

  When this time adjustment control process is performed, the VDP 2000 performs a process of displaying the image data after the time adjustment control process on the first liquid crystal display device 31. In the display list as shown in FIG. 14C, information indicating whether to display the image data after the time adjustment control process on either the first liquid crystal display device 31 or the second liquid crystal display device 37 is set. In the VDP 2000, the created image data is displayed on the first liquid crystal display device 31 or the second liquid crystal display device 37 based on this information.

  Subsequently, various processes performed in the gaming machine according to the embodiment of the present invention will be described with reference to all 10 diagrams from FIG. 15 to FIG. 24.

  FIG. 15 is an example of a flowchart showing a detailed flow of the main process performed on the main control board 110 of the gaming machine in the embodiment of the present invention.

  When power is supplied from the power supply board 170, a system reset occurs in the main CPU 110a, and the main CPU 110a performs the following main processing.

  First, the main CPU 110a performs initialization processing (S1501). In this initialization process, the main CPU 110a reads a startup program from the main ROM 110b in response to power-on, and performs a process of initializing flags and the like stored in the main RAM 110c.

  Subsequently, the main CPU 110a performs an effect random number update process for updating the reach determination random number value and the special figure variation random value for determining the variation mode (variation time) of the special symbol (S1502).

  Then, the main CPU 110a updates the special symbol determination initial random number value, the big hit symbol initial random value, the small hit symbol initial random number value, and the normal symbol determination initial random value (S1503).

  When such a process is performed, it is determined whether or not a power-off process for shutting off the power is performed (S1504), and until the power-off process is performed (NO in S1504), an interrupt process is performed to produce an effect. The random number value update process (S1502) and subsequent steps are repeated. If the power interruption process is performed (YES in S1504), the process is terminated.

  FIG. 16 is an example of a flowchart showing a detailed flow of the timer interrupt process performed on the main control board 110 of the gaming machine according to the embodiment of the present invention.

  A clock pulse is generated every predetermined period (4 milliseconds) by the reset clock pulse generation circuit provided on the main control board 110, thereby executing a timer interrupt process described below.

  First, the main CPU 110a saves information stored in the register of the main CPU 110a to the stack area (S1601).

  The main CPU 110a has various timers such as a special symbol time counter update process, a special game timer counter update process such as a special electric accessory release time, a normal symbol time counter update process, and a general electric release time counter update process. A time control process for updating the counter is performed. Specifically, a process of subtracting 1 from the special symbol time counter, the special game timer counter, the normal symbol time counter, and the general electricity open time counter is performed (S1602).

  The main CPU 110a performs random number update processing for the special symbol determination random number value, the big hit symbol random number value, the small hit symbol random number value, and the normal symbol determination random number value (S1603).

  Specifically, each random number value and random number counter are incremented (unit number addition) and updated. When the added random number counter exceeds the maximum value of the random number range (when the random number counter makes one round), the random number counter is returned to “0 (zero)” and the initial random number “0 (zero) at that time” ”To update each random value.

  Subsequently, as in S1503, the main CPU 110a updates the initial random number value for updating the initial random number value for special symbol determination, the initial random number value for big hit symbol, the initial random number value for small hit symbol, and the initial random number value for normal symbol determination. Processing is performed (S1604).

  The main CPU 110a performs input control processing (S1605).

  In this input control process, the main CPU 110a includes the general winning opening detecting switch 12a, the first large winning opening detecting switch 16a, the second large winning opening detecting switch 17a, the first starting opening detecting switch 14a, and the second starting opening detecting switch 15a. Then, it is determined whether or not there is an input to each switch of the gate detection switch 13a.

  Specifically, various detection signals from the general winning opening detecting switch 12a, the first big winning opening detecting switch 16a, the second large winning opening detecting switch 17a, the first starting opening detecting switch 14a, and the second starting opening detecting switch 15a. Is inputted, predetermined data is added to the prize ball counter used for the prize ball provided for each winning opening and updated.

  Furthermore, when a detection signal is input from the first start port detection switch 14a, if the data set in the first special symbol hold number (U1) storage area is less than 4, the first special symbol hold number ( U1) Add 1 to the storage area to obtain special symbol determination random number value, jackpot symbol random number value, small hit symbol random number value, reach determination random value, and special symbol variation random value The random number value is stored in a predetermined storage unit (0th storage unit to 4th storage unit) in the first special symbol random value storage area.

  Similarly, when a detection signal is input from the second start port detection switch 15a, if the data set in the second special symbol hold number (U2) storage area is less than 4, the second special symbol hold number (U2) 1 is added to the storage area, and a special symbol determination random number value, a big hit symbol random number value, a small hit symbol random number value, a reach determination random number value, and a special symbol variation random value are acquired. Various random numbers are stored in a predetermined storage unit (0th storage unit to 4th storage unit) in the second special symbol random number value storage area.

  When a detection signal is input from the gate detection switch 13a, if the data set in the normal symbol hold number (G) storage area is less than 4, the normal symbol hold number (G) storage area is set to 1. It adds, acquires the random number value for normal symbol determination, and memorize | stores the acquired random number value for normal symbol determination in the predetermined memory | storage part (0th memory | storage part-4th memory | storage part) in a normal symbol holding | maintenance storage area.

  Further, when a detection signal is input from the first grand prize opening detection switch 16a or the second big prize opening detection switch 17a, the number of game balls won in the first big prize opening 16 or the second big prize opening 17 is counted. 1 is added to the number of entries (C) storage area for the big winning opening to update.

  Next, the main CPU 110a performs special figure special electric power control processing for controlling the jackpot lottery, the special electric accessory, and the gaming state (S1606). Subsequently, the main CPU 110a performs a general-purpose normal power control process for controlling the normal symbol lottery and the normal electric accessory (S1607).

  Specifically, it is first determined whether or not 1 or more data is set in the normal symbol hold count (G) storage area, and 1 or more data must be set in the normal symbol hold count (G) storage area. If this is the case, the current ordinary power transmission control process is terminated.

  If 1 or more data is set in the normal symbol holding number (G) storage area, after subtracting 1 from the value stored in the normal symbol holding number (G) storage area, the data is in the normal symbol holding storage area. The normal symbol determination random numbers stored in the first storage unit to the fourth storage unit are shifted to the previous storage unit. At this time, the normal symbol determination random value already written in the 0th storage unit is overwritten and erased.

  Then, a process of determining whether or not the normal symbol determination random number value stored in the 0th storage unit of the normal symbol hold storage area is a random value corresponding to “win” is performed. Thereafter, the normal symbol display device 22 displays the fluctuation of the normal symbol. When the fluctuation time of the normal symbol elapses, the normal symbol corresponding to the result of the normal symbol lottery is stopped and displayed. If the random number for normal symbol determination referred to is “winning”, the start opening / closing solenoid 15c is driven to control the second start opening 15 to the second mode for a predetermined opening time.

  Here, in the non-short-time gaming state, the variation time of the normal symbol is set to 29 seconds, and if it is “winning”, the second start port 15 is controlled to the second mode for 0.2 seconds. On the other hand, in the short-time gaming state, the normal symbol variation time is set to 0.2 seconds, and if it is “winning”, the second start port 15 is controlled to the second mode for 3.5 seconds. .

  Then, the main CPU 110a performs a payout control process (S1608).

  In this payout control process, the main CPU 110a refers to the respective prize ball counters, generates payout number designation commands corresponding to various winning ports, and transmits the generated payout number designation commands to the payout control board 130.

  The main CPU 110a includes external information data, start opening / closing solenoid data, first big prize opening / closing solenoid data, second big prize opening / closing solenoid data, special symbol display device data, normal symbol display device data, and memory number designation command data. A creation process is performed (S1609).

  The main CPU 110a performs output control processing. In this process, the port output process is performed to output the signals of the external information data, the start opening / closing solenoid data, the first big prize opening / closing solenoid data, and the second big prize opening / closing solenoid data created in S1609 (S1610).

  Further, the special symbol display device data and the normal symbol display device data created in S1609 are used to turn on the LEDs of the first special symbol display device 20, the second special symbol display device 21 and the normal symbol display device 22. Display device output processing is performed.

  Further, command transmission processing for transmitting the command set in the effect transmission data storage area of the main RAM 110c to the effect control board 120 is also performed.

  The main CPU 110a restores the information saved in S1601 to the register of the main CPU 110a (S1611).

  FIG. 17 is an example of a flowchart showing a detailed flow of the special figure special power control process performed on the main control board 110 of the gaming machine in the embodiment of the present invention.

  First, the value of the special figure special processing data is loaded (S1701), and the branch address is referenced from the loaded special figure special processing data (S1702).

  At this time, if the special symbol special electricity processing data is “0 (zero)”, the special symbol memory determination processing is performed (S1703). If the special symbol special electricity processing data is “1”, the special symbol variation processing is performed. (S1704), and if the special figure special electricity processing data is "2", special symbol stop processing is carried out (S1705).

  If the special figure special power processing data is “3”, the big hit game processing is performed (S1706), and if the special figure special electric processing data is “4”, the big hit game end processing is performed (S1707). If the process data is “5”, a small hit game process is performed (S1708).

  This “special drawing special electricity processing data” is set as necessary in each subroutine of the special figure special electricity control processing, so that the subroutine necessary for the game is appropriately processed.

  As the special symbol memory determination process at this time, the main CPU 110a performs a jackpot determination process, a special symbol determination process for determining a special symbol to be stopped and displayed, a variation time determination process for determining a variation time of the special symbol, and the like. The detailed flow of this special symbol memory determination process will be described with reference to FIG.

  FIG. 18 is an example of a flowchart showing a detailed flow of the special symbol memory determination process performed on the main control board 110 of the gaming machine in the embodiment of the present invention.

  First, the main CPU 110a determines whether or not one or more data is set in the first special symbol hold count (U1) storage area or the second special symbol hold count (U2) storage area (S1801).

  If one or more data is not set in any storage area of the first special symbol hold number (U1) storage area or the second special symbol hold number (U2) storage area (NO in S1801), the special figure is stored. The special symbol variation process of this time is terminated while the special electric processing data is kept at “0 (zero)”.

  On the other hand, if one or more data is set in the first special symbol hold count (U1) storage area or the second special symbol hold count (U2) storage area (YES in S1801), the main CPU 110a performs the jackpot determination process. This is performed (S1802).

  Specifically, when one or more data is set in the second special symbol hold count (U2) storage area, 1 is calculated from the value stored in the second special symbol hold count (U2) storage area. After the subtraction, the various random numbers stored in the first to fourth storage units in the second special symbol random number storage area are shifted to the previous storage unit. At this time, various random values already written in the 0th storage unit are overwritten and deleted. Whether the special symbol determination random number value stored in the 0th storage unit of the second special symbol random value storage area is a random value corresponding to “big hit” or a random value corresponding to “small hit” Judgment is made.

  In addition, when one or more data is not set in the second special symbol hold number (U2) storage area and one or more data is set in the first special symbol hold number (U1) storage area, Various random numbers stored in the first to fourth storage units in the first special symbol random number storage area after subtracting 1 from the value stored in the first special symbol hold number (U1) storage area Is shifted to the previous storage unit. Also at this time, various random numbers already written in the 0th storage unit are overwritten and deleted. Whether the special symbol determination random number value stored in the 0th storage unit of the first special symbol random value storage area is a random value corresponding to “big hit” or a random value corresponding to “small hit” Judgment is made.

  In the present embodiment, the random number value stored in the second special symbol random value storage area is shifted (digested) with priority over the first special symbol random value storage area.

  Without being limited thereto, the first special symbol storage area or the second special symbol storage area may be shifted in the order of winning in the start opening, or the first special symbol storage area may be shifted to the second special symbol storage area. The shift may be performed with priority over.

  Next, the main CPU 110a performs a special symbol determination process for determining the type of special symbol to be stopped (S1803).

  In this special symbol determination process, if it is determined as “big hit” in the jackpot determination process (S1802), the jackpot symbol random number value stored in the 0th storage unit of the first special symbol random number value storage area is set. The jackpot symbol is determined based on this.

  Also, in the big hit determination process (S1802), if it is determined as “small hit”, the small hit symbol is stored based on the small bonus symbol random number stored in the 0th storage unit of the first special symbol random value storage area. The winning symbol is determined.

  Further, in the big hit determination process (S1802), when it is determined “lost”, a lost symbol is determined.

  Stop symbol data corresponding to the special symbol determined as described above is stored in the stop symbol data storage area.

  Next, the main CPU 110a performs special symbol variation time determination processing (S1804).

  Specifically, the variation pattern of the special symbol is determined based on the reach determination random number value and the special diagram variation random value stored in the 0th storage unit of the first special symbol random value storage area. Thereafter, the variation time of the special symbol corresponding to the determined variation pattern of the special symbol is determined. Then, a process of setting a counter corresponding to the determined variation time of the special symbol in the special symbol time counter is performed.

  The main CPU 110a sets variation display data for causing the first special symbol display device 20 or the second special symbol display device 21 to perform variation display of the special symbol (LED blinking) in a predetermined processing area.

  As a result, when variable display data is set in a predetermined processing area, LED lighting or extinguishing data is appropriately created by the above processing, and the created data is output, whereby the first special symbol display The variable display of the device 20 or the second special symbol display device 21 is performed.

  Furthermore, when the special symbol variation display is started (S1805), the main CPU 110a changes the special symbol variation pattern designation command (the first special symbol variation pattern designation command or the first special symbol variation pattern designation command) corresponding to the determined special symbol variation pattern. The second special symbol variation pattern designation command) is set in the effect transmission data storage area of the main RAM 110c.

  The main CPU 110a sets “Special Figure Special Electric Processing Data = 0” to “Special Special Electric Processing Data = 1” (S1806), prepares for the special symbol variation processing subroutine, and ends the special symbol memory determination processing. To do.

  FIG. 19 is an example of a flowchart showing a detailed flow of the main process performed on the effect control board 120 of the gaming machine in the embodiment of the present invention.

  First, the sub CPU 120a performs initialization processing (S1901).

  In this initialization process, the sub CPU 120a reads a main processing program from the sub ROM 120b and initializes and sets a flag and the like stored in the sub RAM 120c in response to power-on.

  Next, the sub CPU 120a performs an effect random number update process (S1902).

  In this effect random number update process, the sub CPU 120a updates the random numbers (the effect random number value 1, the effect random number value 2, the effect design determining random value, the effect mode determining random value, etc.) stored in the sub RAM 120c. Process.

  Subsequently, it is determined whether a power interruption process for shutting off the power is performed (S1903). Until the power interruption process is performed (NO in S1903), the effect random number update process is performed until a predetermined interrupt process is performed. Repeat. If the power interruption process is performed (YES in S1903), the process ends.

  FIG. 20 is an example of a flowchart showing a detailed flow of the timer interrupt process performed on the effect control board 120 of the gaming machine in the embodiment of the present invention.

  Although not shown in the figure, a clock pulse is generated every predetermined period (2 milliseconds) by a reset clock pulse generation circuit provided on the effect control board 120, a timer interrupt processing program is read, and the timer of the effect control board is read. Interrupt processing is executed.

  First, the sub CPU 120a saves the information stored in the register of the sub CPU 120a in the stack area (S2001), and updates various timer counters used in the effect control board 120 (S2002).

  Next, the sub CPU 120a performs command analysis processing (S2003).

  In this command analysis processing, the sub CPU 120a performs processing for analyzing a command stored in the reception buffer of the sub RAM 120c. Specific description of the command analysis processing will be described later with reference to FIGS. 21 and 22. When the effect control board 120 receives a command transmitted from the main control board 110, a command reception interrupt process of the effect control board 120 (not shown) occurs, and the received command is stored in the reception buffer. Thereafter, the received command is analyzed.

  The sub CPU 120a checks the signals of the effect button detection switch 35a and the cross key detection switch 36a, performs effect input control processing related to the effect button 35 (S2004), and receives various commands set in the transmission buffer of the sub RAM 120c. Data output processing to be transmitted to the lamp control board 140 and the image control board 150 is performed (S2005).

  Then, the sub CPU 120a restores the information saved in S1810 to the register of the sub CPU 120a (S2006).

  FIG. 21 is an example of a flowchart showing a detailed flow of a command analysis process performed on the effect control board 120 of the gaming machine in the embodiment of the present invention. FIG. 22 is a continuation of the command analysis process shown in FIG. It is a flowchart which shows.

  The sub CPU 120a confirms whether or not the command is received in the reception buffer, and confirms whether or not the command is received (S2101).

  If there is no command in the reception buffer (NO in S2101), the sub CPU 120a ends the command analysis process. If there is a command in the reception buffer (YES in S2101), it is subsequently confirmed whether or not the command stored in the reception buffer is a demo designation command (S2102).

  If the command stored in the reception buffer is a demonstration designation command (YES in S2102), the sub CPU 120a performs a demonstration effect pattern determination process for determining a demonstration effect pattern (S2103).

  Specifically, the demonstration effect pattern is determined, the determined demonstration effect pattern is set in the effect pattern storage area, and information on the determined demonstration effect pattern is transmitted to the image control board 150 and the lamp control board 140. An effect pattern designation command based on the demo effect pattern is set in the transmission buffer of the sub-RAM 120c.

  If the command stored in the reception buffer is not a demo designation command (NO in S2102), then the sub CPU 120a checks whether the command stored in the reception buffer is a special symbol storage designation command. (S2104).

  If the command stored in the reception buffer is a special symbol memory designation command (YES in S2104), the special symbol memory designation command is analyzed and displayed on the first liquid crystal display device 31 and / or the second liquid crystal display device 37. A special symbol memory number determination process for determining the number of special figure reservation images to be displayed and transmitting a special figure display number designation command corresponding to the determined display number of special figure reservation images to the image control board 150 and the lamp control board 140 (S2105).

  If the command stored in the reception buffer is not a special symbol storage designation command (NO in S2104), the sub CPU 120a then determines whether or not the command stored in the reception buffer is an effect symbol designation command. Confirmation is made (S2106).

  If the command stored in the reception buffer is an effect designating command (YES in S2106), the sub CPU 120a determines the first liquid crystal display device 31 and / or the second liquid crystal based on the content of the received effect designating command. An effect symbol determination process for determining an effect symbol 38 to be stopped and displayed on the display device 37 is performed (S2107).

  Specifically, the effect symbol determination process analyzes the effect symbol designation command, determines the effect symbol data constituting the combination of the effect symbols 38 according to the presence or absence of the jackpot and the type of jackpot, and the determined effect In addition to setting the symbol data in the effect symbol storage area and transmitting the effect symbol data to the image control board 150 and the lamp control board 140, a stop symbol designating command indicating the effect symbol data is set in the transmission buffer of the sub RAM 120c. .

  At this time, the sub CPU 120a further acquires one random number value from the effect mode determination random value updated as shown above, and based on the acquired effect mode determination random value and the received effect designating command. Then, an effect mode determination process for determining one effect mode from a plurality of effect modes (for example, a normal effect mode and a chance effect mode) is performed (S2108). Further, the determined effect mode is set in the effect mode storage area.

  If the command stored in the reception buffer is not an effect designating command (NO in S2106), the sub CPU 120a checks whether or not the command stored in the receiving buffer is a variation pattern specifying command (S2109). ).

  If the command stored in the reception buffer is a variation pattern designation command (YES in S2109), the sub CPU 120a acquires one random value from the updated effect random value 1, and the acquired effect random value 1. Based on the received variation pattern designation command and the effect mode set in the effect mode storage area, a variation effect pattern determination process for determining one variation effect pattern from a plurality of variation effect patterns is performed (S2110). .

  Thereafter, based on the effect pattern, the first liquid crystal display device 31, the audio output device 32, the decoration device 33a, the effect lighting device 34, and the second liquid crystal display device 37 are controlled. Note that the variation mode of the effect design 38 is determined based on the variation effect pattern determined here.

  If the command stored in the reception buffer is not a variation pattern designation command (NO in S2109), the sub CPU 120a checks whether or not the command stored in the reception buffer is a symbol determination command (S2111). .

  If the command stored in the reception buffer is a symbol determination command (YES in S2111), the sub CPU 120a transmits a stop designation command for stopping and displaying the effect symbol to stop the effect symbol 38 to be transmitted to the sub RAM 120c. An effect symbol stop process to be set in the buffer is performed (S2112).

  If the command stored in the reception buffer is not a symbol determination command (NO in S2111), the sub CPU 120a determines whether or not the command stored in the reception buffer is a gaming state designation command (S2113). .

  If the command stored in the reception buffer is a gaming state designation command (YES in S2113), the sub CPU 120a stores data indicating the gaming state based on the received gaming state designation command in the gaming state storage area in the sub RAM 120c. Set (S2114).

  If the command stored in the reception buffer is not a gaming state designation command (NO in S2113), the sub CPU 120a checks whether or not the command stored in the reception buffer is an opening command (S2115).

  If the command stored in the reception buffer is an opening command (YES in S2115), the sub CPU 120a performs a hit start effect pattern determination process for determining a hit start effect pattern (S2116).

  Specifically, the hit start effect pattern is determined based on the opening command, the determined hit start effect pattern is set in the effect pattern storage area, and information on the determined hit start effect pattern is controlled by the image control board 150 and the lamp control. In order to transmit to the board 140, an effect pattern designation command based on the determined hit start effect pattern is set in the transmission buffer of the sub RAM 120c.

  If the command stored in the reception buffer is not an opening command (NO in S2115), the sub CPU 120a determines that the command stored in the reception buffer is the first grand prize winning port 16 and / or the second major winning prize port 17. It is confirmed whether or not it is a special winning opening opening designation command for instructing opening (S2117).

  If the command stored in the reception buffer is a big winning opening opening designation command (YES in S2117), the sub CPU 120a performs a jackpot effect pattern determination process for determining a jackpot effect pattern (S2118).

  Specifically, the jackpot effect pattern is determined based on the big prize opening opening designation command, the determined jackpot effect pattern is set in the effect pattern storage area, and information on the determined jackpot effect pattern is stored in the image control board 150 and the lamp. In order to transmit to the control board 140, an effect pattern designation command based on the determined jackpot effect pattern is set in the transmission buffer of the sub RAM 120c.

  If the command stored in the reception buffer is not a special winning opening opening designation command (NO in S2117), the sub CPU 120a checks whether or not the command stored in the reception buffer is an ending command (S2119). ).

  If the command stored in the reception buffer is an ending command (YES in S2119), the sub CPU 120a performs a hit end effect pattern determination process for determining a hit end effect pattern (S2120).

  Specifically, the winning end effect pattern is determined based on the ending command, the determined winning end effect pattern is set in the effect pattern storage area, and information on the determined hit end effect pattern is controlled by the image control board 150 and the lamp control. In order to transmit to the board 140, an effect pattern designation command based on the determined hit end effect pattern is set in the transmission buffer of the sub-RAM 120c.

  If it is not any command (NO in S2119), the command analysis process is terminated by terminating the present process.

  Next, FIG. 23 is a flowchart showing a detailed flow of a main process performed in the image control board 150 of the gaming machine according to the embodiment of the present invention.

  When power is supplied from the power supply board 170, a system reset occurs in the liquid crystal control CPU 150a, and the liquid crystal control CPU 150a performs main processing as described below.

  The liquid crystal control CPU 150a performs an initialization process (S2301).

  In this initialization process, the liquid crystal control CPU 150a reads the main processing program from the liquid crystal control ROM 150c and instructs the initial settings of the various modules of the liquid crystal control CPU 150a and the VDP 2000 when the power is turned on.

  Here, the liquid crystal control CPU 150a, as an instruction for initial setting of the VDP 2000, (1) instructs the display circuit constituting the VDP 2000 to create and output a video signal, and therefore instructs the display of the video signal (display). (“1” is set to 0 bit of the register), or (2) image data that is frequently used in the decompression circuit constituting the VDP2000 (image data such as production symbol 38) is decompressed to the image data development area 153b of the VRAM 153. In order to set the initial value data in the expansion register, or (3) the initial value image data (such as a character image “power-on”) is drawn in the drawing circuit constituting the VDP 2000. Output value display list.

  Subsequently, the liquid crystal control CPU 150a performs a drawing execution start process (S2302).

  In this drawing execution start process, drawing execution start data is set in the drawing register in order to instruct VDP 2000 to execute drawing on the display list that has already been output.

  That is, at the start of power-on, execution of drawing on the initial value display list output at step (S2301) is instructed, and at normal routine processing, execution of drawing on the display list output at S2050 described later is instructed. It will be.

  Next, the liquid crystal control CPU 150a performs an effect instruction command analysis control process for analyzing the effect pattern designation command (command stored in the reception buffer of the liquid crystal control RAM 150b) transmitted from the effect control board 120 (S2303).

  When the image control board 150 receives a command transmitted from the effect control board 120, a command reception interrupt process of the image control board 150 (not shown) occurs, and the received command is stored in the reception buffer. Thereafter, the received command is analyzed.

  The effect pattern designation command analysis process confirms whether or not an effect pattern designation command is stored in the reception buffer. If the effect pattern designation command is not stored in the reception buffer, the process is continued. If the effect pattern designation command is stored in the reception buffer, a process of reading a new effect pattern designation command is performed. Based on the read effect pattern designation command, one or more animation groups to be executed are determined, and an animation pattern is determined from each animation group.

  When the animation pattern is determined, the read effect pattern designation command is deleted from the transmission buffer.

  Next, the liquid crystal control CPU 150a performs animation control processing (S2304).

  In this animation control process, based on the above-described “scene switching counter”, “weight frame”, “frame counter” to be updated, and the animation pattern determined by the process as described above, Update the scene address.

  Thereby, the liquid crystal control CPU 150a determines the display list from the display information (sprite identification number, display position, etc.) of one frame of the animation scene at the updated address according to the priority order (drawing order) of the animation group to which the animation scene belongs. When the generation of the display list is completed, the display list is output to the VDP 2000 (S2305). The display list output here is stored in the display list storage area 153a of the VRAM 153 via the CPU I / F 2030 in the VDP 2000.

  Then, the liquid crystal control CPU 150a determines whether or not the FB switching flag = 01 (S2306).

  Here, as will be described later with reference to FIG. 24B, the FB switching flag indicates that if the previous display list has been drawn in the V blank interrupt every 1/60 seconds (about 16.6 ms). , FB switching flag = 01. That is, it is determined whether or not the previous drawing has been completed.

  If the FB switching flag is “01” (YES in S2306), the liquid crystal control CPU 150a sets the FB switching flag to “00” (S2307) (turns off the FB switching flag) and ends the process.

  On the other hand, if the FB switching flag is “00” (NO in S2306), the process waits until the FB switching flag becomes “01”.

  Next, FIG. 24 is a flowchart showing a detailed flow of an interrupt process performed on the image control board 150 of the gaming machine according to the embodiment of the present invention.

  The interrupt processing of the image control board 150 includes a drawing end interrupt process performed by inputting a drawing end interrupt signal, a V blank interrupt process performed by inputting a V blank interrupt signal, and a player It includes at least an effect button press signal interrupt process performed by inputting an effect button press signal and a command reception interrupt process performed by receiving a command.

  The drawing end interrupt process and the V blank interrupt process will be described with reference to FIG. Since the command reception interrupt process is as described above, illustration is omitted.

  FIG. 24A is a flowchart showing a detailed flow of a drawing end interrupt process performed on the image control board 150 of the gaming machine according to the embodiment of the present invention.

  When the drawing of a predetermined unit frame (one frame) is completed, the VDP 2000 outputs a drawing end interrupt signal to the liquid crystal control CPU 150a.

  When the liquid crystal control CPU 150a receives a drawing end interrupt signal from the VDP 2000, the liquid crystal control CPU 150a executes a drawing end interrupt process.

  In the drawing end interrupt process, the liquid crystal control CPU 150a sets the drawing end flag = 01 (turns on the drawing end flag), and ends the current drawing end interrupt process (S2401). That is, the drawing end flag is turned on every time drawing ends.

  FIG. 24B is a flowchart showing a detailed flow of the V blank interrupt process performed on the image control board 150 of the gaming machine according to the embodiment of the present invention.

  The crystal oscillator 152 constituting the image control board 150 generates a V blank interrupt signal (vertical synchronization signal) having a pulse waveform every 1/60 seconds (about 16.6 ms), and this V blank interrupt signal is generated. The detected VDP 2000 outputs an “effect processing timing notification signal” based on the V blank interrupt signal to the liquid crystal control CPU 150a at a predetermined timing.

  Thereby, the liquid crystal control CPU 150a receives an “effect process timing notification signal” based on the V blank interrupt signal from the VDP 2000, and performs an interrupt process to perform an effect by receiving the effect process timing notification signal. The effect process is performed at the interrupt timing by the interrupt process.

  The predetermined timing at which the VDP 2000 outputs the “production process timing notification signal” to the liquid crystal control CPU 150a is determined based on the generated V blank interrupt signal.

  As an interrupt process performed by the image control board 150, first, the liquid crystal control CPU 150a performs a process of updating various counters of “scene switching counter”, “wait frame”, and “frame counter” from existing values by a unit quantity ( S2402).

  Subsequently, when the liquid crystal control CPU 150a performs processing for updating these various counters, it determines whether or not “01” is set in the “drawing end flag” (S2403). This “drawing end flag” is flag information for determining whether or not the rendering process of the effect image in the immediately preceding frame has ended.

  If the liquid crystal control CPU 150a determines that the “drawing end flag” is “01” (YES in step S2403), that is, determines that drawing of the effect image in the frame has ended, the “drawing end flag” "00" is set to "" (S2404).

  On the other hand, if “01” is not set in the “drawing end flag” (NO in S2403), that is, if it is determined that drawing of the effect image in the frame has not ended, the current V blank assignment Finish the process. Even if an effect processing timing notification signal based on the V blank interrupt signal is received from the VDP 2000, the subsequent interrupt processing is not performed unless the effect image drawing processing in the immediately preceding frame is completed in the liquid crystal control CPU 150a. It is shown that.

  Then, the rendering of the effect image in the immediately preceding frame has been completed, and when “00” is set in the “rendering end flag” (S2404), the liquid crystal control CPU 150a continues to the memory controller configuring the VDP2000. Then, together with an instruction to switch between “display frame buffer” and “drawing frame buffer”, an “effect processing timing notification signal” is output (S2405).

  This “effect process timing notification signal” is a signal for notifying the effect process timing in the liquid crystal control CPU 150a.

  Then, the liquid crystal control CPU 150a sets “01” in the “FB switching flag” (turns on the FB switching flag) (S2406), cancels the standby state, and ends the V blank interrupt processing.

  Thus, the liquid crystal control CPU 150a instructs the VDP2000 memory controller to generate an effect image in units of frames corresponding to the effect pattern designation command received from the effect control board 120 in the drawing frame buffer after switching.

  As a result, the VDP 2000 reads the image information constituting the effect image stored in the CGROM 151 and stores the effect image composed of the frames in the drawing frame buffer on the VRAM 153.

  In addition to this, in the VDP 2000, even if the V blank interrupt signal generated by the crystal oscillator 152 is detected, when the V blank interrupt signal is detected immediately before, an effect processing timing notification signal is notified to the liquid crystal control CPU 150a. If the V blank interrupt signal is present, the effect processing timing notification signal is not notified. Conversely, when the V blank interrupt signal is detected immediately before, the effect processing timing notification is sent to the liquid crystal control CPU 150a. When the signal is not notified, the presentation process timing notification signal may be notified in the case of the V blank interrupt signal.

  This is because, for example, when the V blank interrupt signal is detected in VDP2000, the interrupt flag is “valid (ON)”, so that the effect processing timing notification signal is notified to the liquid crystal control CPU 150a, and then the interrupt is performed. Set the flag from “valid (ON)” to “invalid (OFF)”. Subsequently, when the next V blank interrupt signal is received, since the interrupt flag is set to “invalid (OFF)”, the interrupt flag is not notified to the liquid crystal control CPU 150a without notifying the liquid crystal control CPU 150a. Is set to “valid (ON)”, an effect processing timing notification signal can be notified every other time (at intervals).

  FIG. 25 is a flowchart showing a detailed flow of an image display time adjustment control process performed in liquid crystal control CPU 150a configured by the gaming machine according to the embodiment of the present invention.

  In FIG. 25, the liquid crystal control CPU 150a starts processing upon receiving an effect pattern designation command from the effect control board 120, and determines whether or not it is a display request for an effect image based on the original movie data (S2501). If it is not determined by this determination processing that the effect pattern designation command received from the effect control board 120 is a display request for an effect image based on the original movie data (NO in S2501), the processing in this flowchart is not started.

  In this determination processing, whether or not the effect pattern designation command received from the effect control board 120 is a specific effect pattern designation command, and whether or not the original movie data and the reproduction information are associated with the effect pattern designation command. Is a process for determining.

  If it is determined that the effect pattern designation command received from the effect control board 120 is a display request for an effect image based on the original movie data (YES in S2501), the liquid crystal control CPU 150a reproduces information corresponding to the original movie data. The start frame of the “first designated position” designated in step S1 and the end frame of the “second designated position” designated in the same information are respectively identified (S2502).

  In this specifying process, when a plurality of first designated positions and second designated positions are designated in the reproduction information, the start frame and the end frame for the first designated position and the second designated position are specified.

  Then, the liquid crystal control CPU 150a generates playback movie data based on the playback information from the identified start frame to end frame (S2503). When a plurality of start frames and end frames are specified by the specifying process, playback movie data for the number of combinations of the start frames and end frames is generated.

  Subsequently, the liquid crystal control CPU 150a reads designated image frame information stored in the liquid crystal control ROM 150c or the like (S2504). As indicated above, the designated image frame information includes a frame image that must be included in the effect image when creating an effect image (reproduction frame data described later) that is reproduced using the original movie data. The designated information is indicated by the elapsed time from the start time of the original movie data.

  When the designated image frame information is read, the liquid crystal control CPU 150a sets the reproduction time of the reproduction movie data based on the designation image frame information to the “variable display time” of each reproduction movie data designated by the display list (more specifically, Performs time adjustment processing for adjusting the time to “variable display time” designated for the original movie data and the reproduction information in the display list (S2505).

  This time adjustment process specifies a frame image (designated image frame) based on designated image frame information from the reproduced movie data, and performs a process of thinning out other frame images other than this frame image, thereby reducing the reproduction time in the reproduced movie data. This is a process for shortening the time until the variable display time. The thinning-out process at this time is a process of thinning out frame images corresponding to the random number by using random numbers in addition to a process of thinning out frame images other than the designated image frame evenly.

  The time adjustment process described above is a process for shortening the playback time of the playback movie data. However, the present invention is not limited to this and may be a process for extending the playback time. In this expansion processing, expansion is performed by interpolating a new frame image between frame images.

  The liquid crystal control CPU 150a that has performed the time adjustment processing in this manner determines whether or not the time adjustment processing has been performed on all the playback movie data shown in the display list (S2506). If all playback movie data has not been time-adjusted (NO in S2506), the designated image frame information reading process shown in S2504 is repeated.

  On the other hand, when all the playback movie data is time adjusted (YES in S2506), the liquid crystal control CPU 150a issues a display instruction of “playback frame data” generated by the time adjustment by this time adjustment processing. The data is sent to the VDP 2000 (S2507). The transmission order at this time is based on the display order of the playback frame data specified in the display list.

  As a result, the liquid crystal control CPU 150a generates “playback frame data” in which the playback time of the playback movie data is adjusted.

  FIG. 27 is a diagram showing original movie data 1 and reproduction information associated with the original movie data 1.

  In FIG. 27, FIG. 27A shows “original movie data 1”, which is an example of original movie data, and represents a time series in a linear manner. The “original movie data 1” shown in FIG. 27A is movie data composed of frame images that require a playback time of “60 seconds”, and all six points (k0, This shows a state where k1, k2, k3, k4, k5) are set.

  The point “k0” set in the original movie data 1 indicates a reproduction start point (hereinafter referred to as “start point”) in the original movie data 1, and the point “k5” is the original movie data 1 Indicates the reproduction end point (hereinafter referred to as “end point”). That is, “original movie data 1” indicates that the reproduction time required for reproduction from the point “k0” to the point “k5” is “60 seconds”.

  The point “k1” represents an intermediate point when the point “k0” is reproduced from the point “k5”, and this point “k1” is “30 seconds” when the point “k0” is reproduced. It is a later point. Furthermore, the point “k2” represents an intermediate point between the point “k0” and the point “k1”, and is a point after “15 seconds” when the reproduction is started from the start point “k0”.

  The point “k3” is a point after the point “k1” and before the end point “k5”, and is a point “20 seconds” after the point “k1”. The point “k4” indicates the same point as the point “k1”.

  To sum up the above, the original movie data 1 is reproduced from the start point “k0”, passes through the point “k2”, and is intermediate between the start point “k0” and the end point “k5”. This is movie data that is played back up to the end point “k5” after passing through the point “k3” after passing the point “k1” (point “k4”).

  27 (b) and 27 (c) show the reproduction information associated with the original movie data 1 shown in FIG. 27 (a). As shown above, the reproduction information is the first information as shown in FIG. This is information used to create playback movie data from the first designated position to the second designated position, at least one designated position and the second designated position being designated.

  FIG. 27B shows “reproduction information 1”. In this “reproduction information 1”, reproduction movie data including a combination of five start points and end points (“reproduction movie shown in FIG. 28B”). Information used to create data 1 ").

  In the reproduction information 1, the first combination is “30 seconds” when the start point is the point “k0” and the end point is the point “k1”. The second combination is the start point “15 seconds” when the point is “k1” and the end point is “k2”. The third combination is when the start point is “k2” and the end point is “k3”. “35 seconds”.

  In the second combination at this time, since the start point is the point “k1” and the end point is the point “k2”, the reproduction direction is the reverse of the reproduction direction reproduced by the first combination. Will be played. That is, in the second combination, since the start point is the point “k1” and the end point is the point “k2”, the end point “k2” is more chronologically past than the start point “k1”. The point is shown.

  This indicates that playback is performed in the reverse playback direction opposite to the playback direction played back by the first combination. Although details will be described later, in the reel images as shown in FIGS. 31 to 34, rotation in a direction (reverse direction) different from the first combination that rotates in the forward direction is shown (reverse rotation).

  The fourth combination is “20 seconds” when the start point is the point “k3” and the end point is the point “k4”, and the fifth combination is the point “k4”. And “30 seconds” when the end point is the point “k5”.

  In the fourth combination, the start point is the point “k3”, the end point is the point “k4”, and the end point “k4” indicates the past point in time series from the start point “k3”. ing.

  This indicates that reproduction is performed in the reverse reproduction direction opposite to the reproduction direction reproduced by the third combination. Although details will be described later, in the reel image as shown in FIGS. 31 to 34, the reel image rotates in a direction (reverse direction) different from the third combination that rotates in the forward direction (reverse rotation).

  By using the reproduction information composed of the combination of the five start points and the end points as described above, the original movie data having the reproduction time “60 seconds” becomes “30 seconds + 15 seconds + 35 seconds + 20 seconds + 30 seconds”. Playback movie data having a playback time of “130 seconds” calculated in the above is created. The reproduction movie data “reproduction movie data 1” is shown in FIG.

  Further, FIG. 27C shows “reproduction information 2”. In this “reproduction information 2”, reproduction movie data including a combination of three start points and end points (“reproduction information 2” shown in FIG. 28D). This is information used to create reproduction movie data 2 ").

  In the reproduction information 2, the first combination is “30 seconds” when the start point is the point “k0” and the end point is the point “k1”. The second combination is the start point “15 seconds” when the point is “k1” and the end point is the point “k2”, and the third combination is when the start point is the point “k2” and the end point is the point “k5” “45 seconds”.

  In the second combination at this time, since the start point is the point “k1” and the end point is the point “k2”, the reproduction direction is the reverse of the reproduction direction reproduced by the first combination. Will be played. That is, in the second combination, since the start point is the point “k1” and the end point is the point “k2”, the end point “k2” is more chronologically past than the start point “k1”. The point is shown.

  This indicates that reproduction is performed in the reverse reproduction direction opposite to the reproduction direction reproduced by the third combination. Although details will be described later, in the reel images as shown in FIGS. 31 to 34, rotation in a direction (reverse direction) different from the first combination that rotates in the forward direction is shown (reverse rotation).

  By using the reproduction information composed of the combination of the three start points and the end points as described above, the original movie data whose reproduction time is “60 seconds” is calculated by “30 seconds + 15 seconds + 45 seconds”. Playback movie data having a playback time of “90 seconds” in total is created. The reproduction movie data “reproduction movie data 2” is shown in FIG.

  FIG. 28 is a diagram illustrating an example of image data (reproduction frame data) generated until an effect image to be reproduced is generated by time adjustment processing.

  This reproduction frame data is generated based on the display list as shown in FIG. 14C received by the VDP 2000 from the liquid crystal control CPU 150a.

  FIG. 28A shows “original movie data 1”, similar to that shown in FIG.

  FIG. 28B shows “reproduction movie data 1” generated by using “reproduction information 1” shown in FIG. 27B set for “original movie data 1”. This “reproduced movie data 1” is movie data composed of a reproduction time of “130 seconds” as described with reference to FIG.

  FIG. 28C shows movie data (“playback frame data”) generated by shortening the playback time by performing time adjustment processing on “playback movie data 1” shown in FIG. It is called). “Playback frame data 1” shown in FIG. 28C includes a designated image frame set for “original movie data 1”, and other frame images other than the designated image frame are thinned out at a predetermined interval. This is the movie data generated by

  The playback frame data shown in FIG. 28C is generated based on “playback movie data 1” consisting of “130 seconds” shown in FIG. 28B, and has a playback time of “30 seconds”. That is, “reproduction frame data 1” is generated by reducing the reproduction time of “130 seconds” to the reproduction time of “30 seconds” by the time adjustment process.

  FIG. 28D shows “reproduced movie data 2” generated by using “reproduced information 2” shown in FIG. 27C set for “original movie data 1”. This “reproduced movie data 2” is movie data composed of a reproduction time of “90 seconds” as described with reference to FIG.

  FIG. 28E shows movie data (“playback frame data”) generated by reducing the playback time by performing time adjustment processing on “playback movie data 2” shown in FIG. It is called). The playback frame data shown in FIG. 28 (e) includes a designated image frame set for “original movie data 2”, and is generated by thinning out other frame images other than the designated image frame at a predetermined interval. Movie data.

  “Playback frame data 2” shown in FIG. 28 (e) is generated based on “playback movie data 2” consisting of “90 seconds” shown in FIG. 28 (d), and has a playback time of “60 seconds”. Consists of. That is, “reproduction frame data 2” in which the reproduction time of “90 seconds” is shortened to the reproduction time of “60 seconds” by the time adjustment process is generated.

  FIG. 28 (f) shows “reproduction frame data 1” shown in FIG. 28 (c) and FIG. 28 (e) based on the display list shown in FIG. 14 (c) received by the VDP 2000 from the liquid crystal control CPU 150a. The reproduction effect image displayed by the VDP 2000 receiving the display list configured by setting the reproduction order of the “reproduction frame data 2” shown in FIG.

  The reproduction effect image shown in FIG. 28F is obtained by reproducing “reproduction frame data 2” having a reproduction time “60 seconds” following “reproduction frame data 1” having a reproduction time “30 seconds”. A total of “90 seconds” of playback time and a displayed effect image.

  From the above, the reproduction effect image shown in FIG. 28F is displayed when the variation time designated by the variation pattern designation command received by the effect control board 120 from the main control board 110 is “90 seconds”. This is a production image.

  FIG. 29 is a diagram showing original movie data 2 and reproduction information associated with the original movie data 2.

  In FIG. 29, FIG. 29A shows “original movie data 2” which is an example of the original movie data, and represents the time series in a linear manner. The “original movie data 2” shown in FIG. 29A is movie data composed of frame images that require a reproduction time of “60 seconds”, and all six points (k0, This shows a state where k1, k2, k3, k4, k5) are set.

  The “original movie data 2” requires the same reproduction time as the “original movie data 1” shown in FIG. 27A, and is movie data showing the production contents different from the “original movie data 1”. is there.

  The point “k0” set in the original movie data 2 indicates a reproduction start point (hereinafter referred to as “start point”) in the original movie data 2, and the point “k5” is the original movie data 2 Indicates the reproduction end point (hereinafter referred to as “end point”). That is, “original movie data 2” indicates that the reproduction time required for reproduction from the point “k0” to the point “k5” is “60 seconds”.

  The point “k1” represents an intermediate point when the point “k0” is reproduced from the point “k5”, and this point “k1” is “30 seconds” when the point “k0” is reproduced. It is a later point. Furthermore, the point “k2” represents an intermediate point between the point “k0” and the point “k1”, and is a point after “15 seconds” when the reproduction is started from the start point “k0”.

  The point “k3” is a point after the point “k1” and before the end point “k5”, and is a point “20 seconds” after the point “k1”. The point “k4” indicates the same point as the point “k1”.

  To sum up the above, the original movie data 2 is reproduced from the start point “k0”, passes through the point “k2”, and is intermediate between the start point “k0” and the end point “k5”. This is movie data that is played back up to the end point “k5” after passing through the point “k3” after passing the point “k1” (point “k4”).

  FIGS. 29 (b) and 29 (c) show reproduction information associated with the original movie data 2 shown in FIG. 29 (a). This is information used to create playback movie data from the first designated position to the second designated position, at least one designated position and the second designated position being designated.

  FIG. 29B shows “reproduction information 1”, and this “reproduction information 1” is the same as “reproduction information 1” shown in FIG. In other words, “original movie data 1” and “original movie data 2” are associated with the same reproduction information “reproduction information 1”.

  Further, FIG. 29C shows “reproduction information 3”. In this “reproduction information 3”, reproduction movie data composed of combinations of three start points and end points (“reproduction information 3” shown in FIG. 30D). This is information used to create the playback movie data 4 ").

  In the reproduction information 3, the first combination is “30 seconds” when the start point is the point “k0” and the end point is the point “k1”. The second combination is the start point “15 seconds” when the point is “k1” and the end point is the point “k2”, and the third combination is when the start point is the point “k2” and the end point is the point “k4” “15 seconds”.

  In the second combination at this time, since the start point is the point “k1” and the end point is the point “k2”, the reproduction direction is the reverse of the reproduction direction reproduced by the first combination. Will be played. That is, in the second combination, since the start point is the point “k1” and the end point is the point “k2”, the end point “k2” is more chronologically past than the start point “k1”. The point is shown.

  This indicates that reproduction is performed in the reverse reproduction direction opposite to the reproduction direction reproduced by the third combination. Although details will be described later, in the reel images as shown in FIGS. 31 to 34, rotation in a direction (reverse direction) different from the first combination that rotates in the forward direction is shown (reverse rotation).

  By using the reproduction information composed of the combination of the three start points and the end points as described above, the original movie data whose reproduction time is “60 seconds” is calculated by “30 seconds + 15 seconds + 15 seconds”. Playback movie data having a playback time of “60 seconds” in total is created. The reproduction movie data “reproduction movie data 4” is shown in FIG.

  FIG. 30 is a diagram illustrating an example of image data (reproduction frame data) generated until an effect image to be reproduced is generated by time adjustment processing.

  This reproduction frame data is generated based on the display list as shown in FIG. 14C received by the VDP 2000 from the liquid crystal control CPU 150a.

  FIG. 30A shows “original movie data 2”, similar to that shown in FIG.

  FIG. 30B shows “reproduction movie data 3” generated by using “reproduction information 1” shown in FIG. 29B set for “original movie data 2”. This “reproduced movie data 3” is movie data composed of a reproduction time of “130 seconds” as described with reference to FIG.

  FIG. 30C shows movie data (“playback frame data”) generated by shortening the playback time by performing time adjustment processing on “playback movie data 3” shown in FIG. It is called). “Playback frame data 3” shown in FIG. 30C includes a designated image frame set for “original movie data 3”, and other frame images other than the designated image frame are thinned out at a predetermined interval. This is the movie data generated by

  The playback frame data shown in FIG. 30C is generated based on “playback movie data 3” consisting of “130 seconds” shown in FIG. 30B, and has a playback time of “30 seconds”. That is, “reproduction frame data 3” is generated by reducing the reproduction time of “130 seconds” to the reproduction time of “30 seconds” by the time adjustment process.

  FIG. 30D shows “playback movie data 4” generated by using “playback information 3” shown in FIG. 29C set for “original movie data 2”. This “playback movie data 4” is movie data constituted by a playback time of “60 seconds” as described with reference to FIG.

  FIG. 30E shows movie data (“playback frame data”) generated by reducing the playback time by performing time adjustment processing on “playback movie data 4” shown in FIG. It is called). The playback frame data shown in FIG. 30 (e) includes a designated image frame set for “original movie data 4”, and is generated by thinning out other frame images other than the designated image frame at a predetermined interval. Movie data.

  “Playback frame data 4” shown in FIG. 30 (e) is generated based on “playback movie data 4” consisting of “60 seconds” shown in FIG. 30 (d), and has a playback time of “45 seconds”. Consists of. That is, “reproduction frame data 4” is generated by reducing the reproduction time of “60 seconds” to the reproduction time of “45 seconds” by the time adjustment process.

  FIG. 30 (f) shows “reproduction frame data 3” shown in FIG. 30 (c) and FIG. 28 (e) based on the display list shown in FIG. 14 (c) received by the VDP 2000 from the liquid crystal control CPU 150a. 4 shows a reproduction effect image that is displayed by the VDP 2000 receiving the display list that is configured by setting the reproduction order of the “reproduction frame data 3” shown.

  The reproduction effect image shown in FIG. 30 (f) is obtained by reproducing “reproduction frame data 4” having a reproduction time “60 seconds” following “reproduction frame data 3” having a reproduction time “30 seconds”. A total of “75 seconds” of playback time and a displayed effect image.

  From the above, the reproduction effect image shown in FIG. 30F is displayed when the variation time designated by the variation pattern designation command received by the effect control board 120 from the main control board 110 is “75 seconds”. This is a production image.

  In the display list shown in FIG. 14C, following the “playback frame data 1” created using the playback information 1 for the original movie data 1, the playback information 2 is used for the original movie data 1. “Playback frame data 2” to be created is displayed. Further, “Playback frame data 3” created by using the playback information 1 for the original movie data 2 is followed by playback information for the original movie data 2. 3 is instructed to display “playback frame data 4” created by using 3.

  Therefore, in the VDP 2000 that has received the display list shown in FIG. 14C, the playback effect image (playback frame data 1, playback frame data 2) shown in FIG. 28F is displayed for “90 seconds”. The reproduction effect image (reproduction frame data 3 and reproduction frame data 4) shown in FIG. 30 (f) is displayed for "75 seconds".

  FIGS. 31 to 35 are diagrams showing “reproduction frame data 2” generated using the reproduction information 2 for the original movie data 1.

  That is, FIGS. 31 to 35 show “reproduction frame data 2” as an example of the reproduction frame data. Similarly, “reproduction frame data 1”, “reproduction frame data 3”, and “reproduction frame data”. “4” is also generated using original movie data and reproduction information, although not shown.

  31 to 33, a reel image showing a rotated state is shown. FIGS. 31 (a), 32 (a), and 33 (a) show the same first reel image. 31 (b), 32 (b), and 33 (b) show the same second reel image, and the same third reel in FIGS. 31 (c), 32 (c), and 33 (c). 31 (d), FIG. 32 (d), and FIG. 33 (d) show the same fourth reel image, and the same as FIG. 31 (e), FIG. 32 (e), and FIG. 33 (e). The fifth reel image is shown.

  The rotation state of the reel image will be described with reference to FIG. 32 and 33 also show a rotation state using the same reel image.

  Transition from the state of the first reel image shown in FIG. 31 (a) to the state of the second reel image shown in FIG. 31 (b) and from the state of the second reel image shown in FIG. 31 (b) to FIG. To the state of the third reel image shown in FIG. Further, the state of the third reel image shown in FIG. 31C is shifted to the state of the fourth reel image shown in FIG. 31D, and the state of the fourth reel image shown in FIG. A transition is made to the state of the fifth reel image shown in (e).

  By continuously performing FIG. 31A to FIG. 31E, an image rotated from top to bottom is displayed.

  FIG. 31 shows the reel image displayed when the reproduction information 2 shown in FIG. 27C is used for the original movie data 1 showing the rotation state of the reel image as shown in FIGS. Thru | or the lower part of FIG.

  The lower part of FIG. 31 shows the playback movie data from the point “k0” to the point “k1” indicated in “playback information 2” with respect to the original movie data 1. Also, in the lower part of FIG. 32, the playback movie data from the point “k1” to the point “k2” indicated in “playback information 2” with respect to the original movie data 1 is shown. Further, in the lower part of FIG. 33, the playback movie data from the point “k2” to the point “k5” indicated in “playback information 2” with respect to the original movie data 1 is shown.

  At this time, the playback movie data from the point “k1” to the point “k2” shown in the lower part of FIG. 32 is more time-series than the point “k1” where the point “k2” as the end point is the start point. Shows past points. Accordingly, a state in which the reel image rotates in another rotation direction (reverse direction) different from the rotation direction of the reel image shown in the lower part of FIG. 31 is shown.

  FIG. 34 is a diagram showing an example of the playback movie data 2 created by the time adjustment process performed in the liquid crystal control CPU 150a configured by the gaming machine according to the embodiment of the present invention.

  Reproduction movie data 2 shown in FIG. 34 is movie data created using original movie data 1 and reproduction information 2, and has a variable display time (reproduction time) of “90 seconds”.

  The reproduced movie data 2 shown in FIG. 34 displays the reproduced movie data shown in the lower part of FIG. 31 from the point “k0” to the point “k1” of the original movie data, and then the point “k1” to the point “ After displaying the playback movie data shown in the lower part of FIG. 32 until “k2”, the playback movie data shown in the lower part of FIG. 33 from the point “k2” to the point “k5” of the original movie data is continuously displayed. Is shown.

  FIG. 35 is a diagram conceptualizing the processing steps of the time adjustment processing performed in the liquid crystal control CPU 150a configured by the gaming machine in the embodiment of the present invention.

FIG. 35A is a diagram showing the playback movie data, which is the same image as the reel image shown in FIG. 34, and FIG. 35B is a diagram other than the designated image frame shown in FIG. FIG. 35C is a diagram showing newly created reproduction frame data after the time adjustment processing.
Such a time adjustment process is performed.

  The embodiment described above is one embodiment of the present invention, and is not limited to these examples, and can be implemented with appropriate modifications within a range not changing the gist thereof.

1 gaming machine 150 image control board 150a liquid crystal control CPU
150b Liquid crystal control RAM
150c LCD control ROM
150d first counter (frame counter)
151 CGROM
152 Crystal Oscillator 153 VRAM

Claims (1)

Effect moving image storage means for storing effect moving images composed of a plurality of effect images, which are used for effects performed in games using game media;
When the display of the effect moving image is requested, at least a part of the effect moving image corresponding to the display request stored in the effect moving image storage unit is used, and the display effect moving image used in the effect in the display request is displayed. Generating means for generating;
A time adjustment control means for performing time adjustment control for adjusting a playback time of the display effect moving image generated by the generating means to an image display time designated for an effect performed using the effect requested moving image;
Display control means for controlling display of the display effect moving image adjusted to the image display time by the time adjustment control by the time adjustment control means, and
The time adjustment control means includes:
When displaying the display effect moving image with an image display time shorter than the reproduction time of the display effect moving image generated by the generating means, the display effect moving image is displayed among the effect images constituting the display effect moving image. A game machine that adjusts the playback time of the display effect moving image to the image display time by thinning out another effect image different from the specified effect image that is always included in the effect to be performed.

Images