JP2017159102A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine capable of preferably improving an interest of a game.SOLUTION: A Pachinko machine comprises: a pattern display device 94 having a display screen; and a display control device 500 for performing a display performance at the display screen. The display control device 500 comprises: a display CPU 520 for 2D for executing a 2D performance as the performance; a display CPU 530 for executing a 3D performance at the same display screen; and a memory module 540 for storing 2D image data and 3D image data which are referred to when creating drawing data for respective performances. In a game, one of the 2D performance and 3D performance is selected for executing a display performance. The display control device 500 executes a predetermined 3D performance among plural kinds of 3D performances, so that, a player recognizes that the 3D performance image displayed in the 3D performance and the 2D performance image displayed in the 2D performance during execution are in series.SELECTED DRAWING: Figure 24

Description

  The present invention relates to a gaming machine.

  Among gaming machines such as pachinko machines, those equipped with a display device such as a liquid crystal display device having a display screen are known. In this type of gaming machine, the entertainment is improved by dividing the effects performed on the display screen into a plurality of parts (parts) and realizing diversification of the display effects. For example, the degree of attention to the display effect is improved by suggesting the presence / absence or type of the later (for example, the latter half) effect in the former (for example, the first half) effect. As an aspect of such effects, there is a technique in which a reach notice effect is performed before shifting to reach display, and a reach effect corresponding to the previous reach notice effect is performed after shifting to reach display.

  However, when diversification is attempted by simply dividing the production, the visual connection between the previous production and the later production is diminished, so that the game is integrated between the start and end of the game times. There is concern that it will be difficult to perform a special performance. For example, for a player who has little knowledge about the gaming machine, it is easy to give an impression that the two effects are separate effects that are not connected, and the above-described suggestion function or the like is difficult to be exhibited.

  In recent years, for example, a gaming machine that executes an effect having a story property has been proposed as an effect after the above. In such a gaming machine, when the story is developed by a later production, the production period is limited, so it is difficult to enhance the content of the production and improve the entertainment.

JP 2007-7465 A

  As described above, in the gaming machine in which the effects performed during the game round are divided into a plurality of parts, there is still room for improvement in order to improve the interest.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a gaming machine capable of suitably improving the interest of games.

The present invention
Information acquisition means for acquiring special information based on the establishment of a predetermined acquisition condition;
Determination means for determining whether or not the special information acquired by the information acquisition means corresponds to predetermined transition information;
Transition means for shifting to a specific gaming state that is more advantageous to the player than usual, based on the determination result by the determination means being a transition response result that corresponds to the transition information;
A display unit having a display screen;
After performing variable display of a plurality of pictures on the display screen, comprising variable display means for stopping and displaying the pictures in a combination corresponding to the determination result by the determination means,
A game in which a predetermined picture combination corresponding to the transition correspondence result is stopped and displayed on the display screen before the transition to the specific gaming state when the determination result by the determination means is the transition correspondence result. Machine,
First effect means for implementing a first effect as a display effect displayed on the display unit;
Second effect means for performing a second effect as a display effect displayed on the display unit;
Data storage means for storing image data for the first effect relating to the first effect and image data for the second effect relating to the second effect;
The first effect means has means for generating first effect drawing data using the first effect image data read from the data storage means,
The second effect means includes means for generating second effect drawing data using the second effect image data read from the data storage means,
The second effect means displays a predetermined second effect among a plurality of types of second effects as indicated by the second effect image displayed in the second effect and the first effect being performed. There is provided a means for performing so that the player recognizes that the first effect image shown is in a series,
The second effect is reached after reaching a reach state in which the picture stopped and displayed on the display screen constitutes a part of the predetermined picture combination and at least a part of the picture is variably displayed. It is configured to be performed as a production,
The first effect means implements the first effect as a suggestion effect that suggests a second effect that can be executed after the reach state in the same game times when the reach state is reached,
The first effect means sets the first effect image on the display screen to a predetermined display mode on the display screen before entering the reach state, and starts an image in the predetermined display mode until the second effect is started. It is characterized by maintaining.

  It is possible to suitably improve the interest of the game.

It is a front view which shows the pachinko machine in 1st Embodiment. It is the perspective view which looked at the pachinko machine from diagonally forward. It is a perspective view which expands and shows the main structures of a pachinko machine. It is a perspective view which expands and shows the main structures of a pachinko machine. It is the disassembled perspective view which looked at the front door frame from the back side. FIG. 2 is a partial cross-sectional view taken along line AA in FIG. 1. It is a front view which shows the structure of an inner frame. (A) It is a front view which shows the structure of a game board, (b) It is sectional drawing which shows the structure of a game board. It is a rear view which shows the structure of an inner frame. It is a perspective view which shows the back surface structure of a game board. It is a front view which shows the structure of a back pack unit. It is a block diagram which shows the electric constitution of a pachinko machine. It is explanatory drawing for demonstrating the display content on the display screen of a symbol display apparatus. It is explanatory drawing for demonstrating the content of the various counters used for a success or failure lottery. It is a flowchart which shows the timer interruption process in MPU of a main controller. It is a flowchart which shows the winning process for the operation port in MPU of a main controller. It is a flowchart which shows an information acquisition process. It is a flowchart which shows a normal process. It is a flowchart which shows game times control processing. It is a flowchart which shows a data setting process. It is a flowchart which shows a fluctuation | variation start process. It is a flowchart which shows the setting process of a fluctuation | variation display time. It is a flowchart which shows a game state transfer process. It is a block diagram which shows the electrical structure concerning a display effect. (A) is the schematic which shows the kind of fluctuation | variation display aspect, (b) group is the schematic which shows the outline | summary of each fluctuation | variation display aspect. It is a flowchart which shows the confirmation process of holding information. It is a flowchart which shows the setting process of a pending command. It is a flowchart which shows the response | compatibility process of a pending command. (A) It is a flowchart which shows a big hit correspondence setting process, (b) It is a flowchart which shows a loss reach correspondence setting process. (A) Flowchart showing pending command handling processing, (b) Flowchart showing 3D image data reading start timing setting processing. It is a flowchart which shows a fluctuation | variation display control process. (A) Flowchart showing variation start processing, (b) Flowchart showing effect switching processing. It is a flowchart which shows the process for a fluctuation | variation completion. It is a flowchart which shows V interruption process. (A)-(c) It is explanatory drawing for demonstrating the content of the drawing list | wrist for 2D. (A)-(c) It is explanatory drawing for demonstrating the content of the drawing list | wrist for 3D. It is a flowchart which shows a drawing process. It is the schematic which shows the operation | movement of the character in a display screen. It is the schematic which shows the mode of switching from 2D effect to 3D effect. It is a timing chart which shows the reading mode and erasing mode of 3D image data. It is a timing chart which shows the reading mode and erasing mode of 3D image data. It is a flowchart which shows the drawing list creation process for operation corresponding | compatible 3D effects in 2nd Embodiment. It is the schematic which shows the mode of creation of the data for 3D drawing. (A) It is a flowchart which shows a big hit correspondence setting process, (b) It is a flowchart which shows a loss reach correspondence setting process. It is a flowchart which shows the setting process for notification effect display. It is the schematic which shows the flow of the display effect in the game time in which super reach D is performed. It is the schematic which shows the outline | summary of reach production. It is the schematic for demonstrating the outline | summary of an image process.

<First Embodiment>
Hereinafter, a first embodiment of a pachinko gaming machine (hereinafter referred to as a “pachinko machine”), which is a type of gaming machine, will be described in detail with reference to the drawings. FIG. 1 is a front view of the pachinko machine 10, FIG. 2 is a perspective view of the pachinko machine 10 as viewed obliquely from the front, and FIGS. 3 and 4 are exploded perspective views showing the main configuration of the pachinko machine 10. In FIG. 3, the configuration in the game area of the pachinko machine 10 is omitted for convenience.

  As shown in FIG. 1, the pachinko machine 10 includes an outer frame 11 that forms an outer shell of the pachinko machine 10, and a gaming machine main part 12 attached to the outer frame 11.

  The outer frame 11 is configured by connecting wooden plates to four sides and has a rectangular frame shape. The pachinko machine 10 is installed in the island facility of the game hall by attaching and fixing the outer frame 11 to the island facility. In the pachinko machine 10, the outer frame 11 is not an essential configuration, and the outer frame 11 may be provided on the island facility of the game arcade.

  The game machine main part 12 is supported by the outer frame 11 in an openable and closable state. Specifically, as shown in FIG. 2, an upper support bracket 17 is fixed to a connection portion between the upper frame portion and the left frame portion in the outer frame 11, and the lower frame portion and the left frame in the outer frame 11 are further fixed. The lower support metal fitting 18 is fixed to a connecting portion with the portion. The upper support bracket 17 and the lower support bracket 18 form a support mechanism. The support mechanism causes the gaming machine main unit 12 to turn the left side of the pachinko machine 10 in the front view with respect to the outer frame 11. In addition, the right side can be turned forward of the pachinko machine 10 with the turning tip side.

  As shown in FIG. 3, the gaming machine main part 12 includes an inner frame 13 as a base body, a front door frame 14 arranged in front of the inner frame 13, and a back pack arranged behind the inner frame 13. And a unit 15 (see FIG. 4). The inner frame 13 of the gaming machine main part 12 is supported so as to be rotatable with respect to the outer frame 11.

  A front door frame 14 is rotatably attached to an end of the inner frame 13 on the rotation base end side, and the front door frame 14 rotates on the right side with the left side as the rotation base end side in a front view. It can be turned forward as the tip side. Further, as shown in FIG. 4, a back pack unit 15 is rotatably attached to an end of the inner frame 13 on the rotation base end side, and the back pack unit 15 rotates on the left side when viewed from the front. The moving base end side is set to the right and the right side is set to the rotating tip end side so that it can be rotated rearward.

  Next, the front door frame 14 will be described. In the following description, FIG. 1 and FIG. 2 are referred to, and the configuration of the back surface of the front door frame 14 is referred to FIG. 3 and FIG. FIG. 5 is an exploded perspective view of the front door frame 14 as seen from the back side.

  As shown in FIG. 3, the front door frame 14 is mainly composed of a synthetic resin frame body 20 whose outer shape is substantially the same as that of the outer frame 11, and covers substantially the entire front side of the inner frame 13. ing. A substantially elliptical window portion 21 (see FIG. 1) is formed in the central portion of the frame body 20 so that almost the entire gaming area PE described later can be viewed from the front of the gaming machine. 21 is covered from the back side of the front door frame 14 by the glass unit 30.

  As shown in FIG. 5, a glass unit installation portion 22 is formed on the frame 20 so as to surround the window portion 21. Specifically, the glass unit installation portion 22 is disposed on the back side of the frame body 20 and is recessed toward the front of the pachinko machine 10, and the window portion 21 is disposed at the bottom thereof. The glass unit 30 is fitted in the glass unit installation portion 22 so that the displacement in the vertical direction and the horizontal direction is restricted.

  The glass unit 30 includes glass panels 31 and 32 having transparency, and a glass holder 33 that holds the glass panels 31 and 32. The glass holder 33 has an annular frame portion 34 formed along the window portion 21, and glass panels 31 and 32 are accommodated in a region surrounded by the frame portion 34.

  More specifically, the frame portion 34 is formed with a partition portion that divides the enclosed region back and forth. The partition portion stands up to the center side of the frame portion 34 and has a ridge extending in the circumferential direction of the frame portion 34, and a storage portion for individually storing the glass panels 31 and 32 is defined by the partition portion. Yes.

  Each glass panel 31 and 32 is bonded to the partition portion in a state of facing each other with the partition portion interposed therebetween. Thereby, a predetermined gap is secured between the glass panels 31 and 32, and the game area PE is moved from the front side of the pachinko machine 10 by the glass panels 31 and 32 while avoiding interference between the glass panels 31 and 32. It is in a state of being covered twice.

  In addition, a plurality of attachment portions 35 for the frame body 20 are formed on the frame portion 34 so as to protrude to the side opposite to the side accommodating the glass panels 31 and 32. The attachment portion 35 has a plate-like shape facing the back surface of the frame body 20, and a lever member 23 is disposed on the frame body 20 to sandwich and hold the attachment portion 35 between the frame body 20. Yes.

  The lever member 23 is attached in a rotatable state between a holding position for holding the attachment portion 35 and a release position for not holding the mounting portion 35. In the lever member 23, a convex portion that protrudes toward the mounting portion 35 is formed in a portion facing the mounting portion 35, and the convex portion is fitted into a concave portion formed in the mounting portion 35, thereby The movement from the clamping position to the release position is restricted, that is, the movement is held at the clamping position.

  In the present embodiment, when the glass unit 30 is attached to the frame body 20, means for simply holding the glass unit 30 so as not to drop off the glass unit installation portion 22 is the lever member 23. And is attached.

  Specifically, the rear surface of the frame body 20 is provided with a protrusion that protrudes rearward from the rear surface and has an upward turn formed at the tip portion. Is formed with a receiving portion 36 on which the above-mentioned return is hooked. When the projection is caught on the receiving portion 36, the glass unit 30 is easily prevented from dropping from the mounting completion position. In addition, the said hook is cancelled | released by lifting up the glass unit 30 so that a protrusion may be reversed, and the glass unit 30 from the frame 20 becomes removable.

  The glass unit 30 tends to be heavy. For this reason, if it is necessary to continue to support the glass unit 30 by hand until the fixing operation by the lever member 23 is completed, it is assumed that the work load on the mounting operation of the glass unit 30 increases. In this regard, if the glass unit 30 is simply held at the mounting completion position as described above, it is not necessary to continue to support the glass unit 30 by hand when performing the fixing operation with the lever member 23, thereby facilitating the operation. Can be realized. Therefore, it can suppress that the work load concerning the mounting | wearing operation | work of the glass unit 30 becomes large.

  Referring back to FIG. 1, light emitting means such as various lamps are provided around the window portion 21. For example, an annular illumination part 24 incorporating a light emitting means such as an LED is provided along the periphery of the window part 21. In the annular illumination unit 24, lighting or blinking is performed according to a change in the gaming state at the time of a big hit or a predetermined reach. More specifically, a top lamp portion 25 provided with a function of turning on at a predetermined error is provided at the center of the annular illumination portion 24 and at the uppermost portion of the pachinko machine 10, and prizes are provided on the left and right sides of the window portion 21. A side lamp portion 26 to which a function of lighting during ball payout is given is provided. In addition, on both the left and right sides of the top lamp unit 25, speaker units 27 for outputting sound effects corresponding to the gaming state are provided.

  Hereinafter, the side lamp unit 26 and the configuration associated therewith will be described with reference to FIGS. 1 and 6. 6 is a partial cross-sectional view taken along line AA of FIG.

  As shown in FIG. 1, the side lamp portion 26 extends vertically along the left and right end portions of the frame body 20. The central portion of the side lamp portion 26 protrudes to the inside of the window portion 21, and the central portion faces the front glass panel 31 (region partitioned by the window portion 21) with a gap from the front of the gaming machine. (See FIG. 6). More specifically, the central portion of the side lamp portion 26 faces the game area PE with the glass panel 31 sandwiched from the front.

  As shown in FIG. 6, the side lamp unit 26 includes a light emitting substrate 26a on which a light emitting body (specifically an LED) is mounted, and a light diffusion unit 26b that is disposed in front of the light emitting substrate 26a and diffuses light from the light emitting body. And a cover portion 26c that covers the light emitting substrate 26a and the light diffusion portion 26b from the front of the gaming machine. The light diffused by the light diffusing unit 26b is irradiated to the front of the gaming machine, the side of the gaming machine, and the center of the gaming machine through the cover unit 26c.

  When a portion of the game area PE located behind the side lamp part 26 (hereinafter referred to as “rear area BE” for convenience) is to be viewed from the front of the side lamp part 26, the visual recognition is performed by the side lamp part 26. It will be disturbed. Therefore, at first glance, there is a concern that extending the side lamp part 26 to the game area PE side and expanding the occupied area of the side lamp part 26 may cause a decrease in the visibility of the game area PE.

  However, as described above, the side lamp portion 26 is disposed in front of the gaming machine with respect to the front glass panel 31, and the distance from the game board 80 to the side lamp portion 26 is increased, so that the rear region BE Visibility can be substantially secured. Specifically, when playing a game, the player's eyes are likely to be located in front of the central portion of the game area PE. For this reason, the player can visually recognize the rear area BE by avoiding the side lamp part 26 by moving his / her eyes to the side lamp part 26 side. Thereby, it is possible to improve the notification function and the presentation function given to the side lamp part 26, and to suppress the decrease in the visibility of the game area PE caused by the function.

  As described in detail above, by expanding the lateral width of the side lamp portion 26, it is easy to arrange the light emitter for production and the light emitter for notification side by side. That is, a notification light emitter is arranged near the outside of the pachinko machine 10 to facilitate confirmation by others such as a hall manager, and the production light emitter is arranged near the inside of the pachinko machine 10 (a player's side). It is possible to suitably exhibit the effect function. Thereby, the said alerting | reporting function and the production | presentation function are made to coexist suitably.

  As shown in FIG. 2 or FIG. 6, a transparent panel 41 is disposed between the side lamp portion 26 and the glass panel 31, and the transparent panel 41 closes the gap. As described above, in the configuration in which the side lamp portion 26 is disposed offset to the front of the gaming machine, when performing maintenance work, the front lamp portion 26 is hooked with a finger from the glass panel 31 side. There is a possibility that the door frame 14 is pulled forward of the gaming machine. If such an action is performed, inconvenience such as breakage or deformation may occur in the side lamp portion 26.

  In this regard, by adopting a configuration in which the transparent panel 41 prevents the insertion of a finger or the like into the gap, it is possible to reduce the inconvenience that the side lamp portion 26 is pulled. Therefore, the side lamp part 26 can be suitably protected while ensuring the visibility of the rear region BE.

  Referring to FIG. 2 again, below the window portion 21 in the front door frame 14, an upper bulging portion 28 and a lower bulging portion 29 that bulge to the near side are arranged in parallel vertically. Yes. The upper bulging portion 28 is provided with an upper pan 28 a that opens upward, and the lower bulging portion 29 is provided with a lower pan 29 a that also opens upward. The upper plate 28a has a function of temporarily storing game balls paid out from a payout device, which will be described later, and guiding the game balls to a game ball launching mechanism, which will be described later, while aligning them in a line. In addition, the lower tray 29a has a function of storing game balls that are surplus in the upper tray 28a.

  An operation switch 40 that is manually operated by the players is provided at a portion of the upper bulging portion 28 that is in front of the upper plate 28a (game ball storage area). The operation switch 40 is an operation device for a player to give a predetermined instruction during the progress of the game for the purpose of performing a predetermined effect on a display screen of a symbol display device, which will be described later. The effects executed based on the operation of the operation switch 40 will be described in detail later.

  A game ball launching handle 45 is provided at a position side by side with the lower bulging portion 29 so as to protrude to the front side. By operating the game ball launch handle 45, a game ball is launched from a game ball launch mechanism described later.

  As shown in FIG. 5, a passage forming unit 50 is attached to the back surface of the front door frame 14. The passage forming unit 50 is formed of synthetic resin, and includes a front door side upper tray passage 51 that leads to the upper tray 28a and a front door side lower tray passage 52 that leads to the lower tray 29a (see FIG. 2 and the like). It becomes. A receiving portion 53 that protrudes rearward and opens upward is formed at the upper corner portion of the passage forming unit 50, and the front door side upper plate passage 51 is partitioned by the partition wall 54 to the left and right. And an entrance portion of the front door side lower dish passage 52 are formed. The upstream side of the front door side upper dish passage 51 and the front door side lower dish path 52 are connected to a game ball distributing section described later, and the game balls that have entered the front door side upper dish path 51 are guided to the upper plate 28a, The game balls that have entered the door-side lower dish passage 52 are guided to the lower dish 29a.

  Next, the inner frame 13 will be described in detail with reference to FIG. FIG. 7 is a front view of the inner frame 13. In FIG. 7, the configuration in the game area of the pachinko machine 10 is omitted as in FIG.

  The inner frame 13 is mainly composed of a resin base 60 whose outer shape is substantially the same as that of the outer frame 11. Support metal fittings 71 and 72 are attached to the upper end portion and the lower end portion of the rotation base end side (left side in FIG. 7) of the front surface of the resin base 60. Further, bearing brackets 57 and 58 are provided on the rotation base end side (the right side in FIG. 5) on the back surface of the front door frame 14 so as to correspond to the support brackets 71 and 72. Shafts are formed on the support fittings 71, 72, and these shafts are inserted into the bearing holes of the bearing fittings 57, 58 of the front door frame 14 so that the front door frame 14 rotates relative to the inner frame 13. It is supported movably. That is, the support fittings 71 and 72 and the bearing fittings 57 and 58 constitute an assembly mechanism for the inner frame 13.

  A locking device 75 is provided on the front surface of the inner frame 13. The locking device 75 has a plurality of front door flange members 76 extending toward the front door frame 14. Corresponding to these front door collar members 76, a plurality of collar receiving members 59 extending toward the inner frame 13 are provided on the back surface of the front door frame 14 (see FIG. 3). When the front door brim member 76 is caught by the hook receiving member 59, the front door frame 14 is locked in a closed state. As shown in FIG. 4, the locking device 75 includes an inner frame collar member 77 extending rearward of the inner frame 13. These inner frame hook members 77 are hooked on the hook receiving member 19 of the outer frame 11, so that the gaming machine main part 12 is locked in a closed state with respect to the outer frame 11.

  Referring back to FIG. 7, a cylinder lock 78 for performing the unlocking operation of the locking device 75 is installed at the lower right corner of the resin base 60. The cylinder lock 78 is integrated with the locking device 75, and the tip portion (key hole portion) is exposed to the front of the pachinko machine 10 through the hole provided in the front door frame 14. Turning the key inserted into the key hole of the cylinder lock 78 to the right releases the locking of the front door frame 14 with respect to the inner frame 13, and turning the key to the left releases the locking of the inner frame 13 with respect to the outer frame 11. .

  A game board housing portion 61 for housing the game board 80 is formed at a substantially central portion on the front surface of the resin base 60. The game board accommodating portion 61 is recessed behind the pachinko machine 10 to define an accommodation space for accommodating the game board 80, and the game board 80 attached to the resin base 60 is fitted in the accommodation space. It has become.

  The game board accommodating part 61 includes a flat counter plate part 62 that faces the back of the game board 80, and a peripheral wall part 63 that stands up from the counter plate part 62 in front of the gaming machine and extends along the periphery of the game board 80. It is configured. The counter plate portion 62 has a central opening 64 formed substantially at the center thereof, and has a substantially rectangular frame shape when the inner frame 13 is viewed from the front. The peripheral wall 63 is composed of an upper side wall 65, a lower side wall 66, a left side wall 67, and a right side wall 68 that are individually opposed to the upper, lower, left and right end surfaces of the game board 80, and the game board 80 as a whole. It has a ring shape surrounding it. It can be said that the peripheral wall 63 is formed so as to surround the central opening 64.

  The game board 80 includes a wooden plywood 80P and a cell sheet 80S that covers the front board surface of the plywood, and the front surface of the game board 80 is exposed to the front side of the resin base 60 through an open portion of the game board housing 61. ing. In the exposed portion, that is, the front surface of the game board 80, a game area PE in which game balls flow down is formed. As already described, the game area PE is covered with the glass panels 31 and 32. The rear glass panel 32 is arranged so that the gap with the front surface of the game board 80 is slightly larger than the diameter of the game ball, that is, the game ball flowing down the game area PE is front and back at the same location in the game area PE. It is arranged not to line up. Thereby, the ball blockage in the game area PE is suppressed. Note that the game board 80 is not limited to wooden, and may be made of synthetic resin.

  Hereinafter, the game board 80 (in particular, various configurations arranged in the game area PE) will be described with reference to FIG. FIG. 8A is a front view of the game board 80, and FIG. 8B is a cross-sectional view of the game board 80.

  The game board 80 is formed with a plurality of large and small openings penetrating in its own thickness direction (front-rear direction) by performing router processing. Each opening is provided with a general winning port 81, a variable winning device 82, operating ports 83a and 83b, a through gate 84, a variable display unit 85, a main display unit 90, and the like. When game balls enter the general winning port 81, the variable winning device 82, and the operation ports 83a and 83b, the game balls are detected by a detection switch described later, and a predetermined number of award balls are paid out based on the detection result. The In addition, an out port 86 is provided at the lowermost part of the game board 80, and game balls that have not entered various winning ports etc. are discharged from the game area PE through the out port 86.

  In addition, in the game board 80, a number of nails 87 are implanted in order to disperse and adjust the flow path of the game ball as appropriate, and various members (functions) such as a windmill are arranged. By various configurations such as the nail 87 and the windmill, the flow path of the game ball is differentiated and adjusted so that the winning to the above-described general winning opening 81 or the like occurs with an appropriate probability.

  The variable winning device 82 is normally in a closed state in which a game ball cannot be won or difficult to win, and is switched to a predetermined open state in which a game ball is easy to win in the case of a big hit. As a release mode of the variable winning device 82, a predetermined time (for example, 30 seconds) or a predetermined number (for example, 10) of winnings is regarded as one round, and the variable winning device 82 is opened by a plurality of rounds (for example, 15 rounds). It is set to be repeated as the upper limit.

  The variable display unit 85 is disposed at the upper center of the game board 80, and the operation ports 83a and 83b are disposed below the variable display unit 85. More specifically, the operation ports 83a and 83b are arranged side by side with the operation port 83a on the upper side and the operation port 83b on the lower side. The lower working port 83b is provided with an electric accessory as a guide piece (support piece) composed of a pair of left and right movable pieces. The electric accessory is in a closed state (unsupported state or non-guided state) in which it is impossible or difficult to enter the operation port 83b, and an open state (supported state) in which the game ball can easily enter the closed state. Or a guide state), and when the lottery based on the winning to the through gate 84 is won, the main controller controls the open state. As the opening / closing mode of the electric accessory, the low frequency support mode set so that the winning frequency to the lower operation port 83b is lower than the upper operation port 83a, and the lower operation mode 83a than the upper operation port 83a. The high-frequency support mode is set so that the winning frequency for the operating port 83b is high, and it is low when a predetermined winning result is obtained by a lottery based on entering the operating ports 83a and 83b. The frequency support mode is shifted to the high frequency support mode.

  The variable display unit 85 and the operation ports 83a and 83b are portions that control game play, and the player's attention is likely to be gathered. By arranging the variable display unit 85 and the operation ports 83a and 83b side by side in the center of the gaming machine, the movement amount of the line of sight between the two is suppressed, which contributes to the reduction of the burden on the player's eyes.

  The main display section 90 is provided on a decorative member disposed along the outer edge on the lower side of the game area PE. The decorative member extends from the surface of the game board 80 to the front of the pachinko machine 10. More specifically, the front surface of the decorative member is opposed to the glass panel 32 provided on the front door frame 14 in order to make the game area PE visible from the front of the pachinko machine 10. The distance between them is narrower than that of one game ball. This prevents the game ball from falling in front of the front surface of the decorative member.

  A main display unit 90 is provided so as to be exposed from the front surface of the decorative member. That is, the main display unit 90 is visible from the front of the pachinko machine 10 through the glass unit 30 of the front door frame 14, and the game ball is prevented from falling in front of the main display unit 90. Yes.

  Although the detailed description by illustration is omitted, the main display unit 90 includes a segment display, and the segment display includes an operation port result display unit, an accessory result display unit, and an upper operation port 83a. A reserved number display part, a reserved number display part for the lower operation port 83b, and a reserved number display part for the through gate 84 are provided.

  The working port result display section has a display region for the upper working port and a display region for the lower working port in a one-to-one correspondence with each working port 83a, 83b. The result of the internal lottery performed based on the winning to the mouth 83a or the lower operation port 83b is clearly shown. In this case, in the same display area, the display of variable display (variable display) is performed by sequentially turning on and off each display segment using a winning at the operation ports 83a and 83b as a trigger. As a result, the result of the internal lottery performed based on the winning prize is clearly shown. That is, the lottery result based on the winning for the upper working port 83a is clearly shown in the display area for the upper working port, and the lottery result based on the winning for the lower working port 83b is clearly shown in the display area for the lower working port. .

  The accessory result display unit is a display unit for clearly indicating the result of the internal lottery performed based on the winning to the through gate 84. In this case, in the result display section for an accessory, a variable display (or variable display or switching display) is performed by sequentially turning on and off each display segment using a winning at the through gate 84 as a trigger. As a result of stopping the variable display, the result of the internal lottery performed based on the winning to the through gate 84 is clearly indicated by the display. When the result of the internal lottery based on the winning to the through gate 84 is a winning result corresponding to the transition to the state where the electric character is released, a predetermined stop result is displayed on the result display section for the accessory and the variable display After is stopped, it shifts to the electric utility open state. In the electric combination open state, the electric combination 83c provided in the lower working port 83b is opened in a predetermined manner.

  In addition, the number of times that the game ball has passed through the operation ports 83a and 83b is reserved up to 4 times, and the number of reservations is displayed by the reservation number display section for each operation port. Similarly, the number of times that the game ball has passed through the through gate 84 is reserved up to a maximum of four times, and the reserved number is displayed on the through gate display number display section.

  The variable display unit 85 includes a symbol display device 94 that variably displays symbols with a winning in the operation ports 83a and 83b as a trigger. The symbol display device 94 is configured as a liquid crystal display device including a liquid crystal display (display screen 94a), and the display content is controlled by a display control device described later. Specifically, on the display screen 94a, symbols are displayed side by side in the upper, middle, and lower levels, and these symbols are variably displayed as they are scrolled in the horizontal direction. When a big hit occurs, a predetermined combination of symbols is stopped and displayed on a preset active line, and a transition is made to a special gaming state. The display mode on the display screen 94a may be changed as follows. That is, the symbols may be displayed side by side on the left, middle, and right, and the symbols may be displayed in a variable manner by scrolling up and down.

  Further, the variable display unit 85 includes a center frame 95 formed so as to surround the symbol display device 94, and it is avoided that the game ball flowing down the game area PE by the center frame 95 collides with the symbol display device 94. Has been.

  Here, with reference to FIG.8 (b), the cell sheet 80S attached to the plywood 80P of the game board 80 is demonstrated supplementarily. The cell sheet 80S is fixed with an adhesive such that a resin sheet 80aS formed of a light-transmitting resin material, for example, Cavloid (registered trademark) or the like, is on the front side, and the lens holo film 80bS is on the back side. The lens holo film 80bS can be seen through the resin sheet 80aS.

  On the back surface of the resin sheet 80aS, a pattern or the like related to the model of the pachinko machine 10 is drawn or colored by offset printing. The design of the pachinko machine 10 is improved by this pattern or the like.

  The lens holofilm 80bS includes a PET lens embossed film and a single-side coated paper on which aluminum vapor deposition has been performed in order from the front side, and both of them are fixed by a two-component acrylic adhesive. The PET lens embossed film has a plurality of semicircular lens portions arranged vertically and horizontally, and when the gaming board 80 is viewed from the front side of the gaming machine, the impression that the gaming board 80 has depth is provided. It is easier to give to players.

  In particular, by making the outline of the picture displayed on the cabloid clear, it is possible to prevent the feeling of depth from fading. In addition, a greater sense of depth is achieved by using more cold-colored ink than warm-colored ink for the pattern.

  As already described, the side lamp portion 26 provided on the front door frame 14 has a function of emitting light as if the portion facing the center side of the gaming machine is emitting light. Part of the light emitted from the side lamp portion 26 reaches the cell sheet 80S of the game board 80, and is reflected to the front side of the game machine by the lens holo film 80bS (see the one-dot chain line in FIG. 6).

  Thereby, it is as if the game board 80 itself is emitting light to the player, or as if light from a light emitter disposed behind the game board 80 is irradiated through the game board 80. It is possible to impress. In particular, in the lens holo film 80bS, by using a large number of semicircular lens portions, it is possible to make an illusion that the player has more light sources than actual light sources.

  In the present embodiment, the PET lens embossed film has a semicircular lens portion. However, the present invention is not limited to this, and may have a rectangular lens portion. In the present invention, various depths can be expressed according to the distance from the center of the lens unit, whereas a uniform lens depth can be expressed by adopting a square lens unit.

  Referring again to FIG. 7, below the game board housing portion 61 (game board 80) in the resin base 60, a game ball that launches a game ball to the game area PE based on the operation of the game ball launch handle 45. A firing mechanism 110 is provided. The game ball launching mechanism 110 includes a solenoid 111 that launches a game ball placed at a predetermined launch standby position, a launch rail 112 that defines the launch direction of the game ball launched by the solenoid 111, and a game at the launch standby position. A ball feeding device 113 for supplying a ball and a base plate 114 on which these various components 111 to 113 are mounted are provided as main components, and the base plate 114 is attached to the resin base 60 via a reinforcing plate described later. ing.

  The firing rail 112 is fixed to the base plate 114 in an inclined state so as to be inclined upward toward the game board 80 side. A ball stopper that holds the game ball supplied from the ball feeding device 113 at the above-described firing standby position is disposed at a position closer to the downstream end portion (that is, the lower end portion) of the firing rail 112. The solenoid 111 is arranged at a position further downstream than the ball stopper.

  The solenoid 111 is electrically connected to a power source / launch control device described later. Based on the output of the electrical signal from the power supply / launch control device, the output shaft of the solenoid 111 reciprocates in the expansion / contraction direction, so that the game ball placed at the launch standby position is on the game board 80 side, more specifically, the game. It is driven out toward the guide rail 100 mounted on the board 80.

  The guide rail 100 partitions the game area PE together with a game area partition member, which will be described later, so that the outer shape of the game area PE is substantially circular. In addition, the guide rail 100 includes an inner rail 101 and an outer rail 102 arranged so as to face each other with a gap slightly larger than the diameter of the game ball, and a single guide passage 103 is defined by both the rails 101 and 102. Is formed. The guide passage 103 includes an inlet portion 104 that is opened to the tip side (obliquely downward) of the firing rail 112, and an outlet portion 105 that is located above the gaming area PE. The game ball fired based on the operation of the solenoid 111 is guided to the game area PE by moving in the order of the firing rail 112 → the guide rail 100 (the entrance portion 104 → the exit portion 105). In the game board 80, a reversal prevention member 106 for preventing the reversal of the game ball reaching the game area PE into the guide passage 103 is attached to the front side of the exit portion 105, specifically near the tip of the inner rail 101. Thus, it is possible to prevent the subsequent launch of the game ball from being hindered by the game ball that has reached the game area PE first.

  Each of the rails 101 and 102 constituting the guide rail 100 has an arc shape centered at a substantially central portion of the game area PE. For this reason, the game ball passing through the guide passage 103 is likely to move (slide or roll) along the outer rail 102, that is, in contact with the outer rail 102 due to the centrifugal force generated by itself.

  The guide rail 100 is operated when the game ball launch handle 45 is operated to such an extent that the game ball can reach the game area PE, that is, when the operation amount of the game ball launch handle 45 exceeds the first specified amount. In addition, the game ball launched from the firing rail 112 is formed so as to land on the entrance portion 104 of the guide rail 100, specifically, on the outer rail 102 at a specific site located on the extension of the firing rail 112.

  The outer rail 102 is formed so that the direction of the tangent at the specific portion is substantially the same as the rail direction of the firing rail 112. By aligning the direction of movement of the launched game balls and the direction of the tangent at the specific part, the impact caused by the landing of the game balls is reduced and the rebound of the game balls is suppressed, and the game balls are smoothly moved by the guide rail 100. Is possible.

  As shown in FIG. 8, the outer rail 102 includes a plurality of fixing pins 102 a as fixing means for fixing the outer rail 102 to the game board 80. The fixed pin 102a is disposed along the outer rail 102, and the specific portion is set between the fixed pins 102a. As a result, it is possible to allow a slight bending deformation (elastic deformation) of the outer rail 102 at the specific part, and to reduce the impact when the game ball lands on the specific part.

  As shown in FIG. 7, the guide rail 100 and the launch rail 112 are arranged such that the entrance portion 104 of the guide rail 100 and the tip portion of the launch rail 112 face each other with the lower end edge of the game board 80 interposed therebetween. ing. That is, both the rails 100 and 112 are arranged such that the entrance portion 104 of the guide rail 100 and the tip portion of the firing rail 112 are shifted left and right in the vicinity of the lower end edge of the game board 80. Thus, a gap of a predetermined interval is formed between the entrance portion 104 of the guide rail 100 and the firing rail 112 while bringing both rails 100 and 112 close to the lower end edge of the game board 80.

  A foul ball passage 55 (see FIG. 3) is disposed below the gap formed in this way. The foul ball passage 55 is integrally formed with the passage formation unit 50 of the front door frame 14. If the game balls launched from the game ball launching mechanism 110 do not reach the game area PE and return as foul balls in the guide passage 103, the foul balls enter the foul ball passage 55 through the gap. It becomes. The foul ball path 55 communicates with the front door side lower dish path 52, and the game balls that have entered the foul ball path 55 are discharged to the lower dish 29a shown in FIG. This suppresses interference between the foul ball and the next game ball to be launched.

  In addition, the resin base 60 is provided with a plurality of lock devices that can be switched between a locked state in which the game board 80 cannot be removed from the game board housing portion 61 and an unlocked state in which the game board 80 is allowed to be removed. It has been. The locking device has an abutting portion that abuts against the front surface of the game board 80 in the locked state, and the abutting portion abuts against the front surface of the game board 80, thereby moving the game board 80 toward the front door frame 14 side. The displacement will be suppressed. The holding strength of the game board by the locking device is set to be higher than the holding strength of the lever member 23 that fixes the glass unit 30 to the frame body 20.

  A through hole that penetrates the resin base 60 in the front-rear direction is formed on the left side of the firing rail 112 (specifically, the side that supports the front door frame 14) in the resin base 60, and covers the through hole. A passage forming member 121 is disposed. The passage forming member 121 is screwed to the resin base 60 and has a main body side upper dish path 122 and a main body side lower dish path 123. The upstream side of the main body side upper dish passage 122 and the main body side lower dish passage 123 communicates with a game ball distributing section described later. A receiving portion 53 (see FIG. 3) of the passage forming unit 50 attached to the front door frame 14 enters below the passage forming member 121, and the front door side is below the main body side upper dish passage 122. An upper plate passage 51 is disposed, and a front door side upper plate passage 51 is disposed below the main body side lower plate passage 123 (see FIG. 7).

  In the resin base 60, a shutter 124 that restricts the outflow of game balls from the main body side upper dish path 122 and the main body side lower dish path 123 is provided below the passage forming member 121. The shutter 124 is supported by the resin base 60 in a state where the shutter 124 can be switched between a blocking position where the outlet portions of both passages are narrowed to prevent the gaming ball from flowing out and an allowable position where the gaming ball is allowed to flow out. Further, a biasing member that biases the shutter 124 toward the blocking position is attached to the resin base 60. When the front door frame 14 is opened with respect to the inner frame 13, the shutter is driven by the biasing force of the biasing member. 124 is configured to remain in the blocking position. Thereby, when the front door frame 14 is opened in a state where the game balls are stored in the main body side upper tray passage 122 or the main body side lower tray passage 123, the disadvantage that the stored balls spill out is avoided. . In contrast, when the front door frame 14 is closed, the shutter 124 is pushed back to the allowable position against the urging force by the receiving portion 53 provided in the passage forming unit 50 of the front door frame 14. In this state, the main body side upper tray passage 122 and the front door side upper tray passage 51 communicate with the main body side lower tray passage 123 and the front door side lower tray passage 52, respectively, and the movement of the game ball is permitted. Become.

  Next, the back configuration of the inner frame 13 (the resin base 60 and the game board 80) will be described with reference to FIG. FIG. 9 is a rear view of the inner frame 13.

  A bearing fitting 132 is attached to the rotation base end side (the right side in FIG. 9) on the back surface of the resin base 60. A bearing portion 133 is formed on the bearing bracket 132 so as to be separated from each other in the vertical direction, and the back pack unit 15 is rotatably attached to the inner frame 13 by these bearing portions 133. A plurality of fixing levers 134 for fixing the back pack unit 15 to the inner frame 13 are provided on the back surface of the resin base 60.

  As already described, a central opening that penetrates in the thickness direction of the resin base 60 and opens to the back side of the resin base 60 in the bottom portion of the game board housing portion 61 (that is, the opposing plate portion 62) in the resin base 60. 64 is formed, and the central opening 64 is covered from the front side of the inner frame 13 by the game board 80 accommodated in the game board accommodation part 61. Various components such as a control device are mounted on the back of the game board 80, and these various components are exposed to the back side of the inner frame 13 through the central opening 64. Here, the configuration of the back surface of the game board 80 will be described in detail with reference to FIG. FIG. 10 is a perspective view of the game board 80 as seen from the rear.

  A synthetic resin pedestal member 141 on which the variable display unit 85 (see FIG. 8) is mounted on the game board 80 is fixed to the back of the game board 80. The pedestal member 141 has a substantially box shape opened to the game board 80 side, and covers almost the entire rear surface of the game board 80. A part of the base member 141 protrudes to the back side of the resin base 60 through the central opening 64 of the resin base 60, and the symbol display device 94 (see FIG. 8) described above with respect to the protruding portion and the symbol display thereof. A display control device for driving the device 94 is attached. The symbol display device 94 and the display control device are arranged so that the symbol display device is on the front side and the display control device is on the rear side in the front-rear direction (thickness direction of the resin base 60). Furthermore, the game board 80 is equipped with an audio lamp control device unit 142 so as to be positioned behind the display control device. The sound lamp control device unit 142 includes a sound lamp control device 143 and a mounting table 144, and the sound lamp control device 143 is mounted on the mounting table 144.

  The sound lamp control device 143 includes a sound lamp control board that controls sound, lamp display, and display control device in accordance with instructions from a main control device to be described later, and the sound lamp control board is made of a transparent resin material or the like. It is configured to be accommodated in a substrate box 145.

  A main controller unit 160 is provided below the sound lamp controller unit 142 so as to cover the base member 141 from behind. The main controller unit 160 includes a synthetic resin mounting base 161 fixed to the back of the game board 80 and a main control unit 162 mounted on the mounting base 161. The main controller 162 includes a main control board having a function (main control circuit) that controls the main control of the game and a function (power failure monitoring circuit) that monitors the power source, and the main control board is made of a transparent resin material. It is configured to be accommodated in a substrate box 163 made of, for example.

  The board box 163 includes a substantially rectangular parallelepiped box base (front case body) and a box cover (back case body) that covers an opening of the box base. The box base and the box cover are connected so as not to be unsealed by a box sealing portion 164 as sealing means, whereby the substrate box 163 is sealed. A plurality of box sealing portions 164 are provided on the short side portion of the substrate box 163, and at least one of them is used for sealing processing.

  Any configuration can be applied to the box sealing portion 164 as long as the box base and the box cover are coupled so as not to be opened. However, by inserting a locking pin into the locking hole that forms the box sealing portion 164, the box sealing portion 164 can be applied. The base and the box cover are coupled so as not to be opened. The sealing process by the box sealing unit 164 prevents unauthorized opening after the sealing, and makes it possible to detect such a situation early and easily even if the unauthorized opening is performed. Even after opening, the sealing process can be performed again. That is, the sealing process is performed by inserting a locking pin into at least one locking hole portion among the plurality of box sealing portions 164. When the substrate box 163 is opened, such as when a failure occurs in the accommodated main control board or when the main control board is inspected, a connecting portion between the box sealing portion into which the locking pin is inserted and the substrate box 163 main body. Disconnect. As a result, the box base and the box cover of the substrate box 163 are separated, and the internal main control substrate can be taken out. Thereafter, when the sealing process is performed again, a locking pin is inserted into another locking hole. If the history of opening the substrate box 163 is left in the substrate box 163, it can be easily found that the unauthorized opening has been performed by looking at the substrate box 163.

  The board box 163 and the mounting base 161 are connected by a base seal part 165 so that they cannot be opened. Specifically, the pedestal sealing portion 165 has a locking hole portion and a locking pin similarly to the box sealing portion 164, and the locking pin is inserted into the locking hole portion so that the board box 163 and The mounting base 161 is coupled so as not to be separable. This makes it easier to grasp the fact that the substrate box 163 has been illegally removed.

  The portion of the pedestal member 141 that faces the back of the game board 80 corresponds to the game board openings of the general winning port 81, variable winning device 82, upper operating port 83a, and lower operating port 83b, and on the downstream side. A collection passage that collects in one place is formed. Thereby, all the game balls won in the general winning opening 81 and the like are gathered below the game board 80 through the collection passage. That is, the pedestal member 141 is provided with a function of collecting game balls won in various winning openings.

  A discharge passage, which will be described later, is arranged below the game board 80, and the game balls gathered below the game board 80 by the collection passage are led out into the discharge passage. Similarly, the out port 86 leads to the discharge passage, and a game ball that has not won any winning port is led out into the discharge passage through the out port 86.

  Further, in the collection passage, a winning port switch for detecting a game ball won in the general winning port 81 on the front side of the game board 80, a count switch for detecting a game ball won in the variable winning device 82, and an operation port 83a, An operating port switch for detecting a game ball entering 83b is mounted, and a winning detection mechanism is constituted by these various switches. Furthermore, gate switches for detecting game balls passing through the through gate 84 are provided on the left and right sides of the variable display unit 85 in the base member 141. These various switches are electrically connected to the main control device 162, and the detection information by each switch is output to the main control device 162.

  Next, the back pack unit 15 will be described with reference to FIGS. 4 and 11. FIG. 11 is a front view of the back pack unit 15.

  As shown in FIG. 4, the inner frame 13 is covered from behind by the back pack unit 15. As shown in FIG. 11, the back pack unit 15 includes a back pack 201, and a payout mechanism unit 202, a discharge passage board, and a control device assembly unit 204 are attached to the back pack 201.

  The back pack 201 is formed of a synthetic resin having transparency, and includes a base portion 211 to which the payout mechanism portion 202 and the like are attached, and a protective cover portion 212 that protrudes rearward from the pachinko machine 10 and has a substantially rectangular parallelepiped shape. The protective cover portion 212 has a shape in which left and right side surfaces and an upper surface are closed and only a lower surface is opened, and has a size sufficient to surround at least the variable display unit 85.

  The base portion 211 is provided with an external output terminal plate 213 at the upper right portion thereof. Various output terminals are provided on the external output terminal plate 213, and various signals are output through these output terminals to the management control device (hall computer HC) on the game hall side. Further, the base portion 211 is provided with a pair of upper and lower latch pins 214 at the right end when viewed from the rear of the pachinko machine 10, and the latch pins 214 are inserted through the bearing portions 133 provided on the inner frame 13. The back pack unit 15 is supported so as to be rotatable with respect to the inner frame 13. The base portion 211 is formed with a plurality of insertion portions 215 through which the fixing levers 134 provided in the inner frame 13 are inserted, and the base portion 211 is rearward of the base portion 211 in a state where the fixing levers 134 are inserted through the insertion portions 215. The back pack unit 15 is fixed to the inner frame 13 by contact with the inner frame 13.

  In the base portion 211, a payout mechanism portion 202 is disposed so as to bypass the protective cover portion 212. The payout mechanism 202 is provided with a tank 221 that is arranged at the top of the back pack 201 and that opens upward, and game balls supplied from the island facilities of the game hall are sequentially replenished to the tank 221. The A tank rail 222 that is gently inclined toward the downstream side is connected to the lower side of the tank 221, and a case rail 223 that extends in the vertical direction is connected to the downstream side of the tank rail 222. A payout device 224 is provided at the most downstream portion of the case rail 223. The game balls paid out from the payout device 224 are supplied to the game ball distribution unit 225 provided in the base portion 211 of the back pack 201 through a payout passage (not shown) provided on the downstream side of the payout device 224.

  The game ball distribution unit 225 has a function of distributing the game balls paid out from the payout device 224 to any one of the upper plate 28a, the lower plate 29a, and a discharge passage described later, and the inner opening is the main body described above. It is formed so that it communicates with the upper plate 28a through the side upper plate passage 122 and the front door side upper plate passage, and the outer opening communicates with the lower plate 29a through the main body side lower plate passage 123 and the front door side lower plate passage. Has been.

  At the lower end portion of the base portion 211, the discharge passage board and the control device collective unit 204 are attached so as to sandwich the lower end portion in the front-rear direction. In the discharge passage board, a discharge passage opened rearward is formed on a surface facing the control device assembly unit 204, and an open portion of the discharge passage is closed by the control device assembly unit 204. The discharge passage is formed so as to discharge the game ball to the island facility or the like of the game hall, and the game ball led to the discharge passage from the recovery passage described above passes through the discharge passage to the outside of the pachinko machine 10. Discharged.

  The control device assembly unit 204 has a horizontally long mounting base 241, and a payout control device 242 and a power supply / launch control device 243 are mounted on the mounting base 241. The payout control device 242 and the power supply / launch control device 243 are arranged so as to overlap each other so that the payout control device 242 is behind the pachinko machine 10.

  In the payout control device 242, a payout control board for controlling the payout device 224 is accommodated in the board box 244, and a state return switch 245 provided on the payout control board projects out of the board box 244. For example, when the state return switch 245 is pressed when a payout error occurs, such as a ball jam in the payout device 224, the ball jam is eliminated.

  The power source / launch control device 243 includes a power source / launch control board housed in the board box 246, and a predetermined power source required for various control devices and the like is generated and output by the board. Control of the launch of the game ball accompanying the operation of the firing handle 45 is performed. Further, the power source / launch control device 243 is provided with a power switch 247. By operating the power switch 247, the power of the pachinko machine 10 can be switched to the on state (on state) or the shut off state (off state).

  Here, this pachinko machine 10 has a function for storing various data, and even if a power failure occurs, it retains the state at the time of the power failure and returns to the state at the time of the power failure at the time of recovery from the power failure. It can be done. For example, when the power supply is shut down by a normal procedure as in the case of a game hall being closed, the state before the shutdown is stored and held. The main controller 162 is provided with a RAM erase switch 166. When power is turned on while pressing the RAM erase switch 166, the RAM data is initialized.

<Electric configuration of pachinko machine 10>
Next, the electrical configuration of the pachinko machine 10 will be described based on the block diagram of FIG.

  An MPU 402 is mounted on a main control board 401 provided in the main controller 162. The MPU 402 is a ROM 403 storing various control programs executed by the MPU 402 and fixed value data, and a memory for temporarily storing various data when executing the control program stored in the ROM 403. The RAM 404 is an element incorporating an interrupt circuit, a timer circuit, a data input / output circuit, various counter circuits as a random number generator, and the like. Note that a part of the functions of the MPU 402, for example, the function of the ROM 403 and the function of the RAM 404 may be provided as separate elements.

  The MPU 402 is provided with an input port and an output port. On the input side of the MPU 402, a power failure monitoring board 405, a payout control device 242 and various detection sensors 311a to 311e provided in the main control device 162 are connected. In this case, the power failure monitoring board 405 is connected to the power supply / emission control device 243, and power is supplied to the MPU 402 via the power failure monitoring board 405. In addition, as part of the various detection sensors 311a to 311e, various winning-corresponding winning portions (payout corresponding entering portions) such as a general winning opening 81, a variable winning device 82, an upper operating opening 83a, a lower operating opening 83b, and a through gate 84 are provided. ) Are connected to each other, and based on detection information (detection signals) from these detection sensors, the MPU 402 of the main controller 162 makes a winning determination (entrance determination) to each pitching section. Is called. In addition, the MPU 402 executes a lottery occurrence lottery based on the winnings to the upper working port 83a and the lower working port 83b, and executes the support generating lottery based on the winnings to the through gate 84.

  On the output side of the MPU 402, a power failure monitoring board 405, a payout control device 242 and an audio lamp control device 143 are connected. For example, a payout ball command is output to the payout control device 242 based on a winning determination result to the winning-corresponding winning portion such as the operation ports 83a and 83b described above. In this case, when outputting the prize ball command, the command information storage area 425 of the ROM 403 is referred to. When a winning to the general winning opening 81 is specified, a winning ball command corresponding to paying out 10 gaming balls is output, and when a winning to the variable winning device 82 is specified, 15 gaming balls are output. When the winning ball command corresponding to the payout of the game is output and the winning to the upper operating port 83a is specified, the winning ball command corresponding to the payout of the three game balls is output and the winning to the lower operating port 83b is received. When specified, a prize ball command corresponding to the payout of four game balls is output.

  Various commands such as a change command, a type command, a change end command, an opening command, and an ending command are output to the sound lamp control device 143 from the main control device 162. In this case, the command information storage area 425 of the ROM 403 is referred to when these various commands are output. Details of these various commands will be described later. Each command is configured as information of a predetermined number of bytes, and various information is included as information of the predetermined number of bytes.

  Further, on the output side of the MPU 402, a variable winning drive unit 82c that opens and closes the opening / closing door of the variable winning device 82, an electric combination driving unit 83d that opens and closes the electric combination 83c of the lower operation port 83b, and a main display unit. 90 is connected. Various driver circuits are provided on the main control board 401, and the MPU 402 performs drive control of various drive units through the driver circuits.

  That is, in the opening / closing execution mode, drive control of the variable winning drive unit 82c is executed in the MPU 402 so that the special winning opening 82a is opened and closed. In addition, when the support lottery of the electric combination 83c is won, the MPU 402 performs drive control of the electric combination drive unit 83d so that the electric combination 83c is opened and closed. In addition, display control of the main display unit 90 is executed by the MPU 402.

  Furthermore, an external output terminal board 213 is connected to the output side of the MPU 402, and through this external output terminal board 213, information on the entrance to various entrances to the management control device (hall computer HC) on the game hall side. Information on the lottery results such as the jackpot and the jackpot is output. Thereby, it is possible to grasp the state and the like of the pachinko machine 10 by the hall computer HC.

  The power failure monitoring board 405 relays the main control board 401 and the power / fire control device 243. The power failure monitoring board 405 has a DC stable voltage of 24 volts, which is the maximum voltage output from the power / fire control device 243. The function to monitor is given. The payout control device 242 controls payout of prize balls and rental balls by the payout device 224 based on the prize ball command input from the main control device 162.

  The power / launch control device 243 is connected to, for example, a commercial power source (external power source) in a game hall or the like. Based on the external power supplied from the commercial power supply, necessary operating power is generated for each of the main control board 401, the payout controller 242 and the like, and the generated operating power is supplied through a predetermined power path. To do. The power supply / launch control device 243 is responsible for launch control of the game ball launch mechanism 110, and the game ball launch mechanism 110 is driven when predetermined launch conditions are met.

  The sound lamp control device 143 drives and controls the display lamp units 24 to 26 and the speaker unit 27 provided on the front door frame 14 based on various commands input from the main control device 162, and controls the display control device 500. It is something to control.

  The display control device 500 performs display control of the symbol display device 94 based on the command input from the sound lamp control device 143. In this case, the voice lamp control device 143 is based on various commands input from the main control device 162, and the symbol variation display mode (for example, presence / absence of reach and contents of reach effect) on the symbol display device 94 and the symbol The stop display mode (the combination of symbols to be finally stopped and displayed with the end of the variable display) is determined.

  Here, the configuration related to the variable display of symbols of each game time and the content of the variable display will be described. In the following description, FIG. 13 is referred to as appropriate. FIG. 13 is an explanatory diagram for explaining display contents on the display screen of the symbol display device.

  As shown in FIG. 6A, on the display screen 94a of the symbol display device 94, three symbol rows Z1, Z2, and Z3 of an upper stage, a middle stage, and a lower stage are set. Each of the symbol rows Z1 to Z3 includes a main symbol and a sub symbol arranged in a predetermined order. On the display screen 94a, the symbols of these symbol rows Z1 to Z3 are displayed in a variable manner so as to scroll in a predetermined direction (specifically, from right to left) with periodicity. In this case, nine types of main symbols “1” to “9” are arranged in descending order of numbers in the upper symbol row Z1, and one sub symbol is arranged between each main symbol. In the lower symbol row Z3, nine types of main symbols “1” to “9” are arranged in ascending numerical order, and one sub symbol is arranged between each main symbol. That is, the upper symbol row Z1 and the lower symbol row Z3 are composed of 18 symbols. On the other hand, in the middle symbol row Z2, nine types of main symbols “1” to “9” are arranged in ascending numerical order, and then between the main symbol “9” and the main symbol “1”. In addition, a main symbol “4” is additionally arranged, and one sub symbol is arranged between each main symbol. In other words, only the middle symbol row Z2 is composed of 20 symbols by arranging 10 main symbols.

  Further, as shown in FIG. 6B, the display screen 94a is configured such that 3 symbols are stopped and displayed for each symbol row, and as a result, a total of 9 symbols of 3 × 3 are stopped and displayed. It has come to be. Further, five effective lines, that is, a left line L1, a middle line L2, a right line L3, a right lowering line L4, and a right uppering line L5 are set on the display screen 94a. Then, the variable display stops in the order of the upper symbol row Z1 → the lower symbol row Z3 → the middle symbol row Z2, and a predetermined symbol combination (for example, a combination of symbols with the same numerals) is formed on any effective line. When the variation display of all the symbol rows Z1 to Z3 is finished in the state of being played, the big hit video is displayed as the occurrence of the normal jackpot result or the probability variation jackpot result.

  In view of the fact that the variable display of each symbol row is stopped as described above, the upper symbol row Z1 is the first symbol row (or the first symbol row), and the lower symbol row Z3 is the second symbol row (or the second symbol row). 2 symbol rows), the middle symbol row Z2 can be referred to as a third symbol row (or third symbol row).

  Of the above main symbols, the main symbols with odd numbers (1, 3, 5, 7, 9) correspond to “specific symbols”, and if a probable jackpot result occurs, for example, the same specific symbols The combination of is stopped and displayed. In addition, the main symbols with even numbers (2, 4, 6, 8) correspond to “non-specific symbols”. When a normal jackpot result occurs, for example, the combination of the same non-specific symbols is stopped and displayed. Is done.

  It should be noted that the manner in which the symbol variation display in the symbol display device 94 is not limited to the above, is arbitrary, the number of symbol columns, the direction of symbol variation display in the symbol row, the number of symbols in each symbol row, etc. Can be appropriately changed. For example, a plurality of symbol sequences may be set to be arranged side by side, and the direction of symbol variation display in the symbol sequence may be set to the vertical direction.

  In the lower part of the display screen 94a, more specifically, below the variable display area having the variable display area of the upper symbol sequence, the variable display area of the middle symbol, and the variable display area of the lower symbol, which are set individually, the hold display The area is set. In the hold display area, the hold number display for the upper working opening is displayed in such a manner that unit hold display areas of the same number as the maximum hold number when a game ball wins the upper working opening 83a are arranged in the horizontal direction. Reservation number display area Db for the lower operation opening that is divided and displayed so that the area Da and the unit reservation display area of the same number as the maximum reservation number when the game ball wins the lower operation opening 83b are arranged in the horizontal direction. And is composed of.

  Specifically, when the game ball is won in the upper operation port 83a, the maximum number of reservations is 4, and in correspondence with this, the upper unit operation hold number display area Da includes a first unit reservation display area. The second unit hold display area, the third unit hold display area, and the fourth unit hold display area are set. In addition, when the game ball wins the lower operation port 83b, the maximum number of reservations is four. Correspondingly, the lower operation port reservation number display region Db includes a first unit reservation display region, A unit hold display area, a third unit hold display area, and a fourth unit hold display area are set.

  For example, when the number of holds when the game ball is won in the upper operation port 83a is 1, a predetermined hold image is displayed only in the first unit hold display area, and the game ball is displayed in the upper operation port 83a. When the number of holds when winning is four, a predetermined hold image is displayed in all of the first unit hold display area to the fourth unit hold display area. Note that FIG. 13B illustrates a case where the number of reservations in the upper operation port 83a is three and the number of reservations in the lower operation port 83b is two.

<About various counters>
Next, the operation of the pachinko machine 10 configured as described above will be described.

  The MPU 402 uses lots of counter information during the game to perform jackpot occurrence lottery, setting the display of the main display unit 90, setting the symbol display of the symbol display device 94, and more specifically, the schematic diagram of FIG. As shown in FIG. 4, the jackpot random number counter C1 used for the lottery in which the jackpot is generated, the jackpot type counter C2 used for determining the jackpot type such as the probability variation jackpot result and the normal jackpot result, and the symbol display device 94 are changed. Use a reach random number counter C3 used for reach lottery, a random number initial value counter CINI used for setting an initial value of the jackpot random number counter C1, and a variation type counter CS for determining a variation display time in the symbol display device 94. It is said. Furthermore, the electric accessory release counter C4 used for the lottery to determine whether or not the electric accessory 83c of the lower operating port 83b is in the electric utility open state is used.

  Each of the counters C1 to C3, CINI, CS, and C4 is a loop counter that adds 1 to the previous value every time it is updated and returns to 0 after reaching the maximum value. Each counter is updated at short time intervals, and the updated value is appropriately stored in a lottery counter buffer 431 set in a predetermined area of the RAM 404. In the lottery counter buffer 431, information corresponding to the jackpot random number counter C1, the jackpot type counter C2 and the reach random number counter C3 is obtained as information storage means when a winning is made to the upper working port 83a or the lower working port 83b. Are stored in the reserved ball storage area 432.

  The holding ball storage area 432 includes a holding area RE including an upper working port holding area Ra and a lower working port holding area Rb, and an execution area AE. The reserved areas Ra and Rb include a first area Ra1 and Rb1, a second area Ra2 and Rb2, a third area Ra3 and Rb3, and a fourth area Ra4 and Rb4, and are connected to the upper working port 83a or the lower working port 83b. According to the winning history, the numerical information of the jackpot random number counter C1, the jackpot type counter C2 and the reach random number counter C3 stored in the lottery counter buffer 431 is held information, and any one of the areas Ra1 to Ra4, Rb1 to Rb4 Stored in Note that the hold information corresponds to special information.

  In this case, in the first area Ra1, Rb1 to the fourth area Ra4, Rb4, when the winning to the upper working port 83a or the lower working port 83b is continuously generated a plurality of times, the first areas Ra1, Rb1 → first Each numerical information is stored in time series in the order of 2 area Ra2, Rb2 → third area Ra3, Rb3 → fourth area Ra4, Rb4. Thus, by providing each of the four areas Ra1 to Ra4 and Rb1 to Rb4, a maximum of four game ball winning histories to the upper operating port 83a or the lower operating port 83b are held and stored. It has become. Further, the reserved ball storage area 432 is provided with a total number-of-holds storage area, and the total number-of-holds storage area specifies the number in which the winning history for the upper operating port 83a or the lower operating port 83b is stored in a stored state. To store information.

  The execution area AE is an area for moving each value stored in the first areas Ra1 and Rb1 of the holding area RE when starting the variable display on the main display unit 90, and at the start of one game round. Based on various numerical information stored in the execution area AE, determination of whether or not is made is performed.

  For details of each counter, the jackpot random number counter C1 is configured such that, for example, 1 is added in order within a range of 0 to 299, and after reaching the maximum value (that is, 299), it returns to 0. In particular, when the jackpot random number counter C1 makes one round, the value of the random number initial value counter CINI at that time is read as the initial value of the jackpot random number counter C1. The random number initial value counter CINI is a loop counter similar to the jackpot random number counter C1 (value = 0 to 599). The big hit random number counter C1 is periodically updated and stored in the reserved ball storage area 432 of the RAM 404 at the timing when the game ball wins the upper operation port 83a or the lower operation port 83b.

  The value of the random number for winning the jackpot is stored as a success / failure table (availability information group) in a success / failure table storage area 421 as a success / failure information group storage means in the ROM 403. Here, the contents of the success / failure table will be described.

  In the success / failure table, address information composed of binary number information and jackpot numerical value information composed of binary number information are set in a one-to-one correspondence. Specifically, ten types of address information expressed in decimal numbers from “1” to “10” are set, and jackpot value information is expressed in decimal numbers as “7”, “36”, “67”. , “100”, “131”, “164”, “195”, “223”, “241”, “272” are set, and the address information and the jackpot value information are in a one-to-one relationship. It is associated. The numerical value of each jackpot numerical value information is included in “0” to “299”, which is the numerical range of the random number information that can be updated in the jackpot random number counter C1.

  Here, in the pachinko machine 10, a low probability mode (low probability state) and a high probability mode (high probability state) are set as the lottery modes in the success / failure lottery means. The number of jackpot numerical information referred to in the low probability mode is different from the number of jackpot numerical information referred to in the high probability mode, and the former is smaller than the latter. Specifically, in the low probability mode, only the jackpot value information whose address information is “1” is referred to in the lottery lottery, and in the high probability mode, the jackpot number information corresponding to all the address information is determined in the lottery lottery. Referenced. In other words, there is one piece of numerical information for winning the jackpot in the low probability mode, and there are ten pieces of numerical information in the high probability mode, which is more than in the low probability mode. As a result, the probability of winning the jackpot in the low probability mode is 1/300, whereas the probability of winning the jackpot in the high probability mode is 1/30, and the high probability mode is a jackpot than the low probability mode. The probability of winning is increased. If the winning probability in the high probability mode is higher than that in the low probability mode, the number and value of the random numbers to be won are arbitrary.

  The jackpot type counter C2 is configured so that 1 is added in order within a range of 0 to 29, and after reaching the maximum value, it returns to 0. The big hit type counter C2 is periodically updated and stored in the reserved ball storage area 432 of the RAM 404 at the timing when the game ball wins the upper operation port 83a or the lower operation port 83b.

  Here, in the pachinko machine 10, (1) a winning / no-win lottery mode in the corresponding lottery means after the opening / closing execution mode ends, and (2) a support mode in the electric accessory 83c of the lower working port 83b after the opening / closing execution mode ends. Different types of jackpot results are set by making a difference between the two conditions. As above-mentioned lottery mode, the low probability mode and the high probability mode are set as described above.

  As a support mode, the frequency with which the electric accessory 83c of the lower working port 83b is opened per unit time when compared in a situation where the game ball is continuously being fired in the same manner with respect to the game area PE. The low-frequency support mode (the low-frequency support state or the low-frequency guide state) and the high-frequency support mode (the high-frequency support state or the high-frequency guide state) are set so that is relatively high.

  Specifically, in the low-frequency support mode and the high-frequency support mode, the probability of winning the power combination open state in the electric combination release lottery using the electric combination release counter C4 is the same (for example, both 4/5) However, in the high frequency support mode, the number of times that the electric accessory 83c is in the open state when the electrified open state is won is set more than in the low frequency support mode. The time is set longer. In this case, in the high frequency support mode, when the electrified open state is won and the open state of the electric accessory 83c occurs a plurality of times, the closed state from the end of one open state until the next open state is started The time is set shorter than one opening time. Furthermore, in the high-frequency support mode, a shorter time is selected as the reserved time that is secured after the next electric character opening lottery is performed after the electric character object opening lottery is performed than in the low-frequency support mode. Is set to be.

  As described above, in the high frequency support mode, there is a higher probability of winning the lower working port 83b than in the low frequency support mode. In other words, in the low frequency support mode, there is a higher probability that a prize will be generated in the upper operating port 83a than in the lower operating port 83b. However, in the high frequency support mode, the lower operating port 83b is connected to the lower operating port 83b. The probability of winning a prize increases. When a winning is made to the lower operating port 83b, a predetermined number of game balls are paid out. Therefore, in the high-frequency support mode, the player plays a game while not reducing the number of possessed balls so much. be able to.

  In addition, the configuration for increasing the frequency of the electric power release state per unit time in the high frequency support mode is not limited to the above, for example, lottery for electric power object release lottery than in the low frequency support mode It is good also as a structure which makes high the probability that it will be elected in the electric character open state in. In addition, a secured time (for example, on the result display section for an accessory based on a winning to the through gate 84) that is secured after the next electrification opening lottery is performed after the first electrification opening lottery is performed. In the configuration in which multiple types of variable display time) are prepared, the short support time is more easily selected in the high frequency support mode or the average secure time is shorter than in the low frequency support mode. May be. Further, the number of times of opening is increased, the opening time is lengthened, and the secured time that is secured when the next electric winning combination opening lottery is performed after the first electric winning combination releasing lottery is shortened (that is, , Shorten one fluctuation display time in the result display section for an accessory), shorten the average time of the secured time and increase the winning probability, apply any one condition or any combination of conditions Thus, the advantage of the high frequency support mode over the low frequency support mode may be increased.

  The game result distribution destination for the big hit type counter C2 is stored as a distribution table (distribution information group) in the distribution table storage area as the distribution information group storage means in the ROM 403. Then, a normal jackpot result (low probability special game result) and a probability variable jackpot result (high probability special game result) are set as the distribution destinations.

  The normal jackpot result is that the winning lottery mode becomes the low probability mode after the opening / closing execution mode ends, and the support frequency is high until the number of games reaches the end reference number (specifically, 100 times) after the support mode shifts. It is a jackpot result that becomes a mode. After the end reference count has elapsed, the mode shifts to the low frequency support mode.

  The probability variation jackpot result is a jackpot result in which the success / failure lottery mode becomes the high probability mode and the support mode becomes the high frequency support mode after the opening / closing execution mode ends. The high-frequency support mode continues until the lottery result in the winning or failing lottery becomes a big hit state winning and the operation shifts to the opening / closing execution mode.

  In the distribution table, “0 to 9” corresponds to the normal jackpot result, and “10 to 29” corresponds to the probability variation jackpot result, but this numerical distribution is arbitrary. In addition, the distribution destination of the jackpot result is not limited to the above two types. For example, in the opening / closing execution mode, a plurality of modes are set so that the expected value of the game ball is high and the opening / closing execution is performed. It is good also as a structure which increases the type of jackpot result rather than said two types by providing a difference in the mode transfer destination mode.

  For example, the reach random number counter C3 is incremented one by one within a range of 0 to 238, for example, and reaches a maximum value (that is, 238) and then returns to 0. The reach random number counter C3 is periodically updated and stored in the reserved ball storage area 432 of the RAM 404 at the timing when the game ball wins the upper operation port 83a or the lower operation port 83b. More specifically, the game ball is stored in the holding area RE of the RAM 404 at the timing when a game ball is won in the upper operation port 83a or the lower operation port 83b. Then, based on the reach table stored in the reach table storage area of the ROM 403, it is determined whether to generate a reach. However, in the game times that shift to the open / close execution mode, the MPU 402 determines the occurrence of reach regardless of the value of the reach random number counter C3. The number of reach random number counters C3 corresponding to the occurrence of reach display is the same in each gaming state, but may be set individually according to the gaming state. For example, when the support mode is the high frequency support mode, the number of reach random number counters C3 corresponding to the occurrence of reach display may be set larger than that in the low frequency support mode.

  Here, the reach display (reach state) includes a symbol display device 94 capable of performing variable display (or variable display) of symbols (pictures), and the opening / closing execution mode of the variable winning device 82 is a high-frequency winning mode. In the gaming machine in which the stop display result after the variable display becomes a special display result, the stop display result is derived and displayed after the variable display (or variable display) of the symbol (picture) on the symbol display device 94 is started. This means a display state for making the player think that the display state is a variable display state that is likely to result in the special display result in the previous stage.

  In other words, a combination of jackpot symbols corresponding to the occurrence of the high-frequency winning mode can be obtained by stopping and displaying symbols for some of the symbol sequences displayed on the display screen 94a of the symbol display device 94. This is a display state in which a combination of reach symbols that may be established is displayed, and in that state, the symbols are displayed in a variable manner in the remaining symbol rows.

  More specifically, as a step before ending the variable display of symbols, a combination of jackpot symbols corresponding to the occurrence of the high-frequency winning mode is set on a preset active line in the display screen 94a of the symbol display device 94. A reach line is formed by stopping and displaying a combination of reach symbols that may be established, and a symbol change display is performed by a final stop symbol row in a situation where the reach line is formed.

  The display contents of the reach display will be described in detail with reference to FIG. 13. First, the symbol variation display is finished in the upper symbol row Z1, and the symbol variation display is finished in the lower symbol row Z3. , A reach line is formed by stopping and displaying the main symbols having the same numbers on any of the effective lines L1 to L5, and in the state where the reach line is formed, in the middle symbol row Z2 Reach display is achieved by performing symbol display. When the high-frequency winning mode occurs, the main symbol with the same number as the main symbol forming the reach line is stopped and displayed on the reach line in the middle symbol row Z2. The symbol variation display is terminated.

  In the reach display, in the state where the combination of reach symbols is displayed as described above, the variation display of symbols is performed on the remaining symbol rows, and a predetermined character or the like is displayed as a moving image on the background screen. There are those that produce an effect, and those that perform a reach effect by displaying a predetermined character or the like as a moving image on almost the entire display screen after reducing or not displaying a combination of reach symbols. Further, when reach display is performed or before reach display, it is determined using the reach random number counter C3 or other counter whether or not to perform a notice display using a predetermined image such as a predetermined character. May be.

  For example, the variation type counter CS is incremented one by one within a range of 0 to 198, for example, and reaches a maximum value (that is, 198) and then returns to 0. The variation type counter CS is used when the MPU 402 determines the variation display time on the main display unit 90 and the symbol variation display time on the symbol display device 94. The variation type counter CS is updated once every time a normal process to be described later is executed once, and is repeatedly updated even within the remaining time in the normal process. Then, the buffer value of the variation type counter CS is acquired when the symbol display device 94 determines the variation pattern at the start of symbol variation.

  For example, the electric accessory release counter C4 is incremented by 1 in order within a range of 0 to 249 and returns to 0 after reaching the maximum value (that is, 249). The electric accessory release counter C4 is periodically updated and stored in the electric combination holding area 433 of the RAM 404 at the timing when a game ball wins the through gate 84. Then, at a predetermined timing, a lottery is performed as to whether or not to control the electric accessory 83c to the open state based on the stored value of the electric accessory release counter C4. For example, if C4 = 0 to 199, the electric accessory 83c is controlled to be in an open state, and if C4 = 200 to 249, the electric accessory 83c is not controlled to be in an open state.

  As already described, in the MPU 402, at least the buffer value of the variation type counter CS is used to determine the variation display time in the symbol display device 94, but the variation display time table storage area 423 of the ROM 403 is used for the determination. It is done. Further, in the MPU 402, the stop result in the main display unit 90 is determined using the value of the jackpot random number counter C1 and the value of the jackpot type counter C2 stored in the execution area AE. The stop result table stored in the result table storage area 424 is referred to.

<Various processes executed by main controller 162>
Next, a timer interrupt process and a normal process that are executed when the MPU 402 in the main controller 162 advances the game in each game time will be described. In addition to the timer interrupt process and the normal process, the MPU 402 executes a main process activated when the power is turned on and an NMI interrupt process activated by input of a power failure signal to the NMI terminal (non-maskable terminal). Explanation of these various processes is omitted.

<Timer interrupt processing>
First, timer interrupt processing will be described with reference to the flowchart of FIG. This process is periodically activated by the MPU 402 (for example, at a cycle of 2 msec).

  In step S101, reading processing of the various detection sensors 311a to 311e is executed. That is, while reading the state of the various detection sensors 311a to 311e connected to the main control device 162, the state of the detection sensor (detection information from the detection sensor) is determined and the detection information (winning detection information) is stored. . For example, when it is determined that a ball has entered the upper working port 83a, a winning detection flag for the upper working port is stored in various flag storage areas 435 of the RAM 404, and a ball enters the lower working port 83b. If it is determined that the winning action has been made, a winning detection flag for the lower working port is stored in the various flag storage area 435. If it is determined that the game ball has passed through the through gate 84, a winning detection flag for through gate is stored in various flag storage areas 435 of the RAM 404.

  Thereafter, in step S102, the random number initial value counter CINI is updated. Specifically, the random number initial value counter CINI is incremented by 1 and cleared to 0 when the counter value reaches the maximum value. Then, the update value of the random number initial value counter CINI is stored in the corresponding buffer area of the RAM 404.

  In subsequent step S103, the big hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the electric accessory release counter C4 are updated. Specifically, the jackpot random number counter C1, the jackpot type counter C2, the reach random number counter C3, and the electric accessory release counter C4 are each incremented by 1 and cleared to 0 when the counter values reach the maximum value. Then, the updated values of the counters C1 to C4 are stored in the corresponding buffer area of the RAM 404.

  In a succeeding step S104, a through winning process associated with winning through the through gate 84 is executed. In the through winning process, it is determined whether or not a through gate winning detection flag is stored in the various flag storage area 435 of the RAM 404. If the flag is stored, it is stored in the electric power reservation area. On the condition that the number of stored accessory holdings is less than 4, the value of the electric accessory release counter C4 updated in the step S103 is stored in the electronic combination holding area. In addition, a process for turning on the holding lamp unit 46 of the variable display unit 85 corresponding to the number of reserved memories is executed for the voice lamp control device 143. If the through-gate winning detection flag is stored in the various flag storage areas 435, the winning detection flag is deleted and the through-gate winning process is terminated.

  After performing the winning process for the through gate in step S104, the process proceeds to step S105. In step S105, the winning process for the operating port accompanying the winning to the operating ports 83a and 83b is performed, and this timer interruption process is completed. To do.

<Winning process for working port>
Here, the winning process for the operation port will be described with reference to the flowcharts of FIGS.

  In step S201, it is determined whether or not a game ball has won a prize (start prize) in the upper operating port 83a based on whether or not a winning detection flag for the upper operating port is stored in the various flag storage areas 435 of the RAM 404. If it is determined that the winning detection flag is stored, that is, if the game ball receives a detection signal indicating that a winning has occurred in the upper operation port 83a, the process proceeds to step S202, and the payout control device 242 receives a game. A prize ball command for paying out three balls is set.

  In the subsequent step S203, an external signal setting process is performed to output information indicating that the game ball has won a prize to the upper operating port 83a to the hall computer HC on the game hall side. As a result, the hall computer HC recognizes that a winning for the upper working port 83a has occurred.

  Thereafter, in step S204, the value stored in the holding number storage area of the holding area Ra for the upper working port is read, and the start holding storage number RaN stored in the holding area Ra is set (hereinafter referred to as the upper operation). It is also referred to as the mouth start storage memory number RaN). Thereafter, in step S205, an information acquisition process for storing the values of the jackpot random number counter C1, the jackpot type counter C2 and the reach random number counter C3 is performed, and the main winning process is terminated.

  On the other hand, if it is determined in step S201 that the game ball has not won the upper working port 83a, the process proceeds to step S206. In step S <b> 206, the determination is made based on whether or not a winning detection flag for the lower operation port is stored in various flag storage areas 435 of the RAM 404. If it is determined that the winning detection flag is stored, that is, if the game ball receives a detection signal indicating that the lower operating port 83b has been won, the process proceeds to step S207, and the payout control device 242 receives a game. A prize ball command for paying out four balls is set. The prize ball command set in steps S202 and S207 is transmitted to the payout control device 242 in an external output process S401 of a normal process described later.

  In the subsequent step S208, an external signal setting process is performed to output information indicating that a game ball has won a prize to the lower operation port 83b to the hall computer HC on the game hall side. As a result, the hall computer HC recognizes that a winning has occurred in the lower working port 83b.

  Thereafter, in step S209, the value stored in the reserved number storage area of the holding area Rb for the lower operating port is read, and the start reserved memory number RbN stored in the reserved area Rb is set (hereinafter referred to as the lower action). It is also referred to as the mouth start reserved memory number RbN). Thereafter, an information acquisition process is performed in step S205, and the main winning process is terminated.

  On the other hand, if a negative determination is made in both steps S201 and S206, that is, if a game ball has not won in either the upper operating port 83a or the lower operating port 83b, the main winning process is terminated. .

  Here, the information acquisition processing in step S205 will be described with reference to FIG.

<Information acquisition process>
In the information acquisition process, first, in step S301, it is determined whether or not the start pending storage number N (RaN or RbN) set in step S204 or step S209 described above is less than an upper limit value (4 in the present embodiment). judge. If the start pending storage number N is the upper limit value, the information acquisition process is terminated as it is. If the start pending storage number N is less than the upper limit value, the corresponding start display storage number N of the corresponding result display area holding area is set in step S302. In addition to incrementing by 1, the value stored in the total pending count storage area in step S303 (hereinafter referred to as common pending count CRN) is incremented by 1.

  In the subsequent step S304, the values of the jackpot random number counter C1, the jackpot type counter C2, the reach random number counter C3, and the variation type counter CS updated in the above step S103 are stored in the free storage area area of the corresponding result display area reservation area. Of these, the first storage area, that is, the storage area corresponding to the reserved storage number incremented by 1 in step S302 is stored.

  That is, when the start pending storage number RaN for the upper working port is set, the values of the big hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the variation type counter CS updated in the step S103. Are stored in the first storage area of the free storage area of the upper working port holding area Ra, that is, in the holding area Ra corresponding to the starting working storage number RaN for the upper working port incremented by 1 in step S302.

  When the start pending storage number RbN for the lower working port is set, the values of the big hit random number counter C1, the big hit type counter C2 and the reach random number counter C3 updated in step S103 are set as the lower working port. Is stored in the first storage area among the free storage areas of the reserved area Rb for use, that is, in the reserved area Rb corresponding to the starting reserved memory number RbN for the lower operating port incremented by 1 in step S302.

  In subsequent step S305 and step S306, the audio lamp control device 143 and the display control device 500, which are control devices on the sub-side (sub-side), recognize that the winning to the upper operation port 83a or the lower operation port 83b has occurred. The hold information confirmation process and the hold command setting process are executed. Thereafter, when the winning detection flag is stored, the flag is erased and the information acquisition process is terminated.

  The hold command set in the hold command setting process in step S306 is transmitted to the sound lamp control device 143 in the normal output external output process (step S401) described later. A detailed description of each process in steps S305 and S306 will be described later.

<Normal processing>
Next, the flow of normal processing will be described with reference to the flowchart of FIG. The normal process is a process that is started after the main process that is started when the power is turned on, and the main process of the game is executed in the normal process. As an overview, the processing of steps S401 to S406 is executed as a periodic processing with a period of 4 msec, and the counter update processing of steps S408 and S409 is executed with the remaining time.

  In the normal processing, first, external signal output processing is executed in step S401. In the external signal output process of step S401, output data such as a command set in the timer interrupt process or the previous normal process is transmitted to each control device on the sub side. Specifically, the presence or absence of a prize ball command is determined, and if a prize ball command is set, it is transmitted to the payout control device 242. If an effect command such as a change command, a type command, or a change end command is set, the command is transmitted to the sound lamp control device 143.

  Next, in step S402, the variation type counter CS is updated. Specifically, the variation type counter CS is incremented by 1, and the counter value is cleared to 0 when the counter value reaches the maximum value. Then, the update value of the variation type counter CS is stored in the corresponding buffer area of the RAM 404.

  In subsequent step S403, a game time control process for controlling a game in each game time is executed. In the game times control process, jackpot determination, setting of symbol variation display by the symbol display device 94, display control of the main display unit 90, and the like are performed.

  After executing the game times control process of step S403, the process proceeds to step S404, and the game state transition process is executed. Although details will be described later, the gaming state shifts to an opening / closing execution mode, a high probability mode, a high frequency support mode, and the like by this gaming state transition processing. Details of the game turn control process in step S403 and the game state transition process in step S404 will be described later.

  In the subsequent step S405, an electric role support process for driving and controlling the electric charge 83c provided in the lower working port 83b is executed. In this electronic combination support process, the electronic combination release indicating whether or not to make the electric combination 83c open using the numerical information acquired from the electric combination release counter C4 stored in the electronic combination holding area 433 of the RAM 404. A lottery is performed, and when the electrified open state is won, an opening / closing process of the electric accessory 83c is executed. Further, display control of the main display unit 90 is performed so as to teach the lottery result of the electric role release lottery.

  Here, as already described, the low-frequency support mode and the high-frequency support mode are set as the modes of support by the electric accessory 83c, and the transition to one of the support modes is performed in the gaming state transition process. Is called. After this processing, the high frequency support mode is set when the high frequency support flag is set in the various flag storage areas 435 of the RAM 404, and the low frequency support mode is set when the flag is not set.

  In the power combination support process, it is determined whether or not the high frequency support mode is set by determining whether or not the high frequency support flag is set in the various flag storage areas 435 of the RAM 404. In the high-frequency support mode, when the electrified open state is won, the number of times that the electric accessory 83c is opened is set more than in the low-frequency support mode. Set a longer opening time. Also, in the high frequency support mode, when the electrified open state is selected and the open state of the electric accessory 83c occurs a plurality of times, the next open state is started after the completion of one open state. The closing time until is set to be shorter than one opening time.

  Incidentally, when the mode is shifted to the opening / closing execution mode, even if the high frequency support flag is set in the various flag storage areas 435 of the RAM 404, the support mode is forcibly set to the low frequency support mode.

  Thereafter, in step S406, a game ball launch control process is executed. In the game ball launch control process, the solenoid of the game ball launch mechanism 110 is excited once every predetermined period (for example, 0.6 sec) on condition that a launch permission signal is input from the power supply / launch control device 243. . Thereby, a game ball is launched toward the game area PE.

  In subsequent step S407, it is determined whether or not the execution timing of the next normal process has been reached, that is, whether or not a predetermined time (4 msec in the present embodiment) has elapsed since the start of the previous normal process. Then, the random number initial value counter CINI and the variation type counter CS are repeatedly updated within the remaining time until the next normal processing execution timing.

  That is, in step S408, the random number initial value counter CINI is updated. Specifically, the random number initial value counter CINI is incremented by 1 and cleared to 0 when the counter value reaches the maximum value. Then, the update value of the random number initial value counter CINI is stored in the corresponding area of the RAM 404. In step S409, the variation type counter CS is updated. Specifically, the variation type counter CS is incremented by 1 and cleared to 0 when the counter value reaches the maximum value. Then, the update value of the variation type counter CS is stored in the corresponding area of the RAM 404.

  Here, since the execution time of each process of steps S401 to S406 changes according to the state of the game, the remaining time until the next normal process execution timing is not constant and varies. Therefore, by repeatedly updating the random number initial value counter CINI using the remaining time, the random number initial value counter CINI (that is, the initial value of the big hit random number counter C1) can be updated at random. Similarly, The variation type counter CS can also be updated at random.

<Game times control processing>
Next, the game times control process of step S403 will be described with reference to the flowcharts of FIGS.

  In the game times control process, first, as shown in the flowchart of FIG. 19, it is determined in step S501 whether the open / close execution mode is in effect. When the opening / closing execution mode is in progress, the process after step S502, that is, the game turn start process at steps S503 to S505 and the game turn progress process at steps S506 to S509 are not executed. The control process ends.

  If it is not in the opening / closing execution mode, it is determined in step S502 whether or not the operation port result display section of the main display section 90 is in a variable display. When the operation port result display unit is not in a variable display, the process proceeds to a game turn start process in steps S503 to S505. In the game turn starting process, first, in step S503, it is determined whether or not the total number of start holding balls (common holding number CRN) is “0”. The case where the common holding number CRN is “0” means that the holding information is not stored in the holding ball storage area 432. Accordingly, the game turn control process is terminated as it is.

  On the other hand, if the common hold number CRN is not “0”, a data setting process for setting the data stored in the holding area RE of the holding ball storage area 432 for variable display in step S504, Further, in step S505, after executing the variation start process for starting the variation display on the main display unit 90 and the variation display on the symbol display device 94, the game turn control process is terminated.

  Here, the data setting process in step S504 and the change start process in step S505 will be described in detail. First, the data setting process in step S504 will be described with reference to the flowchart in FIG.

<Data setting process>
In the data setting process, first, it is determined in which holding area Ra, Rb the oldest information stored in the holding area Ra for the upper working opening and the holding area Rb for the lower working opening is stored. To do. Then, the following processing is executed for the holding area where the oldest holding information is stored. In the following description, the case where the upper working port holding area Ra is first described will be described, and then the case where the lower working port holding area Ra is used will be described.

  In step S601, the starting reserved ball number RaN and the common reserved number CRN of the holding area Ra are decremented by one. In subsequent step S602, the data stored in the first area Ra1 of the holding area Ra is moved to the execution area AE.

  Thereafter, in step S603, a process of shifting data stored in the areas Ra1 to Ra4 (that is, the hold information) of the hold area Ra is executed. This data shift process is a process of sequentially shifting the data stored in the first area Ra1 to the fourth area Ra4 to the lower area side, clearing the data in the first area Ra1, and the second area Ra2 → The data in each area is shifted such as the first area Ra1, the third area Ra3 → the second area Ra2, the fourth area Ra4 → the third area Ra3.

  In the subsequent step S604, a command at the time of shifting, which is information for making the audio lamp control device 143 recognize that the data in the holding area has been shifted, is set. Thereafter, the data setting process is terminated. The shift time command set in step S604 is transmitted to the display control device 500 via the audio lamp control device 143 in step S401 in the normal process (FIG. 18). The display control device 500 receives the shift command, and executes a process for changing the display in the reserved number display area Da for the upper working port in accordance with the decrease in the reserved number.

  On the other hand, similarly, when the reserved area Rb for the lower working port is the target, first, in step S601, the starting reserved ball number RbN and the common reserved number CRN of the reserved area Rb are decremented by one. In subsequent step S602, the data stored in the first area Rb1 of the holding area Rb is moved to the execution area AE.

  Thereafter, in step S603, a process of shifting data stored in the areas Rb1 to Rb4 of the holding area Rb (that is, holding information) is executed. This data shift process is a process of sequentially shifting the data stored in the first area Rb1 to the fourth area Rb4 to the lower area side, and clears the data in the first area Rb1 and the second area Rb2 → The data in each area is shifted such as first area Rb1, third area Rb3 → second area Rb2, and fourth area Rb4 → third area Rb3.

  In the subsequent step S604, a command at the time of shifting, which is information for making the audio lamp control device 143 recognize that the data in the holding area has been shifted, is set. Thereafter, the data setting process is terminated. The shift time command set in step S604 is transmitted to the display control device 500 via the audio lamp control device 143 in step S401 in the normal process (FIG. 12). The display control device 500 receives the shift command and executes a process for changing the display in the reserved number display area Db for the lower working port in accordance with the decrease in the reserved number.

<Variation start processing>
Next, the variation start process of step S505 will be described with reference to the flowchart of FIG.

  In the change start process, first, in step S701, a success / failure determination process for determining whether or not the hold information referred to in the current change start process corresponds to the big win is executed. Specifically, the information acquired from the information for jackpot determination among the information stored in the execution area AE, that is, the information updated by the jackpot random number counter C1 is grasped. Then, when the winning / losing lottery mode is the low probability mode, referring to the winning table for the low probability mode stored in the winning table storage area 421 of the ROM 403, the grasped information becomes the information corresponding to the big hit winning. If it is determined that the winning lottery mode is the high probability mode, referring to the high probability mode success / failure table stored in the success / failure table storage area 421 of the ROM 403, the grasped information is a big hit. Identify whether it is included in the information corresponding to the winning.

  In the subsequent step S702, it is determined whether or not the result of the determination process in step S701 is a result corresponding to the big win. If the result corresponds to the big win, the type determination process is executed in step S703.

  In the type determination process, the information acquired from the information for type determination among the information stored in the execution area AE, that is, the information updated by the big hit type counter C2 is grasped. Further, with reference to the sorting table stored in the sorting table storage area of the ROM 403, it is specified whether the grasped type determination information is included in the information corresponding to the probability variation jackpot result.

  In the subsequent step S704, it is determined whether or not the type of the current big hit winning is a probable big hit result based on the information specified in the type determining process in step S703. If it is the probability variation jackpot result, stop result setting processing for probability variation jackpot is executed in step S705, and if it is not the probability variation jackpot result, stop result setting processing for normal jackpot is executed in step S706. If it is determined in step S702 that it is not a big win, a stop result setting process for losing is executed in step S707.

  In each stop result setting process in step S705 to step S707, the information on the pattern mode to be finally stopped and displayed on the main display unit 90 is referred to the stop result table stored in the stop result table storage area 424 of the ROM 403. The specified information is stored in the RAM 404. Further, in step S705 and step S706, information for specifying in the MPU 402 that the determination result of whether or not this game is successful is a probability variation jackpot result or a normal jackpot result is stored in various flag storage areas 435 of the RAM 404. Specifically, the probability variation jackpot flag is stored in step S705, and the normal jackpot flag is stored in step S706.

  After executing any one of steps S705 to S707, a variable display time setting process is executed in step S708.

<Variable display time setting process>
In the variable display time setting process, as shown in the flowchart of FIG. 22, first, in step S801, it is determined whether or not the winning / losing lottery is won. Specifically, it is determined whether or not either the probable big hit flag or the normal big hit flag is stored in the various flag storage areas 435 of the RAM 404.

  If a negative determination is made in step S801, that is, if the result of the above-mentioned lottery determination is a losing result, the process proceeds to step S802. In step S802, it is determined whether or not reach display is generated in the symbol display device 94 in the current game round. Specifically, if the value of the reach random number counter C3 stored in the execution area AE is a value corresponding to the occurrence of reach, an affirmative determination is made in step S802 as occurrence of reach display. When specifying the presence / absence of reach using the value of the reach random number counter C3, the reach determination table stored in the reach determination table storage area of the ROM 403 is referred to.

  If an affirmative determination is made in either step S801 or step S802, the process proceeds to step S803, and the current generation is displayed with reference to the reach generation variable display time table stored in the variable display time table storage area 423 of the ROM 403. Fluctuation display time information corresponding to the value of the fluctuation type counter CS and the like is acquired, and in the subsequent step S804, the fluctuation display time information is provided in a fluctuation display time counter area (variation display time measuring means provided in various counter areas 434 of the RAM 404). ). Thereafter, the setting process ends.

  In other words, in the present embodiment, the reach display is executed when the result of the lottery win is a jackpot winning result or when the result of the same lottery is a missed result and the lottery for generating the reach is won. ing.

  Here, the reach display is provided with a normal reach display and a super reach display which have different display modes. The variable display time information corresponding to each of the normal reach display and the super reach display is set in the variable display time table for reach generation. By referring to the table, the variable display time information corresponding to each reach display is set. To be acquired. Regarding the determination of the type of reach display, a table is provided in which the type of reach display corresponds to the value of the variation type counter CS. By referring to the table, the value of the current variation type counter CS is determined. The corresponding reach display is determined.

  Further, the reach generation variation display time table corresponds to the jackpot type. Specifically, the variable display time is set so that the combination of specific symbols can be stopped in the case of a probable jackpot result, and the combination of non-specific symbols can be stopped in the case of a normal jackpot result. In addition, the variable display time is set.

  On the other hand, if a negative determination is made in step S802, the value of the current variation type counter CS is referred to with reference to the reach non-occurrence variation display time table stored in the variation display time table storage area 423 in step S805. In step S806, the variable display time information is set in the variable display time counter area. Thereafter, the setting process ends.

  Note that the variable display time information when no reach occurs is set so that the variable display time is shortened as the number N of starting reserved balls increases. However, the present invention is not limited to this, and for example, a configuration that does not depend on the number of starting reserved balls N may be used. The smaller the number of starting reserved balls N, the shorter the variation display time is. Also good. Also, in the situation where the support mode is the high frequency support mode, the non-reach time is selected so that the shorter variable display time is selected compared to the situation where the number of pending information is the same as in the situation where the low frequency support mode. Although the generation variation display time table is set, the present invention is not limited to this, and the selected variation display time may be the same, or may be opposite to the above relationship. Furthermore, the above configuration may be applied to the variable display time at the time of reach occurrence, and the variable display time that is easily selected and the variable display time that is difficult to select are different at the time of jackpot winning and out of reach. It is good also as a structure. Also, a variation display time table for probability variation jackpot, a variation display time table for normal jackpot, a variation display time table for outreach, and a variation display time table for complete losing may be set individually.

  As described above, the variation display time of each game time is determined using parameters such as the presence / absence of reach, the type of reach display, the number of hold information, the value of the variation type counter, and the like. However, the variable display time of each game time is the content of other hold information, specifically, jackpot determination information, type determination information and reach determination information included in the other hold information as parameters. Decided without.

  Returning to the description of the change start process (FIG. 21), after the change display time setting process is executed in step S708, a change command and a type command are set in step S709. The change command includes information on presence / absence of reach and information on change display time. The type command includes game result information. That is, the type command includes, as game result information, information on probability variation jackpot results, information on normal jackpot results, information on miss results, and the like.

  The change command and the type command set in step S709 are transmitted to the sound lamp control device 143 in step S401 in the normal process (FIG. 18). The sound lamp control device 143 determines the light emission pattern of the display lamp units 24 to 26 and the sound output pattern from the speaker unit 27 in the game time based on the received variation command and type command, and the determined effect. The display lamp sections 24 to 26 and the speaker section 27 are controlled so that the contents of the above are executed. In addition, the sound lamp control device 143 determines a variation display pattern in the symbol display device 94 in the game time based on the received variation command and type command, and the determined variation display pattern is executed. The change command and the type command are added to the display control device 500 with information for specifying the change display pattern while maintaining the information form. Thereafter, in step S710, the variation display of the pattern is started on the working port display section of the main display section 90, and then the variation start processing is terminated.

  Returning to the description of the game times control process (FIG. 19), when the main display unit 90 is in the variable display mode, the game times progress process of steps S506 to S509 is executed. In the process for advancing game times, first, in step S506, it is determined whether or not the current game time fluctuation display time has elapsed. Specifically, it is determined whether or not the value of the variable display time information stored in the variable display time counter area of the RAM 404 is “0”. The value of the variable display time information is set in the variable display time setting process (FIG. 22) as described above. The set value of the variable display time information is decremented (subtracted) every time the timer interrupt process (FIG. 15) is started.

  If the variable display time has not elapsed, the variable display process is executed in step S507. In the variable display process, the display mode on the main display unit 90 is changed. Thereafter, the game times control process is terminated.

  If the change display time has elapsed, change end processing is executed in step S508. In the change end process, the information stored in the RAM 404 in the process of any one of steps S705 to S707 is specified, and the main display unit 90 is displayed so that the picture corresponding to the information is stopped and displayed on the main display unit 90. 90 is controlled.

  In the subsequent step S509, a change end command is set. Thereafter, the game times control process is terminated. The change end command set in step S509 is transmitted to the sound lamp control device 143 in step S401 in the normal process (FIG. 18). The audio lamp control device 143 transmits the received change end command to the display control device 500 while maintaining the information form. The display control device 500 receives the change end command and displays the final stop symbol combination in the game round in a definitive display (final stop display).

<Game state transition processing>
Next, the gaming state transition processing in step S404 will be described with reference to the flowchart in FIG.

  In the game state transition process, first, in step S901, it is determined whether or not the open / close execution mode is in effect. If it is not in the opening / closing execution mode, the process proceeds to step S902, and it is determined whether or not it is the timing when the display of the variation of the pattern on the main display section 90 (specifically, the display section for the operation opening) of one game time is finished. If it is not the timing when the variable display is finished, the gaming state transition process is finished as it is.

  If it is the timing when the variable display is finished, it is determined in step S903 whether or not the game result of the current game time corresponds to the transition to the opening / closing execution mode. Specifically, it is determined whether or not either the normal jackpot flag or the probability variation jackpot flag is stored in the RAM 404. If none of the above flags is stored, the gaming state transition process is terminated as it is.

  If any of the above flags is stored, “15” is set in the round counter area RC provided in the various counter areas 434 of the RAM 404 in step S904. The round counter area RC is a counter area for counting the number of times the large winning opening 82a of the variable winning device 82 is opened. Thereafter, the gaming state transition process is terminated.

  On the other hand, when in the opening / closing execution mode, an affirmative determination is made in step S901, and the process proceeds to step S905. In step S905, a special winning opening / closing process is executed. In the big prize opening / closing process, when the big prize opening 82a is closed, the variable prize driving unit 82c is set in the driving state on condition that the round counter area RC is “1” or more. The mouth 82a is opened. Further, when the grand prize winning opening 82a is being opened, the variable prize driving is performed on condition that a predetermined time has passed since the opening of the special winning prize opening 82a or a predetermined number of game balls have been won. The driving state of the part 82c is stopped, and the special winning opening 82a is closed.

  In a succeeding step S906, it is determined whether or not the value of the round counter area RC is “0”. If the value of the round counter area RC is not “0”, the gaming state transition process is terminated as it is. If the value of the round counter area RC is “0”, a transition process at the end of the opening / closing execution mode is executed in step S907.

  In the transition process at the end of the opening / closing execution mode, when the probability variation jackpot flag is stored in the RAM 404, the success / failure lottery mode is set to the high probability mode and the support mode is set to the high frequency support mode. Note that these high probability mode and high frequency support mode are maintained at least until the next big win is won. In addition, when the normal jackpot flag is stored in the RAM 404, the success / failure lottery mode is set to the low probability mode and the support mode is set to the high frequency support mode. However, the high-frequency support mode is terminated when the number of game times continues 100 times, and thereafter, the winning lottery mode is the low probability mode and the support mode is the low-frequency support mode.

  Then, in step S908, after executing the opening / closing execution mode end processing, the gaming state transition processing ends. In the opening / closing execution mode end processing, the stored flag is erased from the normal jackpot flag or the probability variation jackpot flag.

<Audio lamp control device 143>
Next, the sound lamp control device 143 will be described with reference to the block diagram of FIG.

  The audio lamp control device includes an audio lamp control board 451 on which an MPU 452 is mounted. The MPU 452 includes a ROM 453 that stores various programs executed by the MPU 452 and fixed value data, and a RAM 454 that is a memory for temporarily storing various data when executing the control program stored in the ROM 453. In addition, an interrupt circuit, a timer circuit, a data input / output circuit, and various counter circuits as a random number generator are incorporated. In the MPU 452, it is not essential that the ROM 453 and the RAM 454 are made into one chip, but each may be made into a chip individually. The same applies to MPUs of other control devices.

  The MPU 452 is provided with an input port and an output port. The main control device 162 is connected to the input side of the MPU 452, and the game time control commands (game time control information) such as the change command, the type command, and the change end command already explained from the main control device 162 are used. Receive. Also, a hold display control command (hold display control information) such as a shift command and a hold command described later, and an open / close execution mode command (open / close execution mode information) such as an opening command and an ending command are received.

  As described above, the display lamp units 24 to 26, the speaker unit 27, and the display control device 500 provided on the front door frame 14 are connected to the output side of the MPU 452. In this case, the various commands are transmitted to the display control device 500 while maintaining the information form as it is.

  In addition, a production operation switch 40 provided on the front door frame 14 is connected to the input side of the MPU 452, and detection information (detection signal) from the operation switch 40 is input. The MPU 452 determines whether or not the operation switch 40 has been operated based on the detection information, and if it is determined that the operation has been performed as a result of the determination, the MPU 452 has the condition that the operation has been performed within the effective period. A command for executing an effect corresponding to the operation is transmitted to the display control device 500.

  The MPU 452 receives the variation command transmitted from the main control device 162, thereby recognizing that it is necessary to start the effect for game times, and executes the effect start processing for game times. Further, by receiving the end command transmitted from the main control device 162, it is recognized that it is necessary to end the effect for the game times, and the game time effect end processing is executed. In addition, by receiving various jackpot presentation commands transmitted from the main controller 162, it is recognized that the jackpot presentation needs to be started or advanced, and the jackpot presentation process is executed. Also, by receiving a demonstration display command transmitted from the main controller 162, it is recognized that the demonstration display needs to be started, and the demonstration display process is executed.

  Note that the MPU 452 receiving a command from the main control device 162 is not limited to a configuration that directly receives a command from the main control device 162, and includes a configuration that receives a command relayed to the relay board.

  In the game turn production start process, based on both the change command and the type command, the change display time grasp processing for grasping the change display time (display duration) of the corresponding game turn and the presence / absence of reach display are grasped. A reach display grasping process, a jackpot result occurrence grasping process for grasping presence / absence of a jackpot result, and a jackpot type grasping process for grasping a jackpot type when a jackpot result occurs are executed. Further, based on the grasp results in the reach display grasping process, the jackpot result occurrence grasping process, and the jackpot type grasping process, a display effect for determining the type of display effect to be performed on the display screen 94a of the symbol display device 94 in this game round. In addition to executing the grasping process, the symbol type grasping process for determining the kind of the symbol to be finally stopped and displayed on the display screen 94a of the symbol display device 94 in this game round is executed. Then, based on the results of each of these grasping processes, a display control device includes a variation pattern command including information on the variation display time and information on the type of display effect, and a symbol designating command including information on the type of symbol to be finally stopped and displayed Sent to 500.

  Further, in the game start effect starting process, the display light emission table for game times and the sound table for game times are read from the ROM 453 based on the processing results of the above processes. The display light emission table for game times defines the light emission mode of the display light emitting unit 44 during the progress of the corresponding game times. In addition, an output mode from the speaker unit 27 in the progress process of the corresponding game round is defined by the game round voice table.

  Here, a supplementary description will be given of the variation display mode of symbols displayed on the symbol display device 94 (display screen 94a) based on FIG. FIG. 25A is a schematic diagram showing the types of variation display modes, and FIG. 25B is a schematic diagram showing an overview of each variation display mode.

  As shown in FIG. 25 (a), there are five symbol fluctuation display modes executed on the display screen 94a: complete detachment, normal reach A, normal reach B, super reach A, super reach B, and super reach C. Broadly divided. About each of these variable display modes, the variable display time is set to be different, and the outline of the variable display mode for each game time is grasped based on the information related to the variable display time given to the command from the main controller 162. It is possible.

  Specifically, “3 sec to 8 sec” is set for the fluctuation display time that is completely out of place (a difference is set according to the number of holds), “10 sec” is set for the fluctuation display time for normal reach A, and the fluctuation display time for normal reach B Is about 15 seconds longer than the fluctuation display time of normal reach A, the fluctuation display time of super reach A is "16 sec" longer than the fluctuation display time of normal reach A and B, and the fluctuation display time of super reach B is super reach. “17 sec”, which is longer than the fluctuation display time of A, and “18 sec”, which is longer than the fluctuation display times of the other super reach A and B, as the fluctuation display time of the super reach C. It is set so that the expectation of winning the jackpot is high. For example, when the information regarding the variable display time given to the command from the main control device 162 is “15 sec”, the display control device 500 knows that the normal reach B should be executed.

  Here, the fluctuation display mode of the normal reach A and B will be described with reference to FIG. When the normal reach A or B is selected, first, the variable display (scroll display) of all the symbol sequences that are stopped is started, and then the symbol variable display is terminated in the upper symbol column Z1 (stop) In addition, in the lower symbol row Z3, the symbol variation display is terminated (stopped display). In the state where the upper and lower symbol rows Z1 and Z3 are stopped and displayed in this manner, the reach symbol is displayed by stopping and displaying the main symbols having the same numbers on any of the effective lines L1 to L5 (see FIG. 6). Is formed. Then, the reach display is performed by performing the variable display of the middle symbol row Z2 under the situation where the reach line is formed. After reaching the reach display, the variable display is terminated by stopping and displaying the middle symbol row Z2. Then, the fact that the symbol that is the same as the symbol that constitutes the reach display stops on the reach line is informed that the jackpot has been won, and the other symbols on the reach line stop to win the jackpot It will be notified that it is not. In this way, the combination of symbols that are finally stopped and displayed is maintained as they are for a predetermined period. In other words, the current game time continues until the stop display period elapses, and the transition to the next game time is permitted after the stop display period elapses.

  In the present embodiment, the difference in the fluctuation display time between the normal reach A and the normal reach B is ensured by setting the difference in the fluctuation display time of the middle symbol row Z2 after the reach line is formed. The method of setting the difference is arbitrary. For example, by setting a difference in the time from when the variable display is started to when the reach line is formed, the difference in the variable display time can be secured.

  Next, the variation display mode of super reach A, B, C will be described based on the above-described variation display mode of normal reach A, B. As shown in FIGS. 25 (b2) to (b4), the reach lines described above are formed through the same process as that of the normal reach A and B for the super reach A, B, and C. And after forming a reach line, it is the structure which performs a reach effect by displaying a predetermined character as a moving image together with the fluctuation display of the middle symbol row Z2. Specifically, after a reach line is formed in Super Reach A, a character imitating a fairy is displayed at the center of the variable display area of the middle symbol row Z2 (the center of the variable display area ME). After the reach line is formed, a character imitating a boy is displayed at the center of the variable display area of the middle symbol row Z2 (the center of the variable display area ME). In Super Reach C, the reach line is formed, A character imitating a girl is displayed at the center of the variable display area of the middle symbol row Z2 (the center of the variable display area ME).

  In the present embodiment, for Super Reach A to Super Reach C, 2D display (2D effect) in which the character is displayed in 2D and 3D display (3D effect) in which the character is displayed in 3D are set. ing. As for 3D correspondence display, after a predetermined waiting period has elapsed since the character was displayed, the image of the character is changed from a flat one corresponding to 2D to a three-dimensional one corresponding to 3D. In accordance with this, the light emission mode of the various lamp units 24 to 26 and the sound output mode from the speaker unit 27 are changed. That is, various conditions such as character size and movement are the same, but the display mode is differentiated depending on whether it is planar or stereoscopic, thereby diversifying the production mode.

  When the variable display mode corresponds to any one of Super Reach A to Super Reach C, the audio lamp control device 143 performs a lottery process for determining whether or not to execute the 3D effect. Specifically, the lottery table stored in the lottery table storage area 461 of the ROM 453 and the value of the lottery counter stored in the various counter areas 472 of the RAM 454 are collated to make a 2D effect or Whether or not to make a 3D effect is determined.

  The lottery table stores a jackpot result and a miss result respectively, and the lottery table corresponding to the jackpot result is configured such that the 3D effect is more easily selected than the lottery table corresponding to the miss result. Therefore, the 3D effect is set so that the winning expectation degree of jackpot is higher than the 2D effect. Details of these 2D effects and 3D effects will be described later.

<Display control device 500>
Next, the display control apparatus 500 will be described with reference to the block diagram of FIG. 24 again.

  As shown in FIG. 24, the display control device 500 includes a central CPU 510, a 2D display CPU 520, a 3D display CPU 530, a memory module 540, a work RAM 550, VRAMs 560 and 570, and a video display processor (VDP) 580. A substrate 501 is provided.

  The overall CPU 510 has a function as a main control unit in the display control device 500, and reads (fetches), interprets (decodes), and executes a control program and the like. Specifically, the overall CPU 510 is connected to an input port 505 mounted on the display control board 501 via a bus, and various commands transmitted from the sound lamp control device 143 are input to the overall CPU 510 through the input port 505. . Note that receiving the command from the sound lamp control device 143 in the overall CPU 510 is not limited to the structure of receiving the command directly from the sound lamp control device 143, and includes the structure of receiving the command relayed to the relay board. It is.

  The central CPU 510 is connected to the work RAM 550, the memory module 540, and the display CPUs 520 and 530 via a bus, and based on commands received from the sound lamp control device 143, various data stored in the memory module 540 are stored in the work RAM 550. The transfer instruction to transfer to is performed. The overall CPU 510 is connected to the display CPUs 520 and 530 via the bus, and outputs an operation command to the display CPUs 520 and 530 based on the command received from the sound lamp control device 143.

  The display CPUs 520 and 530 are also connected to the memory module 540 and the VRAMs 560 and 570, and transfer is performed to transfer various data stored in the memory module 540 to the VRAMs 560 and 570 based on operation commands received from the overall CPU 510. Give instructions. The display CPUs 520 and 530 are connected to the VDP 580 via a bus, and issue a drawing instruction for causing the symbol display device 94 to output an image signal based on a command received from the overall CPU 510. Hereinafter, the memory module 540, the work RAM 550, the VRAMs 560 and 570, and the VDP 580 will be described.

  The memory module 540 stores in advance control data (control information) including a control program and fixed value data, and stores in advance various image data (image information) for displaying a 2D image and a 3D image. Storage means. The memory module 540 includes a non-volatile semiconductor memory that does not require external power supply for memory retention, and more specifically, a NAND flash memory is used as the semiconductor memory. Incidentally, although the storage capacity is 4 Gbits, this storage capacity is arbitrary as long as the control in the display control apparatus 500 is executed satisfactorily. In addition, the memory module 540 is used as a non-write and read-only memory (ROM) when the pachinko machine 10 is used.

  Various image data stored in the memory module 540 includes sprite data (two-dimensional image data) such as symbols and characters displayed on the symbol display device 94, and objects such as symbols and characters displayed on the symbol display device 94. Polygon (3D image data), texture image data pasted on the object, background data (for example, image data for the back that constitutes the backmost image in an image for one frame), and moving image data Various image data including image information (image information) is included.

  Each sprite data includes at least a combination of bitmap format data that defines the outer shape and pattern of the character and a color palette table that is referred to when determining the display color at each pixel of the bitmap image.

  The object is a three-dimensional virtual object arranged in a world coordinate system (world space), which is a three-dimensional coordinate system corresponding to the virtual three-dimensional space, and includes three-dimensional information composed of a plurality of polygons. It is. A polygon is a polygonal plane defined by vertices of a plurality of three-dimensional coordinates. In order to apply, for example, a surface model to the object image data, vertex coordinate information of each polygon is set with reference coordinates preset for each object as the origin. That is, in the image data for each object, the relative position (that is, direction and size) of each polygon is three-dimensionally defined in a self-contained local coordinate system.

  A texture is an image to be pasted on each polygon of an object, and a texture image is pasted on an object, thereby generating a display image including an image corresponding to the object, for example, a design or a character. The manner of holding the image data for texture is arbitrary, but includes at least a combination of, for example, bitmap format data and a color palette table referred to when determining the display color at each pixel of the bitmap image. Yes.

  The backmost image constitutes a two-dimensional image. The manner of holding the image data for the back is arbitrary, but for example, it is stored and held as JPEG format data in a state in which two-dimensional still image data is compressed. Incidentally, a plate polygon is used when the image data for the back side is arranged in the world coordinate system.

  The work RAM 550 is a storage unit that temporarily stores control data read and transferred from the memory module 540 and temporarily stores flags and the like. The work RAM 550 includes a volatile semiconductor memory that requires external power supply for storage and retention, and in detail, a DRAM is used as the semiconductor memory. However, it is not limited to DRAM, and other RAM such as SRAM may be used. The storage capacity is 1 Gbit, but the storage capacity is arbitrary as long as the control in the display control device 500 is executed well. The work RAM 550 is used for both reading and writing when the pachinko machine 10 is used.

  Based on a data transfer instruction from the overall CPU 510 to the memory module 540, control data is transferred from the memory module 540 to the work RAM 550. In this case, the control data is transferred in advance until the execution timing of the process in the overall CPU 510 corresponding to the control data. The general CPU 510 reads the control data transferred to the work RAM 550 into an internal memory area (register group) as necessary, and executes various processes.

  VRAMs 560 and 570 are storage means for temporarily storing various data necessary for image output to the symbol display device 94. The VRAMs 560 and 570 have a volatile semiconductor memory that requires an external power supply for storing and holding, and in detail, an SDRAM is used as the semiconductor memory. However, it is not limited to SDRAM, and other RAM such as DRAM, SRAM or dual port RAM may be used. Note that the storage capacity is 2 Gbits, but the storage capacity is arbitrary as long as the control in the display control apparatus 500 is executed satisfactorily. The VRAMs 560 and 570 are used for both reading and writing when the pachinko machine 10 is used.

  Each of the VRAMs 560 and 570 includes development buffers 561 and 571. The development buffers 561 and 571 store image data (from the memory module 540 based on a data transfer instruction from the display CPUs 520 and 530 to the memory module 540). The above-mentioned sprite data, polygon, background data, etc.) are transferred. In this case, the image data is transferred in advance until the execution timing of processing in the VDP 580 using the image data is reached. Each VRAM 560, 570 is provided with a frame buffer 562, 572 in which drawing data is created by the VDP 580. Note that the VRAMs 560 and 570 may be built in the VDP 580.

  The VDP 580 performs drawing on the symbol display device 94 by specifically processing the data stored in the development buffers 561 and 571 based on the drawing instructions from the display CPUs 520 and 530. It is an image generation device to be performed, and is a kind of drawing circuit that operates an image processing device 94c incorporated so as to drive and control the liquid crystal display unit 94b in the symbol display device 94. Since the VDP 580 is an IC chip, it is also referred to as a “drawing chip”, and the substance of the VDP 580 should be said to be a microcomputer chip with a dedicated firmware for drawing.

  Specifically, the VDP 580 includes a control unit 581, a register 582, a moving picture decoder 583, and a display circuit 584. These circuits are connected to each other via a bus, and an I / F 585 for the display CPUs 520 and 530 and an I / F 586 for the VRAMs 560 and 570 are connected.

  In the VDP 580, a drawing list as drawing instruction information transmitted from each of the display CPUs 520 and 530 is stored in the register 582. By storing the drawing list in the register 582, the control unit 581 starts a program according to the drawing list and executes a predetermined process. Note that all the control programs for operating the control unit 581 may be provided by the drawing list, and a memory storing the control program in advance is built in the control unit 581 so that the control program and the contents of the drawing list are stored. Therefore, the control unit 581 may execute a predetermined process. Alternatively, the control program may be read from the memory module 540 in advance.

  As the above processing, the control unit 581 uses (or processes) the image data expanded in one of the expansion buffers 561 and 571 of both the VRAMs 560 and 570, and one frame is stored in one of the frame buffers 562 and 572. Create drawing data for minutes. The drawing data for one frame refers to data necessary for displaying an image at one update timing in a configuration in which the image on the display screen 94a of the symbol display device 94 is updated at a predetermined update timing. That means.

  Here, the frame buffers 562 and 572 are provided with a plurality of frame regions 562a, 562b, 572a, and 572b, respectively. Specifically, the frame buffer 562 of the first VRAM 560 provided in a one-to-one correspondence with the 2D display CPU 520 has a first frame area 562a and a second frame area 562b, and has a one-to-one correspondence with the 3D display CPU 530. The second VRAM 570 provided corresponding to the above has a first frame region 572a and a second frame region 572b. Each of these frame regions 562a, 562b, 572a, 572b is set to a capacity capable of storing drawing data for one frame.

  Specifically, each of the frame regions 562a, 562b, 572a, and 572b has a large number of unit areas (unit setting regions) corresponding to dots (pixels) of the liquid crystal display unit 94b (that is, the display screen 94a) at a predetermined magnification. )It is included. Each unit area has a storage capacity capable of storing data for specifying which color to display. More specifically, a full color method is employed, and 256 colors can be set for each of R (red), G (green), and B (blue) in each dot. Corresponding to this, in each unit area, 1 byte (8 bits) is assigned to each RGB color. That is, each unit area has a storage capacity of at least 3 bytes.

  Note that the present invention is not limited to the full-color method, and for example, in a configuration that can display only 256 colors in each dot, the storage capacity required to store color information in each unit area may be 1 byte.

  Each frame buffer 562, 572 is provided with the first frame regions 562a, 572a and the second frame regions 562b, 572b, so that the drawing data created in one frame region is used for the symbol display device 94. In the situation where the drawing is executed, the creation of drawing data to be used in the future is executed for other frame regions. That is, in each of the frame buffers 562 and 572, a double buffer method is adopted.

  In the display circuit 584, an image signal corresponding to each dot of the liquid crystal display unit 94b is generated based on the drawing data created in any one of the frame regions 562a, 562b, 572a, 572b, and the image signal is The data is output to the symbol display device 94 via the output port 506 connected to the display circuit 584. The display circuit 584 also outputs a synchronization signal such as a horizontal synchronization signal or a vertical synchronization signal. The display circuit 584 is provided with a scaler 588 and an image signal output unit 587 in order to generate and output the image signal. The moving image decoder 583 decodes the moving image data transferred to the expansion buffers 561 and 571 of the VRAMs 560 and 570.

  Here, the process concerning the effect performed by the symbol display device 94 will be described. In the present embodiment, whether to perform the 2D correspondence display or the 3D correspondence display is determined when the hold information is transmitted from the main control device, not at the start of the game times. It has become. Therefore, in the following description, first, processing that is a premise for determining the display mode executed by the MPU 402 of the main control device 162 will be described.

<Pending information confirmation process>
First, the hold information confirmation process executed in the timer interrupt process will be described. As shown in the flowchart of FIG. 26, in the hold information confirmation process, first, in step S1001, the start hold storage numbers RaN and RbN stored in the hold areas Ra and Rb of the hold ball storage area 432 and the hold information are stored. The common holding number CRN stored in the total holding number storage area of the ball storage area 432 is read, and information on the holding number is stored in the register of the MPU 402. Thereafter, in steps S1002 to S1006, it is confirmed whether or not the winning information is included in the hold information acquired by the current winning.

  Specifically, first, in step S1002, jackpot determination information among the hold information acquired in step S304 based on the current winning to the upper operating port 83a or the lower operating port 83b, that is, the acquired jackpot random number counter Know the value of C1.

  In a succeeding step S1003, it is determined whether or not the low probability mode is set. Specifically, it is determined whether or not the current lottery mode is the low probability mode by determining whether or not the high probability mode flag is stored in the various flag storage areas 435 of the RAM 404. If the mode is the low probability mode, the process proceeds to step S1004, and the information for determining the jackpot (the value of the jackpot random number counter C1) grasped in step S1002 with reference to the low probability mode determination table is information corresponding to the jackpot winning. Determine if it is in the group. In the case of the high probability mode, the process proceeds to step S1005, and the jackpot determination information (value of the jackpot random number counter C1) grasped in step S302 with reference to the above-described high probability mode success / failure table is a jackpot. Specify whether it is included in the information set as a winner.

  After step S1004 or step S1005, the process proceeds to step S1006, and it is determined whether or not the jackpot determination information (value of the jackpot random number counter C1) grasped in step S1002 corresponds to the jackpot winning. If it corresponds to the jackpot winning, the jackpot information is stored in the register of the MPU 402 in step S1007, and the confirmation processing of the reservation information is finished as it is.

  On the other hand, if a negative determination is made in step S1006, the process proceeds to step S1008. In step S1008, outreach reach information acquired in step S304 based on the current winning of the upper operating port 83a or the lower operating port 83b, that is, information for determining reach reach, that is, the value of the acquired reach random number counter C3 is grasped. .

  In the subsequent step S1009, the reach determination table storage area (reach determination information group storage means) 426 of the ROM 403 is referred to and the reach determination table (reach determination information group) is grasped in step S1008. It is specified whether the information for reach determination (the value of the reach random number counter C3) is included in the information set as the reach winning.

  After executing the processing of step S1009, the process proceeds to step S1010, and it is determined whether or not the reach determination information (value of the reach random number counter C3) grasped in step S1008 corresponds to the occurrence of reach. If it corresponds to the occurrence of reach, in step S1011, the reach generation information is stored in the register of the MPU 402, and then the present confirmation process is terminated. On the other hand, if it does not correspond to the occurrence of reach, this confirmation process is terminated as it is.

<Hold command setting process>
Next, the hold command setting process will be described with reference to the flowchart of FIG.

  In the hold command setting process, first, in step S1101, it is determined whether or not jackpot information is stored in the register of the MPU 402, so that information for determining the jackpot in the immediately preceding hold information confirmation process (FIG. 26). It is determined whether or not is identified as corresponding to the jackpot winning. If jackpot information is stored, the process advances to step S1102 to set a jackpot correspondence pending command. Note that the setting of the command and various commands described later are performed by storing command information in a command setting area provided in the RAM 404.

  On the other hand, if a negative determination is made in step S1101, that is, if it is determined that no jackpot information is stored in the register of the MPU 402, the process proceeds to step S1103, and whether or not reach occurrence information is stored in the register of the MPU 402. It is determined whether or not the information for reach determination is identified as corresponding to the occurrence of reach in the immediately preceding hold information confirmation process (FIG. 26). If the reach occurrence information is stored, a release reach hold command is set in step S1104, and if the reach occurrence information is not stored, a complete release hold command is set in step S1105.

  When the hold command is set in steps S1102, S1104, and S1105, the fluctuation display time is determined with reference to the stored value of the jackpot type counter C2, the value of the fluctuation type counter CS, etc. The time-consuming information is stored in the pending command. In determining the variable display time, the variable display time table is referred to in the same manner as the variable display time setting process shown in step S708. The hold command set in this way is transmitted to the display control device 500, and the display control device 500 can grasp the variation display mode of the symbol and the like based on the hold command.

  After executing the command setting process of any one of step S1102, step S1104, and step S1105, in step S1106, a process of setting the number of hold information for the hold command is executed. Specifically, as the processing, the hold command information set as described above is configured as information of a plurality of bytes, and information indicating that the command is a hold command or a hold command for some of the bits. Are included, and information on the number of holds can be set. In this case, in step S1106, the information on the number of holdings stored in the register of the MPU 402 in step S1001 in the confirmation processing of the previous holding information (FIG. 26) is first read, and thereafter, in the holding command already set. The read information on the reserved number is stored in the reserved number information bit by an arithmetic processing such as logical sum. Thereby, with respect to the hold command set in any of the processes of step S1102, step S1104, and step S1105, information for specifying the number of hold information corresponding to the hold command Will be included. After executing the process of step S1106 described in detail above, the hold command setting process is terminated.

  Note that the hold command including the information on the number of hold in step S1106 is transmitted to the sound lamp control device 143 by the external output process in step S401 in the next normal process (FIG. 18). The voice lamp control device 143 receives the hold command and specifies that the hold information has increased. In addition, the voice lamp control device 143 transmits the hold command to the display control device 500 while maintaining the form. The display control device 500 executes image data preparation processing based on the received hold command. The preparation process will be described in detail later.

  In addition, the setting method of the hold command is determined by whether or not the display control device 500 holds the jackpot winning, the jackpot type at the time of jackpot winning, the presence or absence of reach when the jackpot winning is not set, in other words, Any design can be used as long as it can identify the variation display mode of the symbol. For example, a combination of a jackpot corresponding pending command, a miss reach pending command, and a complete miss pending command is individually set corresponding to the number of each pending, and in the pending command setting process, the pending information confirmation process (see FIG. It is also possible to adopt a configuration in which one pending command is selected according to the confirmation result in 26).

  Next, referring to the flowcharts of FIGS. 28 and 29, when a command is transmitted from the main control device 162 to the sound lamp control device 143, among the command response processes executed by the sound lamp control device 143 What corresponds to a command (hereinafter referred to as a pending command handling process) will be described. The pending command handling process is repeatedly activated at a predetermined cycle (for example, 2 msec cycle).

<Processing for pending command>
As shown in the flowchart of FIG. 28, in the pending command handling process, it is first determined in step S1201 whether a jackpot handling command has been received. Here, the MPU 452 of the sound lamp control device 143 receives a command from the main control device 162, and the received command is temporarily stored in the command storage area 471 of the RAM 454. The command storage area 471 is configured as a ring buffer that can store a plurality of commands individually and can be read from the previously stored commands. Even when a plurality of commands are received at the same time, Processing corresponding to each command can be executed satisfactorily. When determining in step S1201, it is determined whether or not a big hit correspondence pending command has been received in the current read target area in the command storage area 471. It should be noted that this command read configuration is the same for the following command read.

  If a jackpot corresponding hold command has been received, information on the number of holds included in the command received this time is specified in step S1202, and the information on the specified number of holds is stored in various counter areas 472 of the RAM 454. Set to the erase counter. As will be described later, the information on the number of reserves set in the erasure counter is updated so as to be decremented by 1 every time a new game is started.

  After the erasure counter is set in step S1202, the process proceeds to step S1203 to execute a big hit correspondence setting process. Hereinafter, the jackpot correspondence setting process will be described with reference to the flowchart of FIG.

<Big hit correspondence setting process>
In the big hit correspondence setting process, it is first determined in step S1301 whether or not the hold command received this time corresponds to any one of super reach A to super reach C. In this embodiment, a plurality of symbol variation display modes are set so that the jackpot winning expectation degree is different, and a configuration in which the jackpot winning expectation degree in game times is notified by each variation display mode is adopted. However, in step S1301, the variable display pattern storage area 462 of the ROM 453 is referred to and it is determined whether or not the hold command corresponds to super reach A to super reach C.

  If a negative determination is made in step S1301, the present setting process is terminated as it is. On the other hand, if an affirmative determination is made in step S1301, that is, if there is information corresponding to super reach A to super reach C in the hold information, the process proceeds to step S1302. In step S1302, the lottery table corresponding to jackpot stored in the lottery table storage area 461 of the ROM 453 is referred to, and in the subsequent step S1303, a lottery process for determining whether or not to execute the 3D effect is executed.

  Specifically, the counter value (numerical information) for 3D effect lottery is read from the lottery counter stored in the various counter areas 472 of the RAM 454, and the lottery table storage area (3D effect lottery information group storage means) of the ROM 453 is read out. ) Referring to the 3D effect lottery table (3D effect lottery information group) stored in 461, it is determined whether or not the read counter value for the lottery corresponds to the winning result. Note that the value of the lottery counter is updated (incremented by 1) every time the pending command handling process (FIG. 28) is started, that is, at a cycle of about 2 msec.

  After executing the process of step S1303, the process proceeds to step S1304, and it is determined whether or not the 3D effect has been won. If a negative determination is made in step S1304, the present setting process is terminated as it is. On the other hand, if a positive determination is made in step S1304, the process proceeds to step S1305.

  After executing the update process of the hold command to be transmitted to the display control device 500 in step S1305, the jackpot correspondence setting process is terminated. Specifically, information indicating that the 3D effect should be executed is added while maintaining the form of the hold command received this time. Thereby, in the display control device 500, by receiving the hold command, the hold information related to the hold command from the hold command, specifically, the type of the variable display pattern, the presence / absence of the jackpot, the possibility of executing the 3D effect, etc. Can be grasped.

  Returning to the description of the hold command response process (FIG. 28) again, after executing the process of step S1203, the process proceeds to step S1204, where the hold information storage area 474 of the RAM 454 (specifically, hold in the first area Rc1 to the eighth area Rc8). The hold information corresponding to the jackpot (specifically, information relating to whether or not the 3D effect is available) is set in the area where the information is not stored (the youngest area), and the hold command handling process is terminated.

  Here, a supplementary description will be given of the configuration relating to the hold information storage area 474. The hold information storage area 474 includes the first area Rc1 to the eighth area Rc8 as described above, and is configured to store one hold information for each area. The hold information stored in each of the areas Rc1 to Rc8 is sequentially shifted to the lower area side when a shift command is received from the main controller 162, that is, when a game is started. Specifically, the data in the first area Rc1 is cleared and the second area Rc2 → first area Rc1, third area Rc3 → second area Rc2, fourth area Rc4 → third area Rc3. The data in each area is shifted, such as area Rc8 → seventh area Rc7. In the holding ball storage area 432 of the main control device 162, the upper working port holding area Ra and the lower working port holding area Rb are distinguished from each other, but the holding information storage area of the voice lamp control device 143 is provided. In 474, the hold information is stored in a time-series manner regardless of the destination.

  Returning to the description of step S1201 again, if it is determined in step S1201 that the jackpot corresponding hold command has not been received, the process proceeds to step S1205. In step S1205, it is determined whether or not a detach reach hold command has been received.

  If an affirmative determination is made in step S1205, that is, if it is determined that an outreach correspondence hold command has been received, the process advances to step S1206 to execute outreach correspondence setting processing. Here, with reference to the flowchart of FIG. 29B, the outreach correspondence setting process will be described.

<Outgoing reach support setting process>
In the outreach correspondence setting process, first, in step S1401, it is determined whether or not the hold command received this time corresponds to any one of super reach A to super reach C. In this embodiment, a plurality of symbol variation display modes are set so that the jackpot winning expectation degree is different, and a configuration in which the jackpot winning expectation degree in game times is notified by each variation display mode is adopted. However, in step S1301, the variable display pattern storage area 462 of the ROM 453 is referred to and it is determined whether or not the hold command corresponds to super reach A to super reach C.

  If a negative determination is made in step S1401, the present setting process is terminated as it is. On the other hand, if an affirmative determination is made in step S1401, that is, if there is information corresponding to super reach A to super reach C in the hold information, the process proceeds to step S1402. In step S1402, the lottery process table corresponding to detachment stored in the lottery table storage area 461 of the ROM 453 is referred to, and in the subsequent step S1403, a lottery process for determining whether or not to execute the 3D effect is executed.

  Specifically, the counter value (numerical information) for 3D effect lottery is read from the lottery counter stored in the various counter areas 472 of the RAM 454, and the lottery table storage area (3D effect lottery information group storage means) of the ROM 453 is read out. ) Referring to the 3D effect lottery table (3D effect lottery information group) stored in 461, it is determined whether or not the read counter value for the lottery corresponds to the winning result. Note that the value of the lottery counter is updated (incremented by 1) every time the pending command handling process (FIG. 28) is started, that is, at a cycle of about 2 msec.

  After executing the process of step S1403, the process proceeds to step S1404 to determine whether or not the 3D effect has been won. If a negative determination is made in step S1404, the present setting process is terminated as it is. On the other hand, if a positive determination is made in step S1404, the process proceeds to step S1405.

  After executing the update process of the hold command to be transmitted to the display control device 500 in step S1405, the jackpot correspondence setting process is terminated. Specifically, information indicating that the 3D effect should be executed is added while maintaining the form of the hold command received this time. Thereby, the display control device 500 receives this hold command, and from this hold command, holds information related to the hold command, specifically, the type of the variable display pattern, the presence / absence of jackpot, and whether or not the 3D effect can be executed. Etc. can be grasped.

  Returning to the description of the hold command response process (FIG. 28) again, after executing the process of step S1206, the process proceeds to step S1204, and the hold information storage area 474 of the RAM 454 (specifically, hold in the first area Rc1 to the eighth area Rc8). The hold information (specifically, information related to whether or not the 3D effect is available) corresponding to the disengagement is set in the youngest area among the areas in which no information is stored, and the hold command handling process is terminated.

  In the hold command handling process described in detail above, whether or not to execute the 3D effect is determined with reference to the hold command, and the result is stored in the hold information storage area 474.

  The sound lamp control device 143 is configured to specify a production mode such as a variation display mode again when a variation start command is received from the main control device 162. At this time, whether or not to perform the 3D effect is specified with reference to the area corresponding to the change start command in the hold information storage area 474. In other words, whether or not the 3D effect is possible is configured to be specified when the hold command is received before receiving the change start command, and when the change start command is received, only the specified result is referred to. The lottery of the 3D effect is not performed again.

<Processing executed by display control device 500>
Next, various processes executed by the display control apparatus 500 will be described. In the display control device 500, a main process that is started when supply of operating power to the display control device 500 is started or when the pachinko machine 10 is reset, a command (strobe) from the sound lamp control device 143 is started. Signal response), a command response process that is activated with the highest priority regardless of the process being executed at that time, and a timer interrupt that is repeatedly activated at a predetermined period (specifically, a 20 msec period) Processing. These various processes are executed by the central CPU 510, and the display CPUs 520, 530 and the like operate according to commands from the central CPU 510. In the present embodiment, the overall control is executed by the central CPU 510, and various processing for generating drawing data is executed by the display CPUs 520 and 530, thereby reducing the processing load on the display control device 500. Distributed.

  In the present embodiment, an increase in processing load on the display control device 500 is suppressed by devising reading / erasing of 3D image data when performing 3D rendering. Hereinafter, various processes related to reading / erasing 3D image data will be described.

<Command processing>
First, with reference to the flowchart of FIG. 30A, the pending command handling process constituting the command handling process will be described.

  In the hold command handling process, first, in step S1501, it is determined whether or not a hold command is received from the main control device 162 through the voice lamp control device 143.

  If a negative determination is made in step S1501, the command determination process is terminated as it is. If an affirmative determination is made in step S1501, the process advances to step S1502 to execute a hold information setting process. The hold information related to the hold command received this time in the hold information storage area 554 of the work RAM 550 (more specifically, the youngest area of the first area Rd1 to the eighth area Rd8 where no hold information is stored) , Information on whether or not the 3D effect is possible) is set, and the pending command handling process is terminated.

  Here, a supplementary description will be given of the configuration relating to the hold information storage area 554. The hold information storage area 554 includes the first area Rd1 to the eighth area Rd8 as described above, and is configured to store one hold information for each area. The hold information stored in each of the areas Rd1 to Rd8 is sequentially shifted to the lower area side when a shift command is received from the main controller 162, that is, when a game is started. Specifically, the data in the first area Rd1 is cleared, and the second area Rd2 → the first area Rd1, the third area Rd3 → the second area Rd2, the fourth area Rd4 → the third area Rd3,. The data in each area is shifted such as area Rd8 → seventh area Rd7. In the holding ball storage area 432 of the main control device 162, the upper working port holding area Ra and the lower working port holding area Rb are distinguished from each other, but the holding information storage area of the voice lamp control device 143 is provided. In 474, the hold information is stored in a time-series manner regardless of the destination.

  Further, the hold information stored in the hold information storage area 554 in the display control device 500 and the hold information storage area 474 in the sound lamp control device 143 are the same.

  Returning to the description of the hold command response process again, after executing the process of step S1502, the process proceeds to step S1503 to determine whether or not the current hold information is hold information related to the 3D effect. If a negative determination is made in step S1503, the pending command handling process is terminated as it is.

  On the other hand, if an affirmative determination is made in step S1503, the 3D image data reading start timing setting process is executed in step S1504, and then the pending command handling process ends.

  Here, with reference to the flowchart of FIG. 30B, the setting process of the read start timing of 3D image data will be described.

<3D Image Data Reading Start Timing Setting Process>
In the setting process, first, whether or not the hold information related to the 3D effect exists in the hold information stored in advance in step S1601 or whether or not the game time currently being executed is a game time related to the 3D effect is determined. Determine.

  If a negative determination is made in step S1601, the process proceeds to step S1602, and after the 3D image data reading start process is executed, the present setting process ends. In the 3D image data read start processing, 3D image data stored in the memory module 540 (specifically, compressed data of the 3D image) is read and stored in the decompression buffer 571 of the second VRAM 570 in a decompressed state. I do.

  About 3D image data in this embodiment, compared to other 2D image data, the amount of data is large, and the time required for reading and compression is increased, but when a hold command is received, By starting the reading of data, it is possible to suitably secure a data preparation period until the 3D image effect is actually executed.

  If a negative determination is made in step S1601, the process proceeds to step S1603. In step S1603, it is determined whether the hold information that has been affirmative in step S1601 and the hold information received this time correspond to the same 3D effect. If it is determined that all the hold information corresponds to the same 3D effect, the present setting process ends.

  On the other hand, when a negative determination is made in step S1603, that is, when there is a piece of hold information stored in advance corresponding to a 3D effect different from the hold information received this time, or currently in progress If the game time corresponds to a 3D effect different from the hold information received this time, the process proceeds to step S1604.

  In step S1604, it is determined whether the reach display is currently being performed or the game times in which the reach display is executed. If a negative determination is made in step S1604, the 3D image data reading start process is executed in step S1602, and then the setting process ends.

  If an affirmative determination is made in step S1604, a delay process for the 3D image data read start timing is executed in step S1605, and then the present setting process is terminated. A supplementary explanation will be given of the delay processing in step S1605. When there is a piece of hold information stored earlier than the hold information received this time, no reach display is performed, and a game time related to the hold information is started. When there is no hold information that is not displayed in reach among the hold information stored before the hold information received this time, the 3D image data A read start flag for specifying the read start timing is stored in various flag storage areas 553 of the work RAM 550 so as to start reading.

<Variable display control processing>
Next, the variable display control process performed as part of the timer interrupt process will be described with reference to the flowcharts of FIGS.

  In the variable display control process, first, in step S1701, it is determined whether or not the variable display of symbols for one game is executed on the symbol display device 94. If the change display of the symbols for one game is not performed, it is determined in step S1702 whether or not the change command transmitted from the main controller 162 is received. If the change command has not been received, the change display control process is terminated as it is. If the change command has been received, the change start control process is terminated after the change start process is executed in step S1703. The variation start processing is processing for starting symbol variation display on the symbol display device 94 based on the reception of the variation command transmitted from the main control device 162.

  Here, the variation start process will be described with reference to the flowchart of FIG. In the variation starting process, first, an effect mode specifying process is executed in step S1801. Specifically, hold information stored in the hold information storage area 554 of the work RAM 550 (specifically, information related to the variable display time, information on whether or not to change), and a variable display pattern table also stored in the work RAM 550 are used. Referring to the symbol display device 94, the symbol variation display mode is specified.

  After executing the specifying process in step S1801, the process proceeds to step S1802, and it is determined whether or not there is an instruction to start reading 3D image data. Specifically, it is determined whether or not a read start flag is stored in various flag storage areas 553 of work RAM 550. If a negative determination is made in step S1802, this variation start processing is terminated as it is. On the other hand, if an affirmative determination is made in step S1802, 3D image data reading start processing designated in subsequent step S1803 is executed, and then the variation start processing ends. By executing the processing of step S1803, the specified data among the compressed data of the 3D image stored in the memory module 540 is stored in the decompressed buffer 571 of the second VRAM 570 in a decompressed state.

  Returning to the description of FIG. 31 again, if an affirmative determination is made in step S1701, that is, if a change display of symbols for one game is being performed, the process proceeds to step S1704. In step S1704, it is determined whether a change end command transmitted from main controller 162 has been received. If the change end command has not been received, the changing process for controlling the symbol display device 94 when the symbol change display is being executed is executed. Specifically, after executing the processing of steps S1705 to S1706 constituting the processing for variation, this variation display control processing is terminated.

  In step S1705, it is determined whether or not the current game time is a game time for executing a 3D effect. Specifically, it is determined whether or not a 3D effect execution flag is stored in various flag storage areas 553 of the work RAM 550. If an affirmative determination is made in step S1705, the process proceeds to step S1706, and it is determined whether or not it is the switching timing from the 2D effect to the 3D effect. If an affirmative determination is made in step S1706, the change display control process is terminated after the effect switching process is executed in step S1707. On the other hand, if a negative determination is made in either step S1705 or step S1706, the present variation display control process is terminated as it is.

  Here, the effect switching process executed in step S1707 will be described with reference to the flowchart of FIG.

<Processing for effect switching>
In the effect switching process, it is first determined in step S1901 whether or not the reading of 3D image data has been completed. If an affirmative determination is made in step S1901, the process proceeds to step S1902, and the 3D display CPU is activated. Specifically, the validation flag is stored in various flag storage areas 553 of the work RAM 550. This flag is referred to in V interrupt processing described later, and the operation of the 3D display CPU 530 is allowed while the flag is stored. Note that the determination timing of step S1706 described above is much earlier than when the 3D effect is actually executed on the symbol display device 94. This is a device for ensuring the period required for the preparation process (for example, creation of a drawing list) for 3D images.

  On the other hand, if a negative determination is made in step S1901, that is, if it is determined that some trouble or the like has occurred and reading of the 3D image data has not been completed, the process proceeds to step S1903 and various flag storage areas 553 of the work RAM 550 are processed. In addition, a substitute flag for substituting the 2D display CPU 520 is stored. When this flag is stored, the 3D effect is canceled and the 2D effect is continued.

  Returning to the description of FIG. 31 again, if an affirmative determination is made in step S1704, that is, if a change end command is received, the change end control process is executed in step S1708, and then the change display control process is executed. Exit. In the process for ending the change, the symbol display device 94 is controlled so that a predetermined symbol combination is stopped and displayed on the display screen 94a of the symbol display device 94 (so as to be confirmed).

  Here, with reference to the flowchart of FIG. 33, various processes related to the 3D effect in the process for ending the change will be described. In the change end process, it is determined in step S2001 whether the 3D effect has been completed. If a negative determination is made in step S2001, the process for ending variation is terminated as it is. At this time, if the above-described validation flag and substitute flag are stored in the various flag storage area 553 of the work RAM 550, these flags are deleted.

  When an affirmative determination is made in step S2001, the process proceeds to step S2002, and processing for switching the drawing CPU to the 2D display CPU 520 is executed. Specifically, the validation flags stored in the various flag storage areas 553 of the work RAM 550 are deleted. Thereby, in the subsequent processing, the 3D display CPU 530 is invalidated, and the 2D display CPU 520 is exclusively used for creating the drawing list.

  After executing the process of step S2002, various processes related to erasure of 3D image data after step S2003 are executed.

  Specifically, first, in step S2003, it is determined whether or not the hold information relating to the same 3D image data as the 3D image data used this time is stored in the hold information storage area of the work RAM 550. If a negative determination is made in step S2003, 3D image data erasure processing is executed in step S2004. Specifically, the 3D image data stored in the expansion buffer 571 of the second VRAM 570 is deleted. Thereafter, the variation end processing is terminated.

  On the other hand, if an affirmative determination is made in step S2003, that is, if a 3D effect relating to the same 3D image is scheduled to be executed in the subsequent game round, the process proceeds to step S2005. In step S2005, it is determined whether there is another game time between the current game time and the next game time in which the same 3D effect is executed. If an affirmative determination is made in step S2005, 3D image data erasure processing is executed in step S2004, and then the variation end processing ends. On the other hand, if an affirmative determination is made in step S2005, this variation end processing is terminated without deleting the 3D image data stored in the expansion buffer 571 of the second VRAM 570. By erasing the 3D image data in this manner, the 3D image data is held in the development buffer 571 until a 3D effect is executed at the next game time related to the 3D image data. Become.

  Next, the V interrupt process constituting the timer interrupt process will be described with reference to the flowchart of FIG.

  When the image signal for one frame is output to the symbol display device 94, the VDP 580 starts outputting the image signal from the dot at the upper left corner of the display screen 94a, and on the horizontal line including the dot at one end. Image signals are sequentially output for the arranged dots, and image signals are output from the left to the right dots in order from the top for each horizontal line. Then, an image signal is finally output for the dots in the lower right corner of the display screen 94a. In this case, the VDP 580 outputs a V interrupt signal to the central CPU 510 at the timing when the image signal is output to the last dot, so that the central CPU 510 recognizes that the update of one frame image has been completed. The output period of this V interrupt signal is 20 msec. In this regard, the V interrupt processing can be regarded as being started in synchronization with reception of the V interrupt signal. However, even if the V interrupt signal is not received, the V interrupt process is newly started when 20 msec has elapsed since the previous V interrupt process was started. After receiving the V interrupt signal, an operation command is output to either the 2D display CPU 520 or the 3D display CPU 530 as the game progresses.

<V interrupt processing>
In the V interrupt processing, first, command analysis processing is executed in step S2101. Specifically, the contents of the command stored in the command storage area 551 of the work RAM 550 are analyzed. In the subsequent step S2102, it is determined whether or not a new command has been received based on the analysis result in step S2101. If a new command has been received, command response processing is executed in step S2103.

  In the command handling process, a data table for executing a program corresponding to the received command is grasped. The data table defines the processing necessary to display an image for one frame at each image update timing when displaying a moving image corresponding to the received command on the display screen 94a of the symbol display device 94. Information group.

  Here, the commands received by the overall CPU 510 from the sound lamp control device 143 include a change command, a type command, a change end command, an opening command, an ending command, and the like as described above. When these commands are received, a data table necessary for executing the game turning effect corresponding to each command on the symbol display device 94 is grasped. In addition, when a change end command is received, a data table necessary for finally stopping the currently executed game turning effect is grasped.

  In addition, since the variation display mode for each game time has been specified in the variation start processing already described, the command response processing is executed based on the identified information.

  Of the data tables necessary for executing the game turn effect, the data table necessary for starting the game turn effect has already been transferred to the normal area of the work RAM 550 as the normal program data. In addition, a data table necessary for finally stopping the game turning effect, a data table necessary for starting the jackpot effect, and a data table necessary for executing the demonstration display are also used as regular program data in the work RAM 550. Already transferred to the area. Further, other program data necessary for executing processing based on these data tables has already been transferred to the regular area of the work RAM 550 as regular program data.

  After executing the command response processing in step S2103, it is determined in step S2104 whether or not advance transfer of program data is necessary. The data determined to be necessary here is a data table that is determined not to be necessary in step S2103 and is necessary for executing processing based on the data table that is not included in the regular program data. Other program data.

  If the program data needs to be transferred in advance, in step S2105, the memory module 540 is requested to transfer the necessary program data. The memory module 540 starts the transfer of program data to the change area of the work RAM 550 by receiving an address designation command corresponding to the program data from the overall CPU 510.

  That is, when a new command is received, the overall CPU 510 determines whether or not new program data needs to be transferred at the timing when the command is analyzed, and if necessary, issues a program data transfer request. As a result, the advance transfer of the program data can be started at the earliest possible timing. Incidentally, when this transfer request is made, not only the logical address where the program data to be transferred is stored but also the address of the transfer destination is designated. In addition, since the data table and program data including the processing at the first timing in executing the processing corresponding to the command are transferred as the regular program data at the initial startup, the processing corresponding to the command is received after receiving the command. There is no waiting time before it starts.

  When a negative determination is made in step S2102, a negative determination is made in step S2104, or after the processing of step S2105 is executed, the process proceeds to step S2106. In step S2106, pointer update processing is executed. In the pointer update process, the pointer information set in the data table is updated to advance by one frame. As a result, the central CPU 510 can grasp processing necessary to display an image for one frame corresponding to the current update timing.

  In a succeeding step S2107, a task process is executed. In the task processing, in order to display an image for one frame corresponding to the current update timing, a command for calculation is given to the display CPUs 520 and 530 in order to perform calculation of parameters necessary for instructing drawing to the VDP 580. Output. Details of the task processing will be described later.

  In a succeeding step S2108, a drawing list output process is executed. In the drawing list output process, a list creation command is output to the display CPUs 520 and 530 in order to create a drawing list for displaying an image for one frame corresponding to the update timing related to the current processing time. The display CPUs 520 and 530 that have received the command create a drawing list and transmit the created drawing list to the VDP 580. In this case, in the drawing list, an image grasped in the immediately preceding task process is set as a drawing target, and parameter information updated in the task process is set together. The VDP 580 creates drawing data in one of the frame areas of the VRAMs 560 and 570 according to the drawing list. The processing in this VDP 580 will be described in detail later.

  In a succeeding step S2109, it is determined whether or not the program data is being transferred. If the program data is being transferred, the V interrupt processing is terminated as it is. On the other hand, if the program data is not being transferred, whether or not the image data needs to be transferred by referring to the information set as the update timing after the current state in the currently set data table in step S2110. Determine whether.

  Of the various image data, the image data used for the drawing instruction based on the regular program data is set as the regular image data. That is, as the regular image data, the image data necessary for starting the game effect, the image data necessary for starting the jackpot effect, and the image data necessary for executing the demonstration display are set. . These image data transfer requests have already been made to the memory module 540 in the initial setting process in the main process. When the general CPU 510 receives a command, the transfer is completed.

  Note that the present invention is not limited to this configuration, and at least the processing after step S2106 may not be executed until the transfer of the regular image data is completed. In this case, after the main process is started by the central CPU 510 and the initial image is displayed by the symbol display device 94, the display of the initial image is continued until the transfer of the regular image data is completed. . In addition, when transferring the initial image data, simple symbol data with a data capacity smaller than the total data capacity of the image data required to display the symbol variation is transferred at the same time, and the transfer of the regular image data group is completed. If a change command is received in a situation where the change is not received, a change display with a simple symbol may be performed.

  The image data determined to be transferred in step S2110 is image data that is required at the update timing after the current state in the currently set data table, and is not included in the regular image data. It is. If it is not necessary to transfer the image data, the V interrupt process is terminated. If it is necessary to transfer the image data, the V interrupt processing is terminated after making a transfer request for the necessary image data to the memory module 540 in step S2111. In the memory module 540, upon receiving an address designation command corresponding to the image data, transfer of the image data to the change area of the development buffers 561 and 571 is started.

  That is, the overall CPU 510 refers to the currently set data table to determine whether or not new image data needs to be transferred. If necessary, the image data transfer request is made, and the VDP 580 creates drawing data. The image data is pre-transferred before the timing required for this is reached. Thereby, the drawing data can be smoothly created in the VDP 580. Incidentally, when this transfer request is made, not only the logical address at which the image data to be transferred is stored, but also the transfer destination address is designated. In addition, since the regular image data is transferred at the time of initial startup, no waiting time is generated after the command is received until the display of the corresponding image is started.

  Here, by executing the processing of step S2109, the transfer of the program data has priority over the transfer of the image data. Even if the transfer of program data is prioritized in this way, the necessity of transferring image data is determined with reference to the data table, so even if transfer is temporarily avoided in step S2109. Then, in the subsequent V interrupt process, the necessity for transfer is determined and a transfer request is executed. As a result, the transfer timing of the program data and the image data can be prevented from overlapping, and the transfer of the program data can be prioritized.

<Processing for tasks>
Here, the task processing in step S2107 will be described. In the present embodiment, 2D image task processing and 3D image task processing are set. The former is executed by the 2D display CPU 520, and the latter is executed by the 3D display CPU 530. It has a configuration.

  The task processing will be briefly described below. In the task process, first, a control start setting process is executed. In the setting process for starting control, the display CPUs 520 and 530 execute processing for setting an individual image for newly starting control (calculation) in the current processing time. The individual image is one 2D image defined by still image data such as back image data, one 3D image defined by a combination of object image data and texture image data, or the like. That is.

  After executing the control start setting process, the background calculation process is executed. In the background calculation processing, the current control update target is grasped among the rearmost still image, the background sprite, and the background plate polygon that constitute the background image. In addition, with respect to the grasped control update target, coordinates in the world coordinate system (on the virtual two-dimensional plane or virtual three-dimensional space), rotation angle, scale, light information for adding light and darkness, and the camera for performing projection A process of calculating and deriving various parameters necessary for creating a drawing list such as information and Z test designation is executed. Then, the control information is updated by writing the derived various parameters in an area secured in the work RAM 550 corresponding to each individual image.

  Subsequently, the effect calculation process is executed. In the effect calculation processing, the current control update target is grasped among effect sprites that constitute an effect image to be displayed in various effects such as reach display, notice display, and jackpot effect. The various parameters are derived for the grasped control update target. Then, the control information is updated by writing the derived various parameters in an area secured in the work RAM 550 corresponding to each individual image.

  Thereafter, symbol calculation processing is executed. In the symbol computation process, the current control update target is grasped from symbols subject to variable display in each game round. The various parameters are derived for the grasped control update target. Then, the control information is updated by writing the derived various parameters in an area secured in the work RAM 550 corresponding to each individual image.

  Incidentally, in each of these processes, animation data set so as to change various parameters of the individual image according to a specific pattern every time the image update timing comes. This animation data is determined according to the type of individual image. Further, the animation data is transferred in advance to the work RAM 550 before the display CPUs 520 and 530 need to read the data.

  Thereafter, the process of grasping the placement target in the world coordinate system is executed. In the process of grasping the arrangement target in the world coordinate system, a process of grasping the individual image set as the drawing target in the current drawing list among the individual images that have been controlled and updated by the above processes is executed. The grasp is performed based on the currently set data table. The individual image grasped here is set as a drawing target in the drawing list.

  The grasp is performed by executing a predetermined calculation with reference to information on the currently set drawing range and information on coordinates, rotation angles, and scales of various individual images. The individual image grasped here is set as a drawing target in the drawing list. In this way, it is necessary to select individual images to be displayed in the VDP 580 by making the individual images specified in the drawing list not only all individual images for which control has been started, but only individual images to be displayed. In addition, even if it is not selected, there is no need to perform drawing processing for individual images that are not display targets. Thereby, the processing load of the VDP 580 can be reduced.

<Basic processing in VDP580>
Next, basic processing executed by the VDP 580 will be described.

  In the VDP 580, processing for setting the value of the register 582 based on the command transmitted from the display CPUs 520 and 530, and drawing data in the frame area of the frame buffer 562 and 572 based on the drawing list transmitted from the display CPUs 520 and 530 are created. And a process of outputting an image signal to the symbol display device 94 based on the drawing data created in the frame area.

  Of the above processes, the process of setting the value of the register 582 is executed each time a command is received by a circuit (not shown) attached to the I / F 585 for the display CPUs 520 and 530. Further, the process of creating the drawing data is repeatedly activated by the control unit 581 at a predetermined cycle (for example, 1 msec). The process of outputting the image signal is executed by the display circuit 584 at a predetermined output start timing of the image signal.

  Hereinafter, the process of creating the drawing data will be described in detail. Prior to the description of the processing, the contents of the drawing list transmitted from the display CPUs 520 and 530 to the VDP 580 will be described.

  Header information is set in the drawing list. In the header information, information on a target buffer, which is information indicating which one of the first frame area and the second frame area is to be created, is set for an image of one frame related to the drawing list. Also, in the header information, presence / absence of decoding designation and address information to which moving image data to be decoded is transferred are set. In addition, various designation information is set in the header information. The contents of the various designation information will be described later.

  In the drawing list, in addition to the header information, a plurality of types of image data to be arranged in the world coordinate system are set when creating the drawing data this time, and information on the drawing order of each image data, Parameter information of each image data is set. More specifically, the drawing order information is set so as to be sequential numerical value information, and the parameter information is set in a one-to-one correspondence with each numerical information.

  In the present embodiment, 2D images and 3D images can be displayed on the symbol display device 94, and the drawing list is different for 2D images and 3D images. Is also different. Therefore, in the following description, first, a configuration relating to a 2D image will be described with reference to FIG.

  The drawing order for the 2D image is set so that the individual image desired to be displayed is positioned on the back side of the display screen 94a in the image for one frame first. The individual image refers to one still image defined by still image data such as background data and one sprite defined by sprite data such as symbol sprite data. In the drawing list of FIG. 35A, the background data is set as the first drawing target, the sprite data A is set as the second, the sprite data B is set as the third, and so on. Accordingly, the background data is first written in the drawing target frame regions 562a and 562b, and then the sprite data A is written so as to overlap the background data, and the sprite data B is further written. In the image for one frame, each individual image is displayed so that the front side is in the order of background image → effect image → design.

  In parameter information P (1), P (2), P (3),..., A plurality of types of parameters are set. Specifically, the background data parameter P (1), as shown in FIG. 35 (b), the address information of the area to which the background data is transferred in the VRAM 560 and the two-dimensional plane when the background data is written. Frame areas 562a and 562b with respect to the coordinates information indicating the position of the image, the rotation angle information indicating the rotation angle on the two-dimensional plane when the background data is written, and the size set as the initial state of the background data. Information on the scale indicating the magnification at the time of writing, information on the uniform α value indicating the entire transmission information (or transparency information) when writing the background data, and the α data designation indicating whether or not the α data is applied and the application target Information is set. The types of parameters are the same for the sprite data A as shown in FIG.

  Here, the coordinate information is not individually set for all the pixels constituting the image data, but one coordinate information is set for one image data. Specifically, one pixel at the center of the image data is set as a reference pixel for specifying coordinate information. In the VDP 580, it is possible to recognize that the designated coordinate information is one pixel at the center of the image data, and when the image data is arranged, the one pixel at the center is on the designated coordinate. . Thereby, the information capacity of the coordinate information to be specified for one image data in the 2D display CPU 520 can be suppressed. In addition, since the 2D display CPU 520 and the VDP 580 do not need to be able to recognize coordinates for all pixels of the image data, the program can be simplified.

  Incidentally, the reference pixel is not limited to the central pixel, and may be a corner pixel such as upper left or upper right. Since sprite data and still image data are basically defined as a rectangular shape, the reference pixel is easily recognized by the 2D display CPU 520 and the VDP 580 by using the corner pixel as the reference pixel.

  The uniform α value is transmission information applied to all dots of one image data, and is numerical information derived as a calculation result in the 2D display CPU 520. The uniform α value is uniformly applied to all the pixels of the image data. On the other hand, the α data is transmission information applied in units of pixels of background data and sprite data, and is stored in advance in the NAND flash memory as image data. The alpha data can have different transmission information for each pixel within the range of the same background data or the same sprite data. The α data has a larger data capacity than program data for setting a uniform α value.

  Since the uniform α value and α data are set as described above, the transparency of the background data and sprite data need not be finely controlled on a pixel-by-pixel basis, but should be controlled uniformly for all pixels. By being able to cope with a uniform α value, the required data capacity can be reduced, and by applying α data, the transparency can be finely controlled in units of pixels.

  Next, a configuration related to a 3D image will be described with reference to FIG.

  In the drawing list of FIG. 36A, the image data for the back is set as the first drawing target, the background object A is set as the second, the background object B is set as the third, and so on. Yes. Also, as the order after the background image data, the effect image data is set, for example, the effect object A is set as mth, the effect object B is set as m + 1, and so on. Yes. Further, as the order after the effect image data, symbol image data is set, for example, symbol object A is set as nth, symbol object B is set as n + 1th,... Yes.

  Parameter information P (1), P (2), P (3), ..., P (m), P (m + 1), ..., P (n), P (n + 1), ... A plurality of types of parameters are set. Specifically, the parameter P (1) of the image data for the back side, as shown in FIG. 36B, the address information of the area where the image data for the back side is transferred in the VRAM 570, and the image for the back side. Coordinate information (X value information, Y value information, Z value information) indicating the position in the world coordinate system when data is set, and in the world coordinate system when image data for the back is set Rotation angle information indicating the rotation angle, scale information indicating the magnification when setting to the world coordinate system, and image data for the back side with respect to the scale set as the initial state of the image data for the back side Uniform α value information indicating the entire transmission information (or transparency information) in the case of setting is set.

  Here, the coordinate information is individually set for all pixels of the image data for the object. The coordinate information is set for the object image data, but is not set for the texture image data. In the texture image data, the coordinate value of each pixel is determined in advance in association with each pixel of the object image data. This coordinate value is a UV coordinate value different from the coordinate value in the world coordinate system, and is stored in the NAND flash memory in a state of being attached to a combination of the image data for the object and the image data for the texture. . This UV coordinate value is referred to by the VDP 580 when texture mapping is performed.

  The parameter (P1) renders camera information including the coordinates and orientation information of the virtual camera and image data for the back when the image data for the back is projected on the virtual two-dimensional plane for drawing. And light information including information on the position and orientation of the virtual light source that determines the shadow in the case where the shadow is to be set.

  In addition, in the parameter (P1), Z test designation information indicating whether or not to apply the Z buffer method, which is a type of hidden surface removal method, is set. The Z buffer method refers to each pixel (or each voxel, each pixel) arranged on the Z axis from the viewpoint when a large number of objects or two-dimensional images overlap in the depth direction (Z axis direction) in the world coordinate system. Are sequentially referred to, and numerical information set for the pixel closest to the viewpoint is set in the corresponding unit area in the frame regions 572a and 572b. When the Z buffer method is applied, a Z buffer provided in the VRAM 570 is used.

  In addition to the Z buffer method, the Z sort method is set as a method for performing the hidden surface removal. The Z sort method is a processing method for depth adjustment in which numerical information set for each pixel is sequentially set in corresponding unit areas in the frame regions 572a and 572b for each pixel arranged on the Z axis. When the Z sort method is applied, the α value set for each pixel is referred to, and if necessary, the addition processing as described above and the fusion calculation processing as described above are executed. The Rukoto. The description of the specific processing configuration of the hidden surface processing by Z sort is omitted, but it is activated when an effect image is displayed.

  In addition, the parameter (P1) is created to display α data designation information indicating whether or not α data is applied and the application target, fog specification information indicating whether or not the fog is applied, and a background image. In addition, information for specifying another save indicating whether or not the drawing data for the background image is stored separately is set.

  Here, the α value is the transmission information of the corresponding pixel. As a method of setting the α value on the drawing list, there are a method of specifying the uniform α value and a method of specifying α data. The uniform α value is transmission information applied to all pixels of one image data, and is numerical information derived as a calculation result in the 3D display CPU 530. The uniform α value is uniformly applied to all the pixels of the image data. On the other hand, the α data is transmission information applied in units of pixels of 2D still image data or texture image data, and is stored in advance in the NAND flash memory as image data. The alpha data can make the transmission information different for each pixel within the range of the same still image data or the same texture image data. The α data has a larger data capacity than program data for setting a uniform α value.

  Since the α value and α data are set uniformly as described above, the transparency of 2D still image data and texture image data is not controlled finely in units of pixels, but is uniform for all pixels. In a situation where control is required, a uniform α value can be used to reduce the required data capacity, and by applying α data, the transparency can be finely controlled on a pixel-by-pixel basis.

  Further, fog is information for adjusting the degree of brightness with respect to a position in a predetermined direction, specifically, the Z-axis direction in the world coordinate system. Fog is used to express fog or inside a cave. Here, a single fog may be applied to the entire image for one frame. In this case, fog is applied to the image for one frame in a certain manner. Alternatively, a plurality of fogs may be applied to the entire image for one frame. In this case, when a fog similar to that of other objects is applied to an object arranged on the far side in the Z-axis direction, another fog is set for the object in a situation where the material is not too dark due to being too dark. It may be configured. Thereby, the effect by setting fog can be acquired, without impairing the said texture.

  Further, the separate storage means that the created drawing data for the background image is written and stored in a mode buffer provided separately from the frame regions 572a and 572b in order to use the drawn data for the background image as it is in the subsequent frames. . The mode buffer is provided with a first mode buffer and a second mode buffer so as to correspond to each display mode on a one-to-one basis.

  Also, with other parameters such as parameter P (2), as shown in FIG. 36 (c), among the various types of information shown in FIG. 36 (b), object information and Texture information is set. As such information, information on the address of the area to which the object or texture is transferred is set.

<Drawing process>
Next, drawing processing in the VDP 580 will be described with reference to the flowchart of FIG.

  First, in step S2201, it is determined whether or not creation of drawing data instructed in the already received drawing list has been completed. If creation of drawing data has been completed, it is determined in step S2202 whether a new drawing list has been received from the display CPUs 520 and 530. If a new drawing list has been received, the corresponding processing at the time of reception is executed in step S2203.

  In the corresponding processing at the time of reception, it is determined in which frame area the image for one frame corresponding to the drawing list received this time is created from the information of the target buffer included in the drawing list, and the recognized frame area Is set as the drawing data creation target.

  In a succeeding step S2204, a content grasping process is executed. In the content grasping process, the type of image data initially set as a drawing target in the drawing list is grasped, and various parameters of the image data are grasped. For example, in the case of sprite data, color palette data is applied to each dot of the bitmap image.

  In a succeeding step S2205, a writing process is executed. In the writing process, based on the grasping result of the contents grasping process in step S2204, the current drawing target image data is written in the frame region set as the creation target.

  On the other hand, if it is determined in step S2201 that drawing data instructed in the already received drawing list is being created, a drawing list counter update process is executed in step S2206. As a result, the drawing target is switched to the image data of the next drawing order. Then, the processing of step S2204 and step S2205 is executed for the switched image data. That is, by executing the drawing process a plurality of times, drawing data of an image for one frame designated by one drawing list is created.

  Note that the present invention is not limited to a configuration in which only one image data is processed in one drawing process, and a configuration in which a plurality of image data is processed in one drawing process may be used. However, the present invention is not limited to the configuration in which the same number of image data is processed in each processing time, and a configuration in which a different number of image data is processed in each processing time of the drawing processing may be employed.

  If a negative determination is made in step S2202, or after the processing of step S2205 is executed, it is determined in step S2207 whether or not one frame of image signal output has been completed in the display circuit 584. If not completed, the present drawing process is terminated as it is. If completed, the V interrupt signal is output to the display CPUs 520 and 530 in step S2208, and then the present drawing process is terminated.

  The drawing data for one frame is generated so as to be completed within a 20 msec cycle. An image signal is output from the display circuit 584 to the symbol display device 94 based on the created drawing data. Since the double buffer method is adopted as described above, the output of the image signal is output to the output. This is performed in parallel with the creation of drawing data for one frame after that frame. Note that the display circuit 584 has a selector circuit that alternately switches a frame area to be referred to every time when output of an image signal for one frame is completed, and the controller 581 performs drawing data by switching by the selector circuit. The frame region that is the target of drawing is restricted so as not to be the output target for outputting the image signal.

  Here, with reference to FIG.25 and FIG.38, the aspect of the display effect in this Embodiment is illustrated. FIG. 38 is a schematic diagram showing the action of the character on the display screen 94a. In the following description, super reach C is exemplified, but the general flow of production is the same for super reach A and super reach B.

  First, the 2D effect (super reach C) will be described with reference to FIG. When the super reach C is executed, first, from the state where all the symbol rows Z1 to Z3 are stopped, the symbol rows Z1 to Z3 start to be displayed in the horizontal direction. Note that the scrolling display in the horizontal direction is continued for the background image (image not shown in the present embodiment, but imitating the sea bottom) regardless of the start of the variable display.

  Thereafter, the variable symbol display is stopped in the order of the upper symbol row Z1 → the lower symbol row Z3, and the display shifts to reach display. A girl character image is displayed at the center of the display screen 94a at a predetermined timing after the shift to reach display. Such a character image is generated by the 2D display CPU 520 using sprite data, and its pose (posture or form) changes as the game progresses.

  Specifically, as shown in FIG. 38 (a) → FIG. 38 (b) → FIG. The middle symbol row Z2 is variably displayed in the horizontal direction in accordance with such an operation. And after performing the operation | movement which shakes a hand over a predetermined period, it transfers to the next operation | movement according to the fall of the fluctuation | variation speed of the middle symbol row | line | column Z2. Specifically, as shown in FIG. 38 (c) → FIG. 38 (d) → FIG. 38 (c), an operation of pushing the hand upward is performed.

  Thereafter, as shown in FIG. 25 (b4), when the variation display end timing is reached, the variation display of the middle symbol row Z2 is stopped and the movement of the character image is stopped.

  In the present embodiment, a 3D effect in which the character image changes from a 2D image to a 3D image is executed while the above 2D effect is being executed. At this time, the 2D image and the 3D image are configured such that the image changes smoothly by matching various parameters such as the character size, position, and posture.

  A plurality of timings for transition to such a 3D effect are set according to the degree of expectation that results in a jackpot result. Specifically, as shown in FIG. 38A, a mode in which the character image is switched to a 3D image at the timing when the hand is waving (specifically, the timing at which the hand is closest to the body), As shown in FIG. 38 (c), a mode is set in which the character image is switched to a 3D image at the timing when the hand moves the hand up and down (specifically, the timing at which the hand is closest to the body).

  Here, the mode of switching to the 3D effect will be described with reference to FIG. FIG. 39 is a schematic diagram showing a state of switching from the 2D effect to the 3D effect.

  First, the first switching mode will be described with reference to FIG. At the timing when the first period has elapsed since the reach display was started on the display screen 94a, the 2D character image displayed on the display screen 94a performs an operation of waving as shown in FIG. 39 (a1). The hand is displayed with the hand closest to the body. More specifically, the 2D display CPU 520 draws a character image that meets the above conditions. At this timing, various parameters of the 3D image are set so that the character image currently displayed by the 3D display CPU 530 matches the position, size, posture, etc., and the VDP 580 uses the 2D image currently displayed. A 3D image is drawn in a frame buffer 572 for 3D images different from the frame buffer 562 of FIG. Then, the character image displayed on the display screen 94a is replaced from the 2D image to the 3D image at the timing immediately after the completion of the 3D image, and thereafter, the character image is generated using the 3D display CPU 530 until the 3D effect is completed. The display of the 3D image is continued.

  The display process executed by the display control device 500 is the same for the second switching mode. Specifically, at the timing when the second period has elapsed since the start of reach display on the display screen 94a, the 2D character image displayed on the display screen 94a is touched as shown in FIG. 39 (b1). It is being moved up and down and is displayed with the hand closest to the body. More specifically, the 2D display CPU 520 draws a character image that meets the above conditions. At this timing, various parameters of the 3D image are set so that the character image currently displayed by the 3D display CPU 530 matches the position, size, posture, etc., and the VDP 580 uses the 2D image currently displayed. A 3D image is drawn in a frame buffer 572 for 3D images different from the frame buffer 562 of FIG. Then, the character image displayed on the display screen 94a is replaced from the 2D image to the 3D image at the timing immediately after the completion of the 3D image, and thereafter, the character image is generated using the 3D display CPU 530 until the 3D effect is completed. The display of the 3D image is continued. In this way, in the first and second switching modes, the 3D image is displayed so as to replace the 2D image, thereby making it easier for the player to recognize the relevance between these two effects. In addition, the display mode can be changed smoothly.

  As described in detail above, in this embodiment, 2D effects using 2D images and 3D effects using 3D images are adopted, and the lottery for 3D effects in the audio lamp control device 143 was won. In this case, the 3D effect is inserted into the 2D effect. For this reason, the processing load applied to the display control device 500 is increased when the 3D effect is executed as compared with the type of game machine that executes only the 2D effect. Such an increase in processing load is not preferable because it can hinder the smooth operation of the display control apparatus 500. In the present embodiment, as described above, various measures are taken to suppress the occurrence of the inconvenience. Has been.

  Hereinafter, the flow of display control in the display control apparatus 500 will be described with reference to FIGS. 40 and 41. FIG. 40 is a timing chart showing how to read and erase 3D image data, and FIG. 41 is a timing chart showing how to read and erase 3D image data.

  First, the read timing of 3D image data from the memory module 540 will be described with reference to FIG.

  When a ball enters the operation port 83 at the timing ta2 after the game turn has started at the timing ta1, a hold command is transmitted from the main controller 162 on condition that there is an empty reservation area. Based on the hold command, the voice lamp control device 143 performs a lottery to determine whether or not to execute the 3D effect at the game time corresponding to the hold command (the next game time in FIG. 40A). When the lottery is won, the hold command reaches the display control device 500 via the voice lamp control device 143, so that the game times executed at the timing of ta2 are games that do not support reach display. On the condition that it is the number of times, reading of the 3D image data from the memory module 540 to the second VRAM 570 (specifically, the development buffer 571) is started.

  Thereafter, the game round ends at the timing ta3, and the game round corresponding to the 3D effect starts at the timing ta4.

  Since the above-described readout of the 3D image data has been completed before the start of the 3D effect at the timing ta6, switching from the 2D effect to the 3D effect at the timing is smoothly executed.

  When this game round ends at the timing of ta7, it is determined whether or not there is something corresponding to the same 3D effect in the hold information at this time, and on condition that the hold information does not exist The 3D image data stored in the second VRAM 570 is erased.

  Next, another reading mode of 3D image data will be described with reference to FIG.

  At the timing of tb2 after the game is started at the timing of tb1, the display shifts to reach display. When a ball enters the operation port 83 at the timing tb3 during the reach display period, a hold command is transmitted from the main controller 162 on condition that there is a vacancy in the hold area. Based on the hold command, the voice lamp control device 143 performs a lottery to determine whether or not to execute the 3D effect at the game time corresponding to the hold command (the next game time in FIG. 40B). When the lottery is won, the hold command reaches the display control device 500 via the voice lamp control device 143. Reach display is executed at the timing of tb3 when the hold command reaches the display control device 500. Therefore, instead of immediately starting the reading of the 3D image data from the memory module 540 to the second VRAM 570 (specifically, the developing buffer 571), the reading is postponed.

  Specifically, when the game round ends at the timing of tb4 and the game round corresponding to the hold command starts at the timing of tb5, the 3D image data delayed by the start of the game round is triggered. Reading is started.

  Thereafter, the display shifts to reach display at the timing of tb7, but the above-described reading of the 3D image data is configured to be completed by the timing of tb6 before the timing of tb7. More specifically, the period required to read out the 3D image data is set shorter than the period from the start of the variable display to the transition to the reach display (the period from the timing tb5 to the timing tb7). Therefore, when the 3D effect is performed, the reading of the 3D image data is completed before the shift to the reach display in almost all cases. In practice, the period for reading the 3D image data varies depending on the state of the display control device 500 (processing load, temperature condition, etc.). A period used for reading and a period from the start of variable display to the transition to reach display are set.

  While the reach display is being executed, the processing load generated in the display control device 500 becomes larger than that during normal fluctuation display or stop display. Thus, when reach display is being performed, it is possible to suppress an excessive increase in the processing load on the display control device 500 by adopting a configuration that reserves reading of 3D image data. Yes.

  Next, with reference to FIG. 41, an aspect different from the above-exemplified aspect regarding the erasing timing of the 3D image data stored in the expansion buffer 571 of the second VRAM 570 will be described.

  When the game times corresponding to the 3D effect start at the timing of tc1, reading of the 3D image data from the memory module 540 is started at the same time. Reading of the 3D image data is completed at the timing tc2, and the normal display is changed to the reach display at the timing tc3. Here, when a ball enters the operation port 83 at the timing of tc4 when the reach display is performed, a hold command is transmitted from the main controller 162 on condition that there is a vacancy in the hold area. Based on the hold command, the voice lamp control device 143 performs a lottery to determine whether or not to execute the 3D effect at the game time corresponding to the hold command (the game time after the game time in FIG. 40C). When the lottery is won, the hold command reaches the display control device 500 via the voice lamp control device 143. At the timing of tc4 when the hold command reaches the display control device 500, 3D image data for 3D effect that is the same as the 3D effect related to the hold command is stored in the second VRAM 570 (specifically, the buffer for development 571). For this reason, 3D image data is not read again.

  When this game round ends at the timing of tc6, at this point in time, there is something corresponding to the 3D effect similar to the current game round in the hold information, and further until the hold information is reached. On the condition that the 3D effect is not executed, the erasure of the 3D image data is reserved.

  In the present embodiment, game times corresponding to complete losing start at the timing of tc7, and the game times end at the timing of tc8. During this time, the 3D image data is maintained while being stored in the second VRAM 570, and the game times corresponding to the 3D effect starting at the timing of tc9 are inherited.

  When the display shifts to reach display at the timing of tc10 and the 3D effect is started at the timing of tc11, the 3D image data stored in the second VRAM 570 is used. Then, when the 3D effect ends at the timing of tc12, the subsequent 3D effect-compatible hold information does not exist, so the 3D image data stored in the second VRAM 570 is deleted.

  According to the first embodiment described in detail above, the following excellent effects are obtained.

  By adopting a configuration that implements the 3D effect in association with the 2D effect, diversification of the effect mode is realized while suppressing the difficulty in understanding the effect. In other words, when both the 2D effect and the 3D effect are performed during one game, it is possible to have a configuration in which the two are not associated with each other, but this weakens the sense of unity of the game effect, and the player Can be a factor to confuse.

  Specifically, the 2D character image displayed in the 2D effect is replaced with the 3D character image so as to inherit various information such as the size, position, and posture (shape). As a result, it is possible to avoid difficulty in understanding the effect when executing the 3D effect.

  As described above, in the configuration in which the 2D effect and the 3D effect are used together, the amount of 3D image data is larger than the amount of 2D image data, and further, the parameters and processing required when handling the data become complicated. In view of this, the processing load on the display control device 500 increases. More specifically, when generating drawing data using image data, the processing load, the processing period, and the like increase as the amount of data increases. Here, for example, when a local increase in the processing load occurs, there is a concern that processing failure occurs or the formation of drawing data is delayed, and the smoothness of the display effect is likely to be impaired. This is not preferable because it may hinder improvement in the degree of attention to the display effect described above.

  In this regard, in the present embodiment, the compressed 3D image data is read out in a decompressed state before the 3D effect is started, so that the 3D effect is started or immediately before it. In addition, the processing load and the like can be prevented from becoming excessively large. Thereby, it is possible to suppress an increase in processing load due to the improvement in the degree of attention to the display effect. Therefore, diversification of display effects can be suitably realized.

  Further, as the amount of 3D image data increases, the period required for reading from the memory module 540 increases. This becomes a factor that strengthens restrictions that occur in the start timing of the 3D effect, or that strengthens restrictions that occur in the amount of 3D image data. This can hinder diversification of production and improvement of appearance of 3D production.

  In this regard, in the present embodiment, when a hold command is received, a configuration is adopted in which data is read before the game times related to the hold information are started. Thereby, it is possible to read out the 3D image data with a margin, and it is possible to eliminate the various restrictions described above. Therefore, it is possible to promote the use of 3D image data with a large amount of data to improve the appearance and diversify the display effect, and to set the start timing of the 3D effect early to realize the diversification of the effect. it can. Thereby, it can contribute to the improvement of the attention degree to a display effect.

  The processing load generated in the display control device 500 becomes larger when the reach display is performed as compared with the case where the symbol display device 94 is stopped and the normal variation display is performed. Cheap. Therefore, when the 3D image data is read, the reading start timing is devised so that the reading is not performed in parallel with the reach display. Thereby, it is avoided that the processing load generated in the display control device 500 temporarily becomes excessively large.

  For example, in the case where 3D image data is always stored in the second VRAM 570, it is not necessary to read data as described above, and an increase in processing load can be suppressed. However, with such a configuration, the amount of data required for the second VRAM 570 increases, or the number of 3D images used is limited, so that variations in 3D effects are reduced. It becomes difficult to achieve both simplification of the configuration according to 500.

  Here, in the present embodiment, it is possible to suppress an increase in required data capacity while maintaining a variety of effects by taking measures to reduce the chance of reading / erasing 3D image data. ing.

  Specifically, it is a case where the 3D effect relating to the same 3D image data is scheduled to be performed again after the game times when the 3D effect relating to the 3D image data is executed, and another 3D effect is performed in the meantime. If not, the 3D image data stored in the second VRAM 570 is held without being erased until the next use. Thereby, it is possible to avoid the unnecessary deletion and re-reading of the 3D image data read once, and to suppress the processing load when the effect related to the predetermined image is executed later.

<Second Embodiment>
In the first embodiment, when the 3D effect is performed, the timing is preset in advance after the game time is started, so that the 2D effect (2D image) is changed to the 3D effect (3D image). However, in this embodiment, a configuration that diversifies the switching timing is adopted. Hereinafter, the configuration according to the 3D effect in the present embodiment will be described focusing on the differences from the first embodiment.

  When a ball enters the operation port 83 and the hold command is transmitted from the main control device 162 to the sound lamp control device 143, the sound lamp control device 143 performs the 3D effect as in the first embodiment. The lottery of whether or not to execute is performed. When the game times corresponding to the hold command are started, a change command is transmitted from the main controller 162.

  When the voice lamp control device 143 receives the change command, the operation correspondence / non-response stored in the lottery table storage area 461 of the ROM 453 is provided on the condition that the 3D effect is won in the lottery. With reference to the determination table, whether or not to make the 3D effect correspond to the operation of the operation switch 40 is selected.

  In the lottery process, when the operation-compatible 3D effect is won, unlike the non-operation-compatible 3D effect (corresponding to the 3D effect in the first embodiment), the start timing of the 3D effect is operated by the player. It is determined by the operation of the switch 40.

  In the sound lamp control device 143, when the operation-compatible 3D effect is won, the operation-compatible 3D effect flag indicating that is stored in the various flag storage areas 473 of the RAM 454 and transmitted to the display control device 500. The process which adds the information which shows that the operation corresponding | compatible 3D effect was won to a command is performed.

  The sound lamp control device 143 sets the operation reception period of the operation switch 40 on the condition that the operation-response 3D effect flag is stored when the game times related to the change command are started, Monitor operations during that period. When the operation switch 40 is operated during the operation reception period, an operation detection command indicating that is transmitted to the display control device 500.

  In the display control device 500, when the received change command corresponds to the operation-compatible 3D effect, the operation-compatible 3D effect flag is stored in the hold information storage area 554 of the work RAM 550. When this operation-compatible 3D effect flag is stored, various controls are performed so that the operation switch 40 is operated to switch to the 3D effect. Further, the notification process is performed so that information for notifying the period during which the operation is effectively received is displayed on the display screen 94a. As the content of such notification, for example, a message such as “Press the button!” May be displayed on the display screen 94a. However, the notification mode is arbitrary as long as it can at least prompt the player to perform an operation. For example, a notification function is provided to the audio lamp control device 143 and the lamp units 24 to 26 and the speaker unit 27 are used. It is good also as a structure which alert | reports.

  When executing a non-operation-supporting 3D effect, it is possible to switch from a 2D image to a 3D image at a preset timing. Therefore, modes (size, position, orientation (shape) of sprite data and polygon data ) Etc.) is easy to unify. However, when the operation-compatible 3D effect is executed, the switching timing is left to the player, so it is difficult to maintain the relevance between the 2D image and the 3D image. Therefore, a separate configuration for maintaining the relationship between the two is required. Specifically, it is necessary to set a parameter corresponding to the operation when creating a drawing list executed by the 3D display CPU.

  Hereinafter, with reference to the flowchart of FIG. 42, the operation corresponding 3D effect drawing list creation process executed based on the task process will be described. Note that the drawing list creation process in the case of non-operation is the same as in the first embodiment, and thus detailed description thereof is omitted.

  In the 3D effect drawing list creation process, it is first determined in step S2301 whether or not it is a game time related to the operation-compatible 3D effect. This determination processing makes an affirmative determination by the fact that the operation-compatible 3D effect flag is stored in the various flag storage area 553 of the work RAM 550.

  If a negative determination is made in step S2301, that is, if it is a game time related to an operation-incompatible 3D effect, the creation process is terminated as it is.

  On the other hand, if an affirmative determination is made in step S2301, the process proceeds to step S2302, and it is determined whether or not it is during the operation acceptance period. Specifically, the overall CPU 510 sets a predetermined value in the valid reception period timer counter stored in the various counter areas 552 of the work RAM 550 by receiving a change command related to the operation-responsive 3D effect. This timer counter is updated each time the timer interrupt process is executed in the overall CPU 510 (subtracted by “1”), and the value of the valid reception period timer counter is not “0”. Thus, it is determined that the effective period has started. When the value of the valid reception period timer counter becomes “0”, the valid reception period ends. In the present embodiment, the timing when the valid reception period timer counter becomes “0” coincides with the end timing of the 3D effect.

  If an affirmative determination is made in step S2302, it is determined whether or not an operation detection command has been received from the sound lamp control device 143. The operation detection command is transmitted only once during the valid reception period, and the operation detection command is not transmitted when the second and subsequent operations are performed during the valid reception period.

  If an affirmative determination is made in step S2303, the process advances to step S2304 to execute a process for grasping parameters relating to the character posture in the currently displayed 2D image data (sprite data).

  After executing the grasping process in step S2304, the process proceeds to step S2305, and a process for calculating a parameter related to the character posture in the 3D image data (polygon data) is executed.

  Hereinafter, with reference to FIG. 43, the grasping process in step S2304 and the calculation process in step S2305 will be described. FIG. 43 is a schematic diagram showing how 3D drawing data is created. Group (1) shows a state in which sprite data related to a character image is arranged on a virtual two-dimensional plane, and group (2) shows the character image. A state in which such polygon data is arranged in a virtual three-dimensional space is shown. Group (3) schematically shows a 3D image displayed on the display screen 94a.

  As shown in FIG. 43 (a1), the sprite data has a 2D connected object. The 2D connected object is a unit object in which a plurality of part objects (partial objects) are connected using a connecting part as a joint. In order to give a motion to a character in a 2D image by relatively displacing each part object. Is set. By using the connected object, the character of the 2D image can be smoothly operated. In view of the fact that the connected object has a skeleton part and a joint part, it can also be called a bone model.

  In the 2D connection object, a first connection object PC1 (corresponding to the left arm) and a second connection object PC2 (corresponding to the right arm) are set in order to represent the arm of the character. In the first connection object PC1, connection portions CT1 (corresponding to shoulder joints) and CT2 (corresponding to elbow joints) are set at different locations, and the second connection object PC2 is connected to different locations. The parts CT3 (corresponding to the shoulder joint) and CT4 (corresponding to the elbow joint) are set.

  Further, as shown in FIG. 43 (a2), the polygon data includes 3D connected objects corresponding to the connected objects PC1 and PC2 of the sprite data. The 3D connected object is a unit object in which a plurality of part objects (partial objects) are connected with a connecting part as a joint. In order to give a motion to a character in a 3D image by relatively displacing each part object. Is set. By using the connected object, the character of the 3D image can be smoothly operated.

  In the 3D connection object, a first connection object PD1 (corresponding to the left arm) and a second connection object PD2 (corresponding to the right arm) are set in order to represent the arm of the character. In the first connection object PD1, connection portions CU1 (corresponding to shoulder joints) and CU2 (corresponding to elbow joints) are set at different locations, and the second connection object PD2 is connected to different locations. The parts CU3 (corresponding to the shoulder joint) and CU4 (corresponding to the elbow joint) are set.

  Here, in the grasping process in step S2304, a process of acquiring the coordinates of the connected portions CT1 to CT4 in the connected objects PC1 and PC2 of the currently displayed sprite data is executed. In the calculation process in step S2305, the obtained 2D coordinates converted to 3D coordinates are applied to the coordinates of the connected portions CU1 to CU4 of the connected objects PD1 and PD2 of the polygon data. As a result, the form (posture) of the sprite data arranged in the virtual two-dimensional space and the polygon data arranged in the virtual three-dimensional space coincide. In the present embodiment, as in the first embodiment, the character image itself does not move on the display screen 94a during the period in which the 3D effect can be executed. It is limited only to the position. For this reason, it is possible to make the sprite data and the polygon data coincide with each other by performing the alignment of the position information related to the connecting portion.

  For example, even when the operation switch 40 is operated as a trigger for the transition to the 3D effect while the arm of the character image is moving up and down, as shown in the group of FIG. Coordinate acquisition of data (sprite data) CT1 to CT4 → Conversion to 3D coordinates determines the position of the polygon data connection CU1 to CU4, and the sprite data and polygon data match the form. Can be made.

  After executing the process of step S2305, or when a negative determination is made in any of steps S2302 and S2303, the process proceeds to step S2306, and other various parameters (for example, color scheme and camera position) are determined. This creation process is terminated.

  In the present embodiment, the start timing of the 3D effect is determined according to the player's operation. If the time lag (waiting time) from when the operation is performed until 3D display is performed increases, smooth movement of the character image is hindered. In this regard, when the 3D effect is confirmed, the responsiveness of the operation → 3D effect execution can be improved by performing the 3D image reading process in advance without waiting for the execution of the 3D effect. . Therefore, even if the configuration in which the 2D image and the 3D image are interchanged is adopted, it is possible to suppress the smooth movement of the character image from being interrupted at the switching timing.

<Third Embodiment>
In the present embodiment, prior to the transition to the reach display, a notice effect for notifying the type of effect performed during the reach display (hereinafter referred to as reach effect and distinguished from the display effect related to the variable display of symbols). Is configured to be performed. The notice effect and the reach effect are configured to be recognized as a series of effects by the player. In this embodiment, by adopting such a configuration, it is one of the features that the diversification of the effects is realized while suppressing the difficulty of understanding the contents of the effects by the player. Hereinafter, a configuration related to the series of effects will be described.

  As described above, in each of the above-described embodiments, as the variable display mode of the symbols executed on the display screen 94a, complete detachment, normal reach A, normal reach B, super reach A, super reach B, super reach C are as follows. It was adopted (see FIG. 25). In the present embodiment, in addition to these various display modes, a super reach D corresponding to the series of notice effects to reach effects is set.

  When the information regarding the variable display time given to the command from the main control device 162 is “20 sec”, it is understood that the audio lamp control device 143 and the display control device 500 should execute the super reach D. .

  In the game times in which the super reach D is executed, the notice effect is executed before shifting to the reach display. About this notice production, a series of story characteristics are given, and it becomes the composition that the aspect of the subsequent reach production changes according to the progress of the notice production, that is, at which timing it shifts to reach display. Yes. Specifically, Super Reach D is provided with a plurality (more specifically three) of branching patterns (transition patterns) from the notice effect to the reach effect, so that each pattern corresponds to one-to-one. Three different production modes are set for the reach production.

  About the detail of the production | presentation aspect in the super reach D, it becomes the structure selected when the pending | holding command is received in the audio | voice lamp control apparatus 143. FIG. Here, among the various processes executed by the voice lamp control device 143, the pending command handling process will be described. Since most of the pending command handling processes are the same as those in each of the above-described embodiments, different parts (a jackpot handling setting process and a miss reach handling setting process) will be mainly described.

<Big hit correspondence setting process>
First, the jackpot correspondence setting process will be described with reference to the flowchart of FIG.

  In the big hit correspondence setting process, first, in step S2401, it is determined whether or not the hold command received this time corresponds to any one of super reach A to super reach C. In this embodiment, a plurality of variation display modes of symbols are set so that the winning expectation degree of jackpot is different, and a configuration is adopted in which the winning expectation degree of jackpot in game times is notified by each variation display mode. In step S2401, the variable display pattern storage area 462 of the ROM 453 is referred to and it is determined whether or not the hold command corresponds to super reach A to super reach C.

  If an affirmative determination is made in step S2401, after executing each processing of step S2402 to step S2405, the jackpot correspondence setting processing is terminated. In addition, about each process of these step S2402-step S2405, since it is the same as that of each process of the said step S1302-step S1305, description is used.

  On the other hand, if a negative determination is made in step S2401, the process advances to step S2406 to determine whether or not the currently received hold command corresponds to super reach D. If a negative determination is made in step S2406, the big hit correspondence setting process is terminated as it is.

  If a positive determination is made in step S2406, the process proceeds to step S2407. In step S2407, the selection table corresponding to the jackpot stored in the lottery table storage area 461 of the ROM 453 is referred to, and branch pattern selection processing is executed in the subsequent step S2408.

  Specifically, the counter value (numerical information) is read from the selection counter stored in the various counter areas 472 of the RAM 454 and stored in the selection table storage area (3D effect selection information group storage means) 461 of the ROM 453. With reference to the selection table (3D effect selection information group), it is determined which of the three types of branch patterns corresponds to the read selection counter value. The jackpot-compatible selection table is configured such that an effect with a later transition timing to reach display is more easily selected than an effect with an earlier transition timing.

  The value of the selection counter is updated (incremented by 1) every time the pending command handling process (FIG. 28) is started, that is, at a cycle of about 2 msec. Incidentally, the selection counter shown in this embodiment does not necessarily have to be provided separately from the lottery counter in each of the above embodiments, and the value of the lottery counter can be referred to at the time of selection.

  After executing the selection process of step S2408, the process proceeds to step S2405, and after executing the hold command update process in step S2405, the big jackpot correspondence setting process is terminated. In the case where the process of step S2405 is executed through steps S2406 to S2408, information relating to the super reach D effect mode is added while maintaining the form of the hold command received this time. Thereby, in the display control apparatus 500, by receiving the hold command, from the hold command, the hold information concerning the hold command, specifically, the type of the variable display pattern, the presence / absence of jackpot, the notice effect and the reach effect pattern Whether or not the 3D effect can be executed can be grasped.

  Next, with reference to the flowchart of FIG. 44 (b), the outreach correspondence setting process will be described.

<Outgoing reach support setting process>
In the miss reach correspondence setting process, it is first determined in step S2501 whether or not the hold command received this time corresponds to any one of super reach A to super reach C. As described above, in this embodiment, a plurality of variable display modes of symbols are set so that the winning degree of winning the jackpot is different, and the expected winning degree of the jackpot in the game times is notified by each of the changing display modes. The configuration is adopted, and in step S2501, the variable display pattern storage area 462 of the ROM 453 is referred to and it is determined whether the hold command corresponds to super reach A to super reach C.

  When an affirmative determination is made in step S2501, that is, in the case where there is information corresponding to super reach A to super reach C in the hold information, after executing each processing of step S2502 to step S2505, the main error is detected. The reach correspondence setting process is terminated. In addition, about each process of these step S2502-step S2505, since it is the same as that of each process of the said step S1402-step S1405, description is used.

  On the other hand, if a negative determination is made in step S2501, the process proceeds to step S2506, where it is determined whether or not the hold command received this time corresponds to super reach D. If a negative determination is made in step S2506, the big hit correspondence setting process is terminated as it is.

  If a positive determination is made in step S2506, the process proceeds to step S2507. In step S2507, the selection table corresponding to detachment stored in the lottery table storage area 461 of the ROM 453 is referred to, and branch pattern selection processing is executed in the subsequent step S2508.

  Specifically, the counter value (numerical information) is read from the selection counter stored in the various counter areas 472 of the RAM 454 and stored in the selection table storage area (3D effect selection information group storage means) 461 of the ROM 453. With reference to the selection table (3D effect selection information group), it is determined which of the three types of branch patterns corresponds to the read selection counter value.

  The selection table corresponding to detachment is configured such that an effect with an earlier transition timing to reach display is more easily selected than an effect with a later transition timing. In other words, the specification is the reverse of the selection table corresponding to the jackpot described above, and the winning expectation degree for the jackpot is increased by the notice effect lasting as long as possible.

  After executing the selection process of step S2508, the process proceeds to step S2505. After the hold command update process is executed in step S2505, the outlier reach correspondence setting process is terminated. In the case where the process of step S2505 is executed through steps S2506 to S2508, information relating to the super reach D effect mode is added while maintaining the form of the hold command received this time. Thereby, in the display control apparatus 500, by receiving the hold command, from the hold command, the hold information concerning the hold command, specifically, the type of the variable display pattern, the presence / absence of jackpot, the notice effect and the reach effect pattern Whether or not the 3D effect can be executed can be grasped.

  In the above-described pending command handling process, information regarding whether or not to execute the 3D effect based on the items determined by the jackpot handling setting process and the outlier reach handling setting process, and also when super reach D is performed. Is stored in the hold information storage area 474 of the RAM 454.

  The sound lamp control device 143 is configured to specify a production mode such as a variation display mode again when a variation start command is received from the main control device 162. At this time, in the hold information storage area 474, the area corresponding to the change start command is referred to and whether or not the 3D effect is performed and the effect mode at the time of executing the super reach D is specified. That is, whether or not the 3D effect is possible and the effect of Super Reach D are determined at the time of receiving the hold command before receiving the change start command. When the change start command is received, the specified state is specified. The lottery or the like of the 3D effect is not performed again only by referring to the result.

  As described above in detail, the sound lamp control device 143 determines the details of the production mode in each game time. By receiving the hold command from the sound lamp control device 143, the display control device 500 In detail, in the game times corresponding to Super Reach A to Super Reach C, whether or not to perform a 3D compatible effect, in the game times corresponding to Super Reach D, which pattern among a plurality of branch patterns Specify whether to perform the production. The detailed information is stored in the hold information storage area 554 of the work RAM 550 when the hold information is set in the command corresponding process executed by the overall CPU 510 of the display control device 500. . And when the change start command is received, the mode of the display effect to be executed is specified with reference to the hold information corresponding to the change display times related to the start command.

  In the display control device 500, 2D image data for a notice effect and 3D image data for a reach effect are stored in a compressed state in the memory module 540, respectively. The 2D image data is read from the memory module 540 at the start of the game times, and is stored in the expansion buffer 561 of the first VRAM 560 in a decompressed state. The 3D image data is read from the memory module 540 when a hold command is received or when a game is started, and is stored in the expansion buffer 571 of the second VRAM 570 in a decompressed state.

  Here, with reference to the flowchart of FIG. 45, the notice effect display setting process executed by the display control device 500 (specifically, the 2D display CPU 520) will be described.

<Notification effect display setting process>
In the notice effect display setting process, it is first determined in step S2601 whether or not it is a timing to start deceleration of the symbol variable display being executed on the display screen 94a. The notice effect is roughly divided into three parts, and is configured such that the symbol temporarily stops or reaches display at a timing at which the notice effect ends and the display can be shifted to reach display. Therefore, in step S2601, it is determined whether or not it is the timing to decelerate the variable display so that the symbol is temporarily stopped or reached. This timing is determined according to the branch pattern determined by the sound lamp control device 143.

  If a positive determination is made in step S2601, the process proceeds to step S2602. In step S2602, it is determined whether or not the symbol variation display area is minimized (ie, reduced to the corner of the display screen 94a). Specifically, it is determined whether or not a reduced display flag is stored in various flag storage areas 553 of the work RAM 550. In the present embodiment, when the notice effect or the reach effect is executed, an effect image such as various characters is displayed on the display screen 94a. By reducing the display area, the display area for the notice effect and the reach effect is secured while ensuring the visibility of the symbol.

  If an affirmative determination is made in step S2602, a symbol variation display area return process is executed in step S2603. As a result, the reduced display flag stored in the various flag storage areas 553 is deleted, and thereafter, the drawing list is created such that the variable display area of the symbol is at the normal position. In the game times, a game result or the like is suggested by the combination of symbols displayed in a stopped state. Therefore, when the symbol stops, the player's attention is easily directed to the symbol row. Therefore, after the deceleration display is started, the visibility of the symbol row is improved by returning the variable display area to the normal position.

  After the return process is executed in step S2603, a notice effect image pause process is executed in subsequent step S2604. Specifically, a temporary stop flag is stored in various flag storage areas 553. By storing this temporary stop flag, the parameters used in the previous process are diverted as parameters relating to the notice effect image in the subsequent drawing list creation process.

  As described above, after decelerating the variable display of the symbol sequence is started, the player's attention is more likely to be directed to the symbol sequence than the notice image. Therefore, after the variable display area returns to the normal state, it is possible to urge the player to pay attention to the symbol sequence by stopping the update of the image for the notice effect.

  In this embodiment, instead of preparing an image for pause in advance, an increase in the storage capacity of the memory module 540 or the like can be suppressed by adopting a configuration that uses parameters for a drawing list. Is possible.

  After the process of step S2604 is executed or when a negative determination is made in the process of step S2602, the process proceeds to step S2605, and a process for deceleration of symbol variation display is executed. Specifically, a deceleration flag is stored in various flag storage areas 553 of the work RAM 550. As a result, in the subsequent drawing list creation processing, the symbol position determining symbol is determined with reference to the table for decelerating the symbol display speed on the display screen 94a in the order of the upper symbol row → the lower symbol row → the middle symbol row. Set various parameters.

  After executing the processing of step S2605, it is determined whether or not re-variation after deceleration should be performed in step S2606. That is, it is determined whether or not temporary stop display should be performed.

  In the present embodiment, when the notice effect is continued, the symbol sequence is temporarily stopped → re-varied during one game round (while the variable display of the operation port display section of the main display section 90 is continued). When the notice effect is completed, the display is shifted to reach display. Therefore, in step S2606, it is determined which of the current deceleration → stop corresponds.

  If a negative determination is made in step S2606, that is, if it is determined not to perform temporary stop display but to shift to reach display, the process proceeds to step S2607. In step S2607, reach display transition processing is executed, and then the notice effect setting processing is terminated.

  In the processing of step S2607, a reach display transition flag is stored in various flag storage areas 553 of the work RAM 550. By storing the reach display shift flag, the symbol variation display pattern table for shifting to reach display is referred to in the subsequent drawing list creation processing. The transition flag is deleted when the reach display is completed, that is, when all the symbol sequences are completely stopped and displayed.

  On the other hand, if an affirmative determination is made in step S2606, the process advances to step S2608 to execute the process for stopping the symbol combination corresponding to the most variation, and then the present notice effect setting process is terminated. In the processing of step S2608, a symbol combination stop flag corresponding to re-variation is stored in various flag storage areas 553 of the work RAM 550. By storing the symbol combination stop flag corresponding to the re-variation, the symbol variation display pattern table for stopping the specific symbol combination corresponding to the re-variation is referred to in the subsequent drawing list creation processing. . The stop flag is deleted when the stop display of the specific symbol combination is completed.

  Again, returning to the description of step S2601, if a negative determination is made in step S2601, the process proceeds to step S2609. In step S2609, it is determined whether it is time to start revariation of the symbol sequence. If an affirmative determination is made in step S2609, the process advances to step S2610 to execute a symbol variation display area reduction process. Specifically, the reduced display flag is stored in various flag storage areas 553 of the work RAM 550. As a result, when the subsequent drawing list creation process is executed, various parameter setting processes for the variable display of symbols are performed so that the variable display area is reduced.

  After executing the process for reducing the symbol variable display area in step S2610, in the subsequent step S2611, a stop cancellation process for the notice effect image is executed. In the stop cancellation process of step S2611, the temporary stop flag stored in the various flag storage areas 553 of the work RAM 550 is erased, and the preliminary announcement effect setting process is terminated as it is.

  In the present embodiment, the 2D display CPU 520 and the first VRAM 560 for 2D image drawing, the 3D display CPU 530 and the second VRAM 570 for 3D image drawing are used in combination, and in particular, the 3D display CPU 530 and the second VRAM 570 Operations and the like are monitored by the overall CPU 510. If the 3D display CPU 530 and the second VRAM 570 are not operating properly, an alternative effect is executed by the 2D display CPU 520 and the first VRAM 560.

  Returning to the description of step S2609, if a negative determination is made in step S2609, the processes of steps S2612 to S2614 are executed as part of the process for the alternative effect.

  First, in step S2612, it is determined whether or not it is a transition timing to a 3D-compatible reach effect. If a negative determination is made in step S2612, the present notice effect setting process is terminated as it is.

  On the other hand, if an affirmative determination is made in step S2612, the process proceeds to step S2613 to determine whether or not the preparation for the 3D-compatible reach effect has been completed. Specifically, a 3D display CPU 530 creates a drawing list based on a command from the overall CPU 510, or 3D image data used for production (character polygon data, background plate polygon data, etc.) ) Is completed.

  When an affirmative determination is made in step S2613, that is, when the 3D display CPU 530 completes preparation for a 3D-compatible reach effect, data for 2D display becomes unnecessary, and these are deleted.

  On the other hand, when a negative determination is made in step S2613, that is, when the preparation of the 3D drawing list is not completed due to some trouble or the like although the preparation is originally completed, the 3D image data If the reading has not been completed, a flag for executing the substitute effect is stored in various flag storage areas 553 of the work RAM 550, and the data for 2D display is retained without erasing the data for the present notice effect display. The setting process ends. Due to the presence of such a flag, the transition effect is implemented in 2D instead of 3D. In addition, although detailed description is omitted, in this alternative effect, almost the same display (however, a planar display) as the content executed by the 3D display CPU 530 is performed. Here, by holding the read 2D data without erasing it, it is possible to quickly execute the alternative effect.

<Direction of Super Reach D>
Here, with reference to FIG. 46, the effect aspect in the game times in which the super reach D is executed will be described. FIG. 46 is a schematic diagram showing a flow of display effects in game times in which super reach D is executed. In FIG. 46, for the sake of convenience, the background image and the hold information displayed on the display screen 94a are omitted.

  At the timing when the game turn is started, as shown in FIG. 46 (a), the variable display of each symbol sequence that has been stopped on the display screen 94a until then is started. After the variable display has started, in detail, at the timing when the first period has passed since the variable display was started, the variable display speed of the symbol decreased, and the display was stopped in the order of the upper symbol row → the lower symbol row → the middle symbol row. Is done. The change display mode so far is the same as the change display mode at the time of complete deviation.

  When the lower symbol sequence stops, do not form a reach line with the symbols in the upper symbol sequence, that is, the symbols that can form a reach line with the upper symbol that is stopped in the lower symbol sequence are shifted from the upper symbol sequence. Stop at the position. Thereafter, when the middle symbol row is stopped and all the symbol rows are stopped and displayed, a state where a specific symbol combination (restart symbol combination or temporary stop symbol combination) is formed at the effective position of the display screen 94a; Become.

  After that, all the symbol sequences once stopped start re-variation with specific sound effects and effects such as flash. That is, it appears as if one game round has ended, and the temporary stop → revariation is performed in a situation where the game round is actually continued (hereinafter referred to as pseudo continuous fluctuation display). In addition, during the pseudo continuous variation display, even when all the symbol sequences are stopped, the variable display is continued for the operation port result display section of the main display section 90, and the game round is continued without ending. Is specified.

  In this way, even if the combination of symbols corresponding to the jackpot result or the like does not stop, the symbol combination that has been stopped by leaving the possibility that the game times are won by the jackpot When the lower symbol row or the middle symbol row stops, it is possible to make it difficult to cause a disadvantage that the attention degree to is reduced at a stretch.

  At the timing immediately after the start of re-variation, the display screen 94a is reduced in a state where the symbol variation display area that has been secured in the center of the display screen 94a (excluding the area where the hold information is displayed) is reduced. Will move to the corner (more specifically, the upper right part). As a result, the symbol row is reduced and displayed at the corner of the display screen 94a, and an area for executing a notice effect or the like is secured on the display screen 94a. Then, the notice effect is started in conjunction with the change of the symbol variable display area.

  For the notice effect, it constitutes the first half of a series of stories expressed in Super Reach D, and the story given to the notice effect proceeds and the reach is displayed when the above-mentioned pseudo variation is performed. At that point, the story branches and the latter half of the series of stories is displayed in the reach production.

  Returning to the description of FIG. 46, after the symbol variation display area is reduced as described above, the character C imitating a girl is displayed in the area where the symbol row has been displayed. As shown in FIG. 46 (c), the character C is arranged at a position on the left side of the display screen 94a, and an item simulating a microphone and a bag is displayed at a position on the right side of the display screen 94a. .

  Thereafter, as shown in FIGS. 46 (c) → (d), the girl character C moves across the display screen 94a toward the place where the microphone and bag items are arranged. When the character C reaches the place where the item is arranged, the symbol sequence that has been reduced and displayed on the upper right of the display screen 94a is enlarged so as to return to the original display position. The speed will decrease.

  After shifting to the deceleration mode in which the fluctuation display speed is reduced, the upper symbol row is stopped first, and then the lower symbol row is stopped. At this time, the girl character C remains stopped and displayed immediately before the item is obtained. Then, at the timing after the lower symbol row is stopped and reach display is performed, the character C grabs the former of the microphone and the bag.

  At this timing (reach display transition timing, reach production start timing), the display control subject is changed from the 2D display CPU 520 to the 3D display CPU 530, and the characters C and backgrounds displayed on the display screen 94a are displayed. The image is switched from a flat one to a three-dimensional one, and details of the change in display mode will be described later.

  When the reach effect is started, each symbol row is reduced and displayed again at the corner of the display screen 94a while maintaining the reach state. Thereafter, until the end of the game round, an effect by the girl character C holding the microphone on the display screen 94a is performed.

  On the other hand, from the state shown in FIG. 46 (d), when the upper symbol row and the lower symbol row are stopped in this order and reach display is not performed, the middle symbol row immediately stops and the above-described specific symbol combination is changed. Will be formed. When a specific symbol combination is stopped and displayed, the symbol sequence starts re-variation without ending the game round, as in the variation display mode shown in FIG. Then, the girl character C, which has been stopped and displayed until a specific symbol combination is formed, resumes its action and grabs the latter of both the microphone and bag items. Thereby, the notice effect is continued.

  After the symbol sequence starts to change again, after the girl character C has grabbed the bag, all the symbol sequences that have been displayed in the approximate center of the display screen 94a (the region excluding the region where the hold information is displayed) until then. In the state where the variable display area is reduced, the display screen 94a moves to the corner (specifically, the upper right portion).

  Thereafter, as shown in FIG. 46 (g), the transformation starts while holding the bag obtained by the girl character C. Immediately after the transformation starts, the variable display of the girl character C is stopped, and the symbol sequence displayed in a reduced size at the corner of the display screen 94a is enlarged so as to return to the position before the reduced display. Accordingly, the variable display speed decreases.

  After shifting to the deceleration mode in which the fluctuation display speed is reduced, the upper symbol row is stopped first, and then the lower symbol row is stopped. At this time, the girl character C remains stopped. Then, at the timing after the lower symbol row is stopped and reach display is performed, the transformation of the girl character C proceeds to the next step.

  At this timing (reach display transition timing, reach production start timing), the display control subject is changed from the 2D display CPU 520 to the 3D display CPU 530, and the character C or background image displayed on the display screen 94a. Will be switched from a flat one to a three-dimensional one, and the details of the change in the display mode will be described later.

  When the reach effect is started, each symbol row is reduced and displayed again at the corner of the display screen 94a while maintaining the reach state. Thereafter, until the end of the game round, a transformation effect by the girl character C is performed on the display screen 94a.

  On the other hand, from the state shown in FIG. 46 (i), when the upper symbol row and the lower symbol row are stopped in this order and reach display is not performed, the middle symbol row immediately stops and the above-described specific symbol combination is Will be formed. When a specific symbol combination is stopped and displayed, the symbol sequence starts re-variation without ending the game round, as in the variation display mode shown in FIG. Then, the girl character C, which has been stopped and displayed until a specific symbol combination is formed, resumes the action, fails to transform, and returns to the state before the transformation start. Thereby, the notice effect is continued.

  After the symbol sequence started to change again and the character C of the girl returned to the state of grabbing the bag, it was displayed on almost the entire area of the display screen 94a (excluding the area where the hold information is displayed). All the symbol rows are shifted to the corner (specifically, the upper right portion) of the display screen 94a, and are reduced and displayed at the corner.

  Thereafter, as shown in FIG. 46 (j), the flight starts across the kite obtained by the girl character C. Then, immediately after the flight is started, the variable display of the girl's image or the like is stopped, and the symbol row that is reduced and displayed at the corner of the display screen 94a is enlarged so as to return to the position before the reduced display. Accordingly, the variable display speed decreases.

  After shifting to the deceleration mode in which the fluctuation display speed is reduced, the upper symbol row is stopped first, and then the lower symbol row is stopped. At this time, the girl character C is maintained in a stopped state. Then, at the timing after the lower symbol row stops and reach display is performed, the traveling direction of the girl character C changes from the front to the side of the display screen.

  At this timing (transition timing to reach display start timing of reach production), the main body of display control is changed from the 2D display CPU 520 to the 3D display CPU 530, and the character C and the background image displayed on the display screen 94a are changed. Switching from a flat one to a three-dimensional one will be described later in detail.

  When the reach effect is started, each symbol row is reduced and displayed again at the corner of the display screen 94a while maintaining the reach state. Thereafter, the flight effect by the girl character C is performed on the display screen 94a until the end of the game round.

  In the super reach D in the present embodiment, not only a series of story characteristics are given to the notice effects, but each reach effect is configured so that its display mode and contents are a series with respect to the notice effects. . In other words, there are a plurality of reach effects that branch from the notice effect, and each of these branch patterns is configured to be recognized by the player as a series of the notice effect and the reach effect.

<Connection between notice production and reach production>
Hereinafter, with reference to FIG. 46 and FIG. 47, the aspect of each reach effect and the relationship between the reach effect and the notice effect will be described. FIG. 47 is a schematic diagram showing an outline of reach production. In FIG. 47, the character C in the reach effect is displayed two-dimensionally for convenience, but in reality, a three-dimensional display is performed. In the following description, the 2D girl character C is identified as “character C1”, and the 3D girl character C is identified as “character C2”.

  First, a case where the pseudo continuous notice is finished once will be described (refer to the group (e) in FIG. 46).

  A girl who grabs the microphone in the lower right part of the display screen 94a (misses a bag) when the symbol display starts and a specific symbol combination temporarily stops on the active line and then shifts to reach display. Character C1 is displayed. Thereafter, the symbol string is reduced and displayed in the upper right part of the display screen 94a. In addition to this, the 3D girl character C2 is displayed in a place (character display range) where the 2D girl character C1 has been displayed so as to be replaced with the 2D girl character C1. The 3D girl character C2 has the same position, size, posture (shape), etc. as the 2D girl character C1, that is, the character display areas are the same, and the preset period (In this embodiment, the display is stopped and displayed over the period until the switching (reduction display) of the display area of the symbol row is completed).

  In addition, when it shifts to reach production, the background image displayed so far is also changed to a 3D image, and the contents displayed on the display screen 94a are all 3D except for the symbol sequence and the hold information. Will be converted. In other words, the display content that has been displayed in 2D until then is directly replaced with 3D display.

<Relationship between 2D display and 3D display>
Here, the relevance between 2D display and 3D display will be supplementarily described with reference to FIG. FIG. 48 is a schematic diagram for explaining an outline of image processing.

  When the quasi-continuous advance notice is completed once, after the display is switched to the reach display, the underwater state is displayed as the background image in the same manner as before the reach display. The background image is scrolled in the horizontal direction at a constant speed, and the display mode is prevented from becoming monotonous by giving a motion to the background.

  Here, in the case of shifting to 3D display, a process of grasping what state (specifically, scroll position or the like) the background image variably displayed by the 2D display CPU 520 of the display control device 500 is. The 3D background image data is arranged in the virtual three-dimensional space so that the background is not shifted according to the grasped information. Specifically, the virtual image is displayed while 2D display is being performed. A background image and a character image (sprite data) are arranged on a two-dimensional plane so that the latter is positioned on the near side. At this time, each image is arranged with reference to the origin provided on the virtual two-dimensional plane.

  The background image is set to be larger than the substantially rectangular drawing range set on the virtual two-dimensional plane, and the background can be moved by changing the arrangement of the background image data little by little. It has become.

  Here, it is possible to grasp the scroll position of the background image by grasping the arrangement coordinates of the background image based on the origin in the virtual two-dimensional plane. Then, by converting the grasped two-dimensional coordinates into three-dimensional coordinates based on the origin in the virtual three-dimensional space, the arrangement of the background plate polygon data is determined.

  The plate polygon data is also set to be larger than the drawing range in the virtual three-dimensional space (specifically, the projection plane), and the background can be moved by changing the arrangement of the plate polygon data little by little. ing. As described above, in the configuration in which the background is moved in both the 2D display / 3D display, the position of the background is shifted when the display is switched to the 2D display / 3D display. Become. Therefore, as described above, the discomfort is suppressed by associating the position information of the 2D background image and the position information of the 3D background image.

  In the present embodiment, the background image includes not only the sea but also the sky, and when a pseudo-continuous notice occurs three times as described later, the girl character straddles the ridge. An effect of jumping out from the sea to the sky is performed. Also in this case, the background can be changed from the sea to the sky by changing the arrangement of the background images in the direction orthogonal to the scroll direction.

  With reference to FIG. 47 again, the contents of the effect when the pseudo continuous notice ends once will be described.

  After switching the display area of the symbol row, the stage is displayed at the center of the display screen 94a as shown in FIG. 47 (e2) → FIG. 47 (e3), and the scoreboard is displayed above the stage. . Then, the girl character C2 who has been waiting (stopped) in the corner of the display screen 94a moves toward the stage and sings a song using a microphone held in the hand after reaching the stage. Executed.

  When the singing effect is finished, the numbers that are variably displayed on the scoreboard are stopped and displayed, and the result of this game round is notified by the stopped and displayed numbers (scores). Specifically, when the current game round corresponds to the jackpot result, as shown in FIG. 47 (e4), “100 points” is displayed on the scoreboard and the change display of the middle symbol row is stopped. The symbol combination corresponding to the jackpot is displayed. On the other hand, when the game times this time correspond to the result of losing, as shown in FIG. 47 (e5), “0 points” is displayed on the scoreboard and the variable display is continued accordingly. In addition, the middle symbol row is stopped, and the symbol combination corresponding to the detachment result is displayed. Thus, the timing at which the symbol is stopped and displayed through the reach effect is synchronized with the timing at which the variable display of the working port display portion in the main display portion 90 ends.

  As described in detail above, when the pseudo continuous notice ends once, after the girl character C who appears on the display screen 94a in the notice effect obtains the microphone and shifts to the reach effect, Singing is performed using a microphone. At this time, with regard to the girl character C, when the transition is made from the notice effect to the reach effect, the effect (story) becomes a series because the position, size, posture, and the like coincide with those before the shift to the reach effect. It is possible to give the player an impression as if it were.

  Next, with reference to FIG. 47 (h), a case will be described in which the pseudo continuous notice is completed twice.

  When the change display of the symbol is started and the specific symbol combination temporarily stops on the active line and then shifts to the reach display, the girl character C1 holding the heel is displayed in the lower right part of the display screen 94a. The Thereafter, the symbol string is reduced and displayed in the upper right part of the display screen 94a. In addition to this, the 3D girl character C2 is displayed in a place (character display range) where the 2D girl character C1 has been displayed so as to be replaced with the 2D girl character C1. The 3D girl character C2 has the same position, size, posture (shape), etc. as the 2D girl character C1, that is, the character display areas are the same, and the preset period (In this embodiment, the display is stopped and displayed over the period until the switching (reduction display) of the display area of the symbol row is completed).

  In addition, when it shifts to reach production, the background image displayed so far is also changed to a 3D image, and the contents displayed on the display screen 94a are all 3D except for the symbol sequence and the hold information. Will be converted. In other words, the display content that has been displayed in 2D until then is directly replaced with 3D display.

  After switching the display area of the symbol row, an effect imitating a ring of light is added to surround the girl character as shown in FIG. 47 (h2) → FIG. 47 (h3), and the girl is displayed. The screen 94a moves from the corner to the center.

  When the game time this time corresponds to the jackpot result, the game time end timing is reached, and as shown in FIG. 47 (h4), the transformation of the girl character C2 is completed and the middle symbol sequence changes. The display stops and the symbol combination corresponding to the jackpot result is displayed. On the other hand, if the current game time corresponds to the result of losing, as shown in FIG. 47 (h5), the game character's character C2 fails to transform and returns to its original state at the end of the game time. Is displayed, the change display of the middle symbol row is stopped, and the symbol combination corresponding to the detachment result is displayed.

  As described in detail above, when the pseudo-continuous notice ends in 2 degrees, the transformation effect can be executed by the girl character C2 appearing on the display screen 94a in the notice effect having a bag. Sex is suggested. Here, with regard to the girl character C, when the transition from the notice effect to the reach effect is made, the notice effect and the reach effect (specifically, the story) become a series by matching the position, size, posture, and the like. It is possible to give the player an impression as if it were.

  Next, with reference to the group (k) in FIG. 47, the case where the pseudo continuous notice is performed three times (when the final stage is reached) will be described.

  When the change display of the symbol is started and the specific symbol combination temporarily stops on the active line and then shifts to the reach display, the girl character C1 straddling the heel is displayed in the lower right part of the display screen 94a. The Thereafter, the symbol string is reduced and displayed in the upper right part of the display screen 94a. In addition to this, the 3D girl character C2 is displayed in a place (character display range) where the 2D girl character C1 has been displayed so as to be replaced with the 2D girl character C1. The 3D girl character C2 has the same position, size, posture (shape), etc. as the 2D girl character C1, that is, the character display areas are the same, and the preset period (In this embodiment, the display is stopped and displayed over the period until the switching (reduction display) of the display area of the symbol row is completed).

  In addition, when it switches to reach production, the background image displayed until then is also changed to a 3D image, and the contents displayed on the display screen 94a are all 3D except for the symbol sequence and the hold information. Will be converted. In other words, the image displayed in 2D until then is switched to 3D display as it is.

  After that, the background is switched from the one corresponding to the sea to the one corresponding to the air, so that the girl jumps out from the sea to the sky, and the state of flying is displayed. Then, as shown in FIG. 47 (k2) → FIG. 47 (k3), the movement of the girl character image in the horizontal direction on the display screen 94a is started. At the same time, a character imitating a fairy is displayed on the display screen 94a.

  When the game times this time correspond to the jackpot result, as shown in FIG. 47 (k4), the girl catches the fairy at the center of the display screen 94a, and the middle symbol row change display is finished. The symbol combination corresponding to the jackpot result is stopped and displayed. On the other hand, when the game times this time correspond to the result of losing, as shown in FIG. 47 (k5), a message that the girl failed to catch the fairy is displayed, and the change display of the middle symbol row is displayed. At the end, the symbol combination corresponding to the detachment result is stopped and displayed.

  As described above in detail, when the pseudo-continuous notice continues three times, it is suggested that the girl who appeared on the display screen 94a in the notice effect straddles the bag and the flight effect may be executed. Here, with regard to the girl character C, when the transition from the notice effect to the reach effect is made, the notice effect and the reach effect (specifically, the story) become a series by matching the position, size, posture, and the like. It is possible to give the player an impression as if it were.

  According to the third embodiment described in detail above, the following excellent effects are produced.

  When the notice effect is started, it is assumed that the player pays attention to the effect in the hope that the temporary stop / restart continues for a plurality of times. Here, the announcement effect constitutes a series of stories, and the effect is diversified by providing a plurality of branch points at which the notice effect is switched to the reach effect. If diversification of production is made in this way, there is a concern that the notice function of the notice effect will not be performed well because the relationship between the content of the reach effect after branching and the content of the notice effect will be diluted. The Such an inconvenience can be prominent for a player who has little knowledge about the specifications of the gaming machine.

  In this respect, in this embodiment, the player is configured to recognize the notice effect and the reach effect as a series, so that the player can easily understand the relationship between the two effects. It becomes. Thereby, the interest improvement effect mentioned above can be exhibited suitably.

  More specifically, in the notice effect and the reach effect, the girl character C is the center of the effect, and the position and form (size, posture) of the girl character C at the end of the notice effect and the start of the reach effect. The position and form of the girl character C are the same. For this reason, the girl character C that has been displayed in the notice effect on the external appearance plays an active role in the reach effect as it is, and the player can easily grasp the relationship between the notice effect and the reach effect.

  In particular, the display area in which the girl character C is displayed at the end of the notice effect on the display screen 94a is the same as the display area in which the girl character C is displayed at the start of the reach effect. For this reason, it is easy to give the player the impression that the display of the character C has just shifted from the notice effect to the reach effect. Thereby, it can suppress that the relationship between a notice effect and a reach effect becomes difficult to understand.

  By executing the notice effect before reaching the reach state, it is possible to contribute to an improvement in the degree of attention to the display effect. After reaching the reach state, the reach effect is executed in a series of notice effects. Thereby, it can suppress that the relationship between a notice effect and a reach effect becomes difficult to understand. In addition, the production can be performed consistently before and after reaching the reach state. The content of the production can be enhanced without depending on the reach production executed after the display production is in the reach state.

  For example, it is possible to enhance the content of the production by setting a long period after reaching the reach state, that is, the implementation period of the reach production, but if such a configuration is adopted, it will be interesting Although it can contribute, the game period in one game round becomes excessively long, which accelerates the decrease in the operating rate of the gaming machine. In this regard, according to the present embodiment, the content of the production can be enhanced using the period before reaching the reach state without increasing the period after the reach state. Can be suitably suppressed.

  In the case of gaming machines of the type that shifts to reach display as a stage before the symbols are stopped and displayed, whether or not the transition to the specific gaming state is clearly indicated by the result of stopping the symbols, etc. The player's attention is easily directed to the symbol. If the notice effect is continued under such circumstances, the player's attention is temporarily separated from the effect image, and the process of continuing to the reach effect is easily overlooked. In this way, when the production progresses in a state where the player is not paying attention, when the player shifts to reach production and the player's attention returns, the player is given an impression that there is a gap in the production content. It becomes easy. This can make it difficult for the player to recognize the notice effect and the reach effect as a series.

  Therefore, as shown in the present embodiment, if it is configured to temporarily stop the production image before entering the reach state, and the production image that has been stopped until after reaching the reach state, That is, such a problem can be made difficult to occur if the effect is temporarily stopped during a period in which the player's attention is easily distracted.

  In particular, in a reach state, the variable display speed of the identification information is reduced as a preceding stage, and if the reduction of the variable display speed is caught by the player's eyes, the player's attention is easily directed to the identification information. . In this way, if the first effect is continued in a situation where the player's attention is separated from the effect image, the above-mentioned oversight tends to occur. In this regard, in the present embodiment, the effect image is temporarily stopped before the reach state is reached, and the effect image that has been stopped until the reach state is started again. In this way, the above-described inconvenience can be made difficult to occur if the effect is temporarily stopped during the period in which the player's attention is easily distracted.

  For example, when a plurality of continuous effects (notice effect → reach effect) including a part of the common contents are stored as image data for continuous effects in which the entire contents are defined for each continuous effect The total amount of image data can be enormous. On the other hand, as shown in the present embodiment, the image data for the notice effect and the image data for the reach effect are respectively stored, and a series of effects are created using the drawing data generated from each image data. If it is set as the structure which implements, the data amount of the image data concerning production can be decreased.

  Further, the image data related to the notice effect and the image data related to the reach effect can be handled individually, and the start timing of reading each image data can be shifted. As a result, it is possible to suppress an increase in the amount of data handled at a time and contribute to a reduction in control load.

  When a series of performances are performed using different image data, the above-mentioned interest-improving effect can be achieved by making it difficult for the player to grasp the relationship between the previous performance (notice performance) and the subsequent performance (reach performance). There is a concern that will not be demonstrated well. Such an inconvenience can be prominent for a player who has little knowledge about the specifications of the gaming machine.

  In this regard, as shown in this feature, a predetermined reach effect among a plurality of types of reach effects is a series of an image displayed in the reach effect and an image displayed in the ongoing notice effect. If it is configured to be recognized by the player when the player is present, the relationship between the two effects can be easily understood by the player. Thereby, the interest improvement effect mentioned above can be exhibited suitably.

  In addition, it is not limited to the description content of embodiment mentioned above, For example, you may implement as follows. Incidentally, each of the following configurations may be individually applied to the above-described embodiment, or a part or all of the configurations may be combined and applied to the above-described embodiment.

  (1) In each of the above embodiments, the 2D effect is normally executed on the display screen 94a, and the 3D effect is executed instead of the 2D effect when a predetermined condition is satisfied. And it was set as the structure which reads 3D image based on the implementation of 3D effect being determined from the image data concerning 3D effect. However, it is not always necessary that the data to be read ahead is a 3D image, and it may be a 2D image, moving image data, or the like. In other words, as image data for displaying a specific type of character or a specific type of background image, the first image data having a relatively high processing load in use and the second having a relatively low processing load in use. In the configuration in which the image data is set, it is possible to avoid a local increase in processing load by devising the reading of the first image data as shown in the above embodiment. The type of image data is arbitrary.

  In addition, about the structure which reads a moving image, before displaying moving image data on the display screen 94a, it is good to start decoding, for example at the timing which reading completed. Thereby, switching to the moving image display can be smoothly advanced, and an increase in processing load at the time of the switching can be suitably suppressed.

  (2) In the first embodiment, the reading of the 3D image data is started based on the reception of the hold command. However, in the configuration in which a series of effects are performed according to a predetermined flow, 3D A drawing list may be created in conjunction with reading of image data or after reading of 3D image data is completed. In particular, as shown in the above embodiment, since the 2D display CPU 520, the 3D display CPU 530, the first VRAM 560, and the second VRAM 570 are included, the 2D display CPU 520 and the first VRAM 560 are used in 3D. Even when the display CPU 530 and the second VRAM 570 are used, it is possible to suppress the 2D effect from being hindered.

  (3) It is good also as a structure which changes the start timing of 3D effect according to the period required for reading of a 3D image.

  For example, the data amount of the 3D image data is set to be large, the period required for reading the 3D image data is set to be longer than the period from the start of the game times to the predetermined start timing of the 3D effect. In the configuration in which reading of 3D image data is set to be completed by the predetermined start timing when reading is started at a time, in the latter reading pattern, the timing is as scheduled. It is also possible to start the 3D effect and delay the start timing so as to be the timing after the reading of the 3D image data is completed in the former pattern.

  In particular, if the configuration of the display control apparatus 500 becomes complicated, the period required for reading tends to vary due to the influence of processing load and the like. Therefore, if the start timing is changed in consideration of such variations, it is possible to realize diversification of production while avoiding further complication of the configuration.

  (4) In the above embodiment, the configuration is such that the reading of the 3D image is completed before shifting to the reach display, that is, the configuration in which the reach display and the reading of the 3D image are not performed at the same time (not overlapping). However, regarding the reading of the 3D image, it is sufficient that the reading is completed at least before the 3D effect is executed, and the reach display and the reading of the 3D image may be performed at the same time. However, as described above, in reach display, the processing load generated in the display control device 500 increases. Therefore, it is desirable to suppress a local increase in processing load by desirably reading the 3D image without overlapping the reach display.

  (5) In each of the above-described embodiments, the character image waits at the center of the screen during the period in which the 3D effect can be executed, and the character image moves only the arm portion. The character image may be moved on the display screen 94a left / right / up / down. In particular, in the second embodiment, a configuration in which a 3D effect starts when the operation switch 40 is operated, and a configuration in which the positions and shapes of the 2D image and the 3D image match is adopted. Is one of the features. Therefore, when such a modification is applied to the second embodiment, the position information (two-dimensional coordinates) of the 2D image (sprite data) is grasped when the drawing list is created, and the grasped position information 3 It may be configured to execute processing for conversion to dimensional coordinates.

  (6) In each of the above embodiments, the erasure of 3D image data is reserved on condition that a similar 3D effect is executed in a game round to be executed later. It is also possible to change the conditions for retaining the erasure of 3D image data as follows. In other words, when the game times of this time are a result of losing, and there is one corresponding to the jackpot result among the currently stored hold information, and the same reach display as this time is applied to the hold information, A configuration may be adopted in which erasure of the 3D image is reserved, and the reach display in the game times related to the hold information is forcibly performed for the 3D effect. In other words, when the same reach display corresponding to the jackpot is performed at a later game round, the 3D effect may be forcibly performed even if the player is out of the 3D effect lottery.

  Furthermore, if there is pending information corresponding to the jackpot result, if a sufficient time for production is secured, that is, if super reach is executed, the type of super reach is forcibly changed. You may change so that it may become the same as this game time. For example, by shortening the period from the normal variation display to the reach display, it is possible to suppress a sense of incongruity in the production due to the above-described forced adjustment.

  In the case where the above-described various modifications are adopted, a configuration may be adopted in which a display change command is transmitted from the display control device 500 to the sound lamp control device 143.

  (7) In each of the above-described embodiments, when the jackpot is won, the game is shifted to the opening / closing execution mode after the game is completed. In the opening / closing execution mode, the game times do not progress. Therefore, by adopting a configuration in which 3D image data is deleted after the end of the game corresponding to the jackpot result, the expansion buffer 571 of the second VRAM 570 can be used even during the open / close execution mode.

  (8) When winning the jackpot through the 3D effect, it is possible to keep the 3D image data and execute the display effect using the 3D image data during the opening / closing execution mode. As a result, it is possible to contribute to diversification of display effects during the opening / closing execution mode while suppressing an increase in processing load for reading image data.

  (9) In the above embodiment, the 2D display / 3D display is switched in the game times. However, the same switching may be performed during the opening / closing execution mode. For example, the jackpot type may be concealed at the end of the game, and the jackpot type may be suggested or notified by switching between 2D / 3D during the opening / closing execution mode.

  (10) In each of the above embodiments, the character is displayed in 3D, but the object to be displayed in 3D is arbitrary. For example, in addition to or instead of the character image, a configuration in which a background or a pattern is displayed in 3D may be used.

  (11) In each of the above embodiments, the overall control CPU 510, the 2D display CPU 520, and the 3D display CPU 530 are provided in the display control device 500. However, the function divided into these three may be given to one CPU. .

  (12) Display control based on a command output from the main control device 162 instead of a configuration in which the display control device 500 is controlled by the sound lamp control device 143 based on a command output from the main control device 162 The device 500 may be configured to control the sound lamp control device 143. In this case, the display control device 500 may determine the content of the effect based on a command input from the main control device 162 without passing through the sound lamp control device 143. Further, instead of the configuration in which the sound lamp control device 143 and the display control device 500 are provided separately, a configuration in which both control devices are provided as one control device may be employed. In this case, the aggregated control device may determine the content of the effect based on the command output from the main control device 162.

  Further, one function of the sound lamp control device 143 and the display control device 500 may be integrated into the main control device 162, or both functions of these two control devices may be integrated into the main control device 162. The configuration of commands output from the main control device 162 to the sound lamp control device 143 is also arbitrary.

  (13) In the second embodiment, the drawing list for displaying the 3D image is started when the operation switch 40 is operated by the player. However, the present invention is not limited to this. is not. As shown in the second embodiment, in a configuration in which a 2D image is replaced with a 3D image while a flow of a series of effects is determined, the 2D effect is being executed, that is, by the display CPU 520 for 2D. While the drawing list for displaying the 2D image is being created, the drawing list for the 3D effect may be created at any time in parallel with this. According to such a configuration, it is not necessary to create a drawing list for 3D image effect after accepting a player's operation, and it is possible to reduce a waiting period for creating the drawing list. Therefore, the drawing process by VDP can be immediately executed in response to the player's operation, and the responsiveness at the time of switching to 3D at the time of operation can be preferably improved.

  (14) In each of the above embodiments, the display effect executed on the display screen 94a is changed (promoted) from a planar 2D effect to a stereoscopic 3D effect as the game progresses. It is also possible to change this and change (downgrade) the 3D effect to the 2D effect as the game progresses. For example, if the game times corresponding to the jackpot result are configured so that the 3D effect is more likely to be continued than the game times corresponding to the missed result, for example, a configuration that suggests the winning expectation degree of the jackpot, The degree of attention can be suitably increased.

  (15) In the third embodiment, when a hold command is received from the sound lamp control device 143, reading of the required 3D image data from the memory module 540 is started. However, in the present embodiment, when a 3D effect is executed, 3D image data is required when the display is shifted to reach display. Therefore, if the reading of 3D image data can be completed before shifting to reach display, the timing for starting the reading of 3D image data may be arbitrarily changed. However, when executing the notice effect, the control load on the display control device 500 tends to increase during the period in which the notice effect is being executed. Therefore, if the above-described 3D image readout period overlaps with the execution period of the notice effect, the control load generated in the display control device 500 tends to increase. In view of such a problem, it is desirable to complete the reading of the 3D image before the start of the notice effect.

  (16) In the third embodiment, the notice effect as the “first effect” is the 2D effect and the reach effect as the “second effect” is the 3D effect, but the present invention is not limited to this. . A configuration in which the player recognizes that the notice effect and the reach effect are a series is sufficient, and whether the notice effect and the reach effect are the 2D effect or the 3D effect is arbitrary.

  (17) In the above embodiment, a story is provided that is consistent with the notice effect to the reach effect, but is not necessarily limited thereto. As described above, it is sufficient that the player recognizes that the notice effect and the reach effect are a series, and it is not always necessary to provide a consistent story. For example, still images (for example, an image during singing, an image during transformation, an image during flight) corresponding to each reach production (singing production, transformation production, flight production) are sequentially switched and displayed in the notice production, and stopped. If it is configured to shift to reach display corresponding to the still image, and the character displayed in the still image starts moving as it is by shifting to reach production, the announcement effect and reach effect are a series. The player can be recognized.

  (18) In the third embodiment, when the transition from the notice effect to the reach effect is made, the position, size, and posture of the character C being displayed on the display screen 94a are the same. As long as they are recognized to be the same, it is not necessary to completely match the position, size, and posture. However, if the position and appearance of the character C1 at the end of the notice effect and the character C2 at the start of the reach effect are greatly different, there is a concern that the function for linking the notice effect and the reach effect given to the character C is lowered. Is done. Therefore, it is desirable that the character display area be the same at the end of the notice effect and the start of the reach effect.

  (19) In the third embodiment, the position at which the character is last displayed in the notice effect, and further the position at which the character is first displayed in the reach effect in light of the size and posture of the character. Furthermore, the configuration in which the 2D character C1 and the 3D character C2 are interchanged by determining the size and posture of the character is not limited to this. For example, when shifting to the reach effect, various parameters such as position information, shape, size and the like of the character C1 displayed in 2D are read, and a 3D polygon data drawing list is used to inherit the parameters of the 2D character. May be set based on the read parameter.

  (20) In the third embodiment, the substantial effect area when switching from the notice effect to the reach effect is made to coincide, but at least the structure that is the main subject of the effect (in the above embodiment, the girl The display area of other display areas (background in the above embodiment) does not necessarily need to be matched.

  For example, when a flight effect is executed, the background during the notice effect may be similar to that of the sea, and after reach display, the structure may be switched to the one that simulates the sky. Even in this case, since the girl character C straddling the bag from the notice effect to the reach effect is displayed, it is possible to give the player an impression that both effects are in a series.

  (21) In the third embodiment, when a transition is made from a notice effect to a reach effect, a girl character is used during a period when the symbol variation display is decelerating (during the transition period to reach display). However, it is also possible to change the display effect so that the character continues to operate even during the transition period to reach display. However, when the symbol variation display is slowing down, it is easy to pay attention to whether the player's attention forms a specific symbol combination or reach display. It becomes difficult to make it appear. Furthermore, when the player's attention changes to the character's position or posture while the player's attention is diverted, when the player's attention is directed to the character in the reach display, It is assumed that it is easy to give an impression as if the production is not a series by being overlooked. Therefore, preferably, as shown in the above-described embodiment, during the period in which the player's attention is assumed to be away from the character, the effect by the character may be paused.

  (22) In the third embodiment, the sprite data is used for the notice effect (2D effect), and the polygon data is used for the reach effect (3D effect), so that data is shared with other reach effects. However, the present invention is not limited to this. In the configuration in which the aspect of the effect is determined in advance, for example, the sprite data and the polygon data are not used, but the notice effect and the reach effect are stored as moving image data, respectively. It is also possible to decode the moving image data and display the moving images on the display screen 94a.

  (23) In the third embodiment, by performing the pseudo continuous variation display, it is possible to avoid giving the player an image that a decrease in the variation display speed of the symbol is directly connected to the end of the notice effect. Although it has been configured to promote continuity, whether or not to perform pseudo continuous variation display is arbitrary.

  Instead of the pseudo continuous variation display, a so-called step-up effect may be used.

  (24) Other types of pachinko machines different from the above embodiment, for example, a pachinko machine in which an electric accessory is released a predetermined number of times when a game ball enters a specific area of a special device, or a game ball in a specific area of a special device The present invention can also be applied to a pachinko machine that generates a right if a player enters, a pachinko machine equipped with other objects, an arrangement ball machine, a sparrow ball, and the like.

  Also, a non-ball-type gaming machine, for example, a plurality of reels with a plurality of types of symbols attached in the circumferential direction, starts rotation of the reel by inserting a medal and operating a start lever, and a stop switch is operated. If a specific symbol or a combination of specific symbols is established on the effective line visible from the display window after the reel has stopped after a predetermined time has passed, a privilege such as paying out medals is given to the player The present invention can also be applied to a slot machine.

  Further, the gaming machine main body supported by the outer frame so as to be openable and closable is provided with a storage unit and a capture device, and the start lever is operated after a predetermined number of game balls stored in the storage unit are captured by the capture device. Thus, the present invention can also be applied to a gaming machine in which a pachinko machine and a slot machine are fused to start the rotation of the reel.

<Invention Group Extracted from the Embodiments>
Hereinafter, the features of the invention group extracted from the above-described embodiment will be described while showing effects and the like as necessary. In the following, for ease of understanding, the corresponding configuration in the above embodiment is appropriately shown in parentheses, but is not limited to the specific configuration shown in parentheses.

Feature A1. A display unit (design display device 94) having a display screen (display screen 94a);
First effect means (2D display CPU 520 or the like in the display control device 500) that performs the first effect as the display effect displayed on the display unit;
Similarly, a second effect means (3D display CPU 530 or the like in the display control device 500) that implements a second effect as a display effect displayed on the display unit,
A gaming machine that selects a first effect by the first effect means and a second effect by the second effect means to perform a display effect on the display unit when playing a game,
The second rendering means is
Read out the predetermined image data (for example, polygon data) compressed from the data storage means (the memory module 540 in the display control device 500) before the second presentation is performed on the display unit in a decompressed state. Means (function of executing image data reading processing in the 3D display CPU 530);
Data generating means (drawing in the display CPU 530 for 3D) that generates second effect drawing data using the image data read by the reading means and temporarily stores the second effect drawing data in the temporary storage means (second VRAM 570). Function to execute data generation processing)
Display control means (VDP 580 of the display control device 500) for causing the display section to display the second effect drawing data stored in the temporary storage means when performing the second effect on the display unit. ,
A determination unit that determines whether or not there is an execution request for the second presentation to be performed on the display unit after the current time in a game mode in which the first presentation by the first presentation unit is performed on the display unit;
Based on the determination by the determining means that there is an execution request, at least the former of the reading of the image data by the reading means and the generation and temporary storage of the second rendering data by the data generating means, A gaming machine comprising pre-processing execution means for carrying out preparation processing for the second effect.

  According to the feature A1, the image data used for the display effect is obtained by reading the compressed predetermined image data in a decompressed state before the timing at which the second effect is started. Can be suppressed from being limited by a period required for preparation (for example, a period required for reading). As a result, the use of image data with a large amount of data can be promoted to improve the appearance and diversify the display effects, thereby contributing to an improvement in the degree of attention to the display effects.

  As the amount of image data increases, the period required for reading from the data storage means becomes longer. In this regard, according to this feature, the second rendering data can be prepared with a margin. Thereby, it can suppress that the processing load which arises in a display control means immediately before performing the display effect using the drawing data for 2nd effects becomes large too much.

  When drawing data is generated using image data as described above, the processing load, the processing period, and the like increase as the amount of data increases. Here, for example, when a local increase in the processing load occurs, there is a concern that processing failure occurs or the formation of drawing data is delayed, and the smoothness of the display effect is likely to be impaired. This is not preferable because it may hinder improvement in the degree of attention to the display effect described above. In this regard, in this feature, the image data is read by the reading unit based on the determination that the display unit has a request for performing the second effect, so that at the start of the effect or just before that It can suppress that processing load etc. become large too much. Thereby, it is possible to suppress an increase in processing load due to the improvement in the degree of attention to the display effect. Therefore, diversification of display effects can be suitably realized.

  In recent years, there has been proposed a type of gaming machine that employs an operation means for production and changes the content of the production according to the operation. Therefore, if the preparatory process is performed in advance as described above, the period required to generate the drawing data at the time of accepting the operation can be shortened even when the technical idea shown in this feature is applied to the structure related to the operation corresponding effect. In addition, the responsiveness to the operation can be improved.

Feature A2. A display unit (design display device 94) having a display screen (display screen 94a);
First effect means (2D display CPU 520 or the like in the display control device 500) that performs the first effect as the display effect displayed on the display unit;
Similarly, a second effect means (3D display CPU 530 or the like in the display control device 500) that implements a second effect as a display effect displayed on the display unit,
A gaming machine that selects a first effect by the first effect means and a second effect by the second effect means to perform a display effect on the display unit when playing a game,
The second rendering means is
Reading means (reading process of image data in 3D display CPU 530) for reading predetermined image data (for example, polygon data) from data storage means (memory module 540 in display control device 500) before the execution of the second effect on the display unit Function to execute)
Data generating means (drawing in the display CPU 530 for 3D) that generates second effect drawing data using the image data read by the reading means and temporarily stores the second effect drawing data in the temporary storage means (second VRAM 570). Function to execute data generation processing)
Display control means (VDP 580 of the display control device 500) for causing the display section to display the second effect drawing data stored in the temporary storage means when performing the second effect on the display unit. ,
A determination unit that determines whether or not there is an execution request for the second presentation to be performed on the display unit after the current time in a game mode in which the first presentation by the first presentation unit is performed on the display unit;
Based on the determination by the determining means that there is an execution request, the reading of the image data by the reading means and the generation and temporary storage of drawing data for the second effect by the data generating means are performed. A gaming machine comprising pre-processing execution means to be implemented as a preparation process.

  According to the feature A2, by performing the preparation process of the second effect (reading of image data and generation and temporary storage of the second effect drawing data) before the timing at which the second effect is started, It can be suppressed that the data capacity of the image data used for the display effect is limited by a period required for preparation (for example, a period required for reading). As a result, the use of image data with a large amount of data can be promoted to improve the appearance and diversify the display effects, thereby contributing to an improvement in the degree of attention to the display effects.

  When drawing data is generated using image data, the processing load, the processing period, and the like increase as the amount of data increases. Here, for example, when a local increase in the processing load occurs, there is a concern that processing failure occurs or the formation of drawing data is delayed, and the smoothness of the display effect is likely to be impaired. This is not preferable because it may hinder improvement in the degree of attention to the display effect described above. In this regard, in this feature, the image data is read by the reading unit based on the determination that the display unit has a request for performing the second effect, so that at the start of the effect or just before that It can suppress that processing load etc. become large too much. Thereby, it is possible to suppress an increase in processing load due to the improvement in the degree of attention to the display effect. Therefore, diversification of display effects can be suitably realized.

Feature A3. The predetermined image data has a larger data amount than the image data used by the first rendering means.
The second effect means is characterized in that, after the first effect is executed on the display unit, the second effect is performed on the display unit. Gaming machine.

  In the configuration in which a large or small difference is set in the data amount of the image data as shown in the feature A3, it is easy to secure the preparation period of the drawing data for the second effect by causing the first effect to precede the second effect. Become.

Feature A4. Information acquisition means (a function for executing information acquisition processing in the MPU 402 of the main control device 162) for acquiring special information based on the establishment of a predetermined condition;
Grant determination means (a function for executing the pass / fail determination process in the MPU 402 of the main control device 162) for determining whether the special information acquired by the information acquisition means corresponds to the grant information;
A privilege granting unit (main control) that grants a privilege to a player based on the result of the grant determination by the grant determination unit being a grant response result that the determination target special information corresponds to the grant information The MPU 402 of the device 162)
The display control means has a pattern display means for variably displaying a plurality of patterns on the display screen,
In the display unit, the display of the variation of the pattern is started by starting the display of the variation of the pattern, displaying the stop result corresponding to the determination result of the grant determination, and ending the variation display of the pattern. Game time control means (function to execute game time control processing in the MPU 402 of the main control device 162) for controlling the picture display means so that display is performed,
In the variation display mode implemented by the display unit, after the variation display is started, other patterns except for the final stop pattern from among the patterns that are likely to be a combination of the patterns to be given are included. It includes an aspect that allows you to perform reach variation display that displays the final stop pattern in a variable manner under the stopped display condition.
The pre-processing execution unit performs reading of image data by the reading unit before shifting to the reach variation display based on the determination by the determination unit that there is an execution request. Thru | or the game machine as described in any one of characteristics A3.

  As shown in the feature A4, in the type of game machine in which the reach variation display is executed, it is general that various measures are taken to increase the attention level of the player after the reach variation display. For example, effects such as displaying a preset moving image or causing a character or the like to appear and causing the character to execute a predetermined action are performed. For this reason, after reaching reach variation display, the processing load on the display control means tends to be larger than before reaching reach variation display. Therefore, by adopting a configuration in which reading of the first image data described above is completed before shifting to reach variation display, it is not necessary to perform reading under a situation where the processing load is large, and the processing of the display control means An excessive increase in load can be suppressed.

  Feature A5. The preprocessing execution means reads out the image data by the reading means during a period in which the reach variation display is not performed on the display unit, and performs the reading during a period in which the reach variation display is performed. The gaming machine according to Feature A4, wherein the gaming machine is not performed.

  According to the feature A5, the effect shown in the feature 4 can be more suitably exhibited.

  In addition, “the special information acquired by the information acquisition unit includes an acquisition information storage unit (the reserved ball storage area 432 in the MPU 402 of the main control device 162) that stores a predetermined number as a plurality of numbers as an upper limit, The grant determination means determines whether or not the special information stored in the acquisition information storage means corresponds to the grant information, and a plurality of special information is stored in the acquisition information storage means. In the case of adopting the configuration in which the determination of the grant is sequentially performed for the plurality of special information in some cases, the reach fluctuation display is also displayed in other game times executed before the second effect is executed. Although it may be performed, even in such a configuration, a practically preferable configuration can be realized by avoiding reading at the time of reach variation display in other game times.

Feature A6. Information acquisition means (a function for executing information acquisition processing in the MPU 402 of the main control device 162) for acquiring special information based on the establishment of a predetermined condition;
Grant determination means (a function for executing the pass / fail determination process in the MPU 402 of the main control device 162) for determining whether the special information acquired by the information acquisition means corresponds to the grant information;
A privilege granting unit (main control) that grants a privilege to a player based on the result of the grant determination by the grant determination unit being a grant response result that the determination target special information corresponds to the grant information A function of executing a special prize opening / closing process in the MPU 402 of the device 162),
Special information acquired by the information acquisition means is provided with acquisition information storage means (holding ball storage area 432 in the MPU 402 of the main control device 162) that stores a predetermined number as an upper limit as a plurality of numbers,
The grant determination means determines whether or not the special information stored in the acquisition information storage means corresponds to the grant information, and a plurality of special information is stored in the acquisition information storage means. In some cases, the grant determination is sequentially performed on the plurality of special information.
The second rendering means is
A destination for determining whether or not the other special information stored in the acquired information storage means corresponds to the second effect using the predetermined image data after the predetermined image data is used. Determination means (overall CPU 510 of the display control device 500);
If it is determined by the destination determination means that other special information corresponding to the second effect using the predetermined image data exists, at least the second effect at the game times related to the special information The game machine according to any one of features A1 to A5, further comprising reservation means for retaining the erasure of the predetermined image data until is executed.

  According to the feature A6, when the second effect relating to the same image data is scheduled to be performed again after the game times in which the second effect relating to the predetermined image data is executed, it is stored in the temporary storage means. The predetermined image data is kept without being erased until the next use. Thereby, it is possible to avoid unnecessary deletion and re-reading of predetermined image data that has been read once, and to suppress the processing load when an effect related to the predetermined image is executed later.

  It should be noted that there is other special information for which use of the temporary storage means has been determined between the special information relating to the game times and the special information corresponding to the second effect relating to the subsequent predetermined image data. In such a case, it is preferable that the predetermined image data is erased without reservation. Thereby, it can suppress that the storage capacity calculated | required by a temporary memory means becomes uselessly large.

Feature A7. The second rendering means is
A reading period grasping means for grasping a period required for reading the predetermined image data by the reading means in a period required for preparation by the preprocessing execution means;
Features A1 to A characterized by comprising start timing determining means for determining the start timing of the second effect by the second effect means according to the read period grasped by the read period grasping means. The gaming machine according to any one of A3.

  The period required for reading a predetermined image may vary depending on the processing load at the time of reading. Therefore, it is possible to suppress the second effect from becoming monotonous by adopting a configuration in which the timing for starting the second effect is changed according to the period required for reading.

  It should be noted that “information acquisition means (a function for executing information acquisition processing in the MPU 402 of the main control device 162) that acquires special information based on the establishment of a predetermined condition, and the special information acquired by the information acquisition means is assigned information. The determination of whether or not the information corresponds to the grant determination means (function for executing the determination process in the MPU 402 of the main controller 162) and the result of the grant determination by the grant determination means indicate that the special information to be determined is A privilege granting means for granting a privilege to a player based on a result of granting correspondence corresponding to the granting information (a function of executing a big prize opening / closing process in the MPU 402 of the main control device 162); Acquisition information storage means (main control device 16) for storing the special information acquired by the information acquisition means as a plurality of numbers, with a predetermined number as an upper limit. The MPU 402 has a holding ball storage area 432), and the grant determination unit performs grant determination as to whether or not the special information stored in the acquisition information storage unit corresponds to the grant information. When a plurality of special information is stored in the information storage means, the combination determination is sequentially performed on the plurality of special information. When the configuration is used in combination, the number of special information stored in advance, etc. Due to this, the period for reading predetermined image data can be changed. That is, the start timing of the second effect can be changed. For example, a player who wants to watch the second effect for as long as possible will play a game in a state where a lot of special information is stored, which can contribute to an improvement in the operating rate of the gaming machine.

Feature A8. Information acquisition means (a function for executing information acquisition processing in the MPU 402 of the main control device 162) for acquiring special information based on the establishment of a predetermined condition;
Grant determination means (a function for executing the pass / fail determination process in the MPU 402 of the main control device 162) for determining whether the special information acquired by the information acquisition means corresponds to the grant information;
A privilege granting unit (main control) that grants a privilege to a player based on the result of the grant determination by the grant determination unit being a grant response result that the determination target special information corresponds to the grant information A function of executing a special prize opening / closing process in the MPU 402 of the device 162),
Special information acquired by the information acquisition means is provided with acquisition information storage means (holding ball storage area 432 in the MPU 402 of the main control device 162) that stores a predetermined number as an upper limit as a plurality of numbers,
The grant determination means determines whether or not the special information stored in the acquisition information storage means corresponds to the grant information, and a plurality of special information is stored in the acquisition information storage means. In some cases, the grant determination is sequentially performed on the plurality of special information.
The second rendering means is
A destination for determining whether or not the other special information stored in the acquired information storage means corresponds to the second effect using the predetermined image data after the predetermined image data is used. Determination means (overall CPU 510 of the display control device 500);
If it is determined by the destination determination means that other special information corresponding to the second effect using the predetermined image data exists, at least the second effect at the game times related to the special information The gaming machine according to feature A7, further comprising reservation means for retaining the erasure of the predetermined image data until is executed.

  According to the feature A8, when the second effect relating to the same image data is scheduled to be performed again after the game times in which the second effect relating to the predetermined image data is executed, it is stored in the temporary storage means. The predetermined image data is kept without being erased until the next use. Thereby, it is possible to avoid unnecessary deletion and re-reading of predetermined image data that has been read once, and to suppress the processing load when an effect related to the predetermined image is executed later.

  It should be noted that there is other special information for which use of the temporary storage means has been determined between the special information relating to the game times and the special information corresponding to the second effect relating to the subsequent predetermined image data. In such a case, it is preferable that the predetermined image data is erased without reservation. Thereby, it can suppress that the storage capacity calculated | required by a temporary memory means becomes uselessly large.

Feature A9. The game state is shifted to a special game state advantageous to the player based on the result of the grant determination by the grant determination means that the grant target result indicates that the special information to be determined corresponds to the grant information. Game state transition means (function to shift to the opening / closing execution mode in the MPU 402 of the main controller 162),
A result determination means for determining whether or not the game time is a game time corresponding to the winning result after the second effect is completed;
In the special game state, the start of the next game round is restricted until the special game state ends,
The gaming machine according to Feature A6 or Feature A8, wherein the predetermined image data stored in the temporary storage unit is deleted when the result of the determination of grant is a result of grant.

  By adopting a configuration in which the image data stored in the temporary storage unit is appropriately deleted, an increase in the storage capacity required for the temporary storage unit can be suppressed. When the game state is shifted to the special game state, the first image data may be unnecessary until the next game round is started. Therefore, when the winning result is obtained, it is practically preferable to delete the first image data on condition that there is no corresponding special information stored in the stored special information. The configuration can be realized.

Feature A10. Information acquisition means (a function for executing information acquisition processing in the MPU 402 of the main control device 162) for acquiring special information based on the establishment of a predetermined condition;
Acquisition information storage means for storing the special information acquired by the information acquisition means as a plurality of numbers, with a predetermined number as an upper limit (the reserved ball storage area 432 in the MPU 402 of the main control device 162);
Grant determination means (a function for executing the pass / fail determination process in the MPU 402 of the main control device 162) for determining whether the special information acquired by the information acquisition means corresponds to the grant information;
A privilege granting unit (main control) that grants a privilege to a player based on the result of the grant determination by the grant determination unit being a grant response result that the determination target special information corresponds to the grant information The MPU 402 of the device 162)
The grant determination means determines whether or not the special information stored in the acquisition information storage means corresponds to the grant information, and a plurality of special information is stored in the acquisition information storage means. In some cases, the grant determination is sequentially performed on the plurality of special information.
The display control means has a pattern display means for variably displaying a plurality of patterns on the display screen,
In the display unit, the display of the variation of the pattern is started by starting the display of the variation of the pattern, displaying the stop result corresponding to the determination result of the grant determination, and ending the variation display of the pattern. Game time control means (function to execute game time control processing in the MPU 402 of the main control device 162) for controlling the picture display means so that display is performed over a predetermined variable display period,
Determination means (display control device 500) for determining whether or not there is any other special information stored in the acquired information storage means corresponding to the assignment determination result after use of the predetermined image data; ,
When it is determined by the determination means that there is a piece of other special information corresponding to the grant determination result, the second aspect is executed in the game mode related to the other special information. A production mode changing means to change;
Any one of features A1 to A9, further comprising reservation means for retaining the erasure of the predetermined image data until the second effect is executed at least in the game times related to the special information. The gaming machine according to one.

  In a game, if the result of the display effect is just off, it will be difficult to draw the player's attention even if the effect occurs thereafter. In this regard, according to the present feature, even if the second effect is executed and the result is a losing result, the second effect is executed again when the grant determination result (for example, a winning result) is subsequently obtained. Thus, it can be avoided that only a disappointing result is impressed on the player. Thereby, when the display effect concerning the predetermined image data is executed, it is possible to make it difficult to cause the inconvenience that the effect of improving the attention level is not satisfactorily exhibited.

  For example, “the variable display period includes a first variable display period and a second variable display period set longer than the first variable display period, and the second effect is the second variable display period. It is configured to be executed when it is a period, and for the special information in which the grant determination result by the grant determination means becomes the grant result, the second variable display period is selected as the variable display period of the pattern By applying the technical idea shown in the present feature to the “configuration”, it is possible to preferably avoid the inconvenience that the smooth progress of the game is hindered by the change in the performance.

Feature A11. The second effect means is three-dimensional image data corresponding to a two-dimensional object displayed on the display unit when the first effect is being executed,
Comprising object information acquisition means for acquiring object information relating to the object displayed on the display screen;
The data generation means has means for changing the mode of the predetermined image data based on the object information acquired by the object information acquisition means,
Any one of features A1 to A10, wherein the second rendering means replaces at least the object with a three-dimensional image generated from the predetermined image data when a predetermined display switching timing is reached. The gaming machine described in one.

  According to the feature A11, in a process in which a series of effects are performed, an object constituting at least a part of the second image is replaced with a 3D image, so that at least a part of the image is changed from the 2D image to An impression can be given to the player as if it was switched to a three-dimensional image.

  In addition, since the object information acquisition unit is included, the timing for switching to the first image can be arbitrarily set. Even if the degree of freedom is ensured in this way, it is possible to reduce the data to be prepared in advance and realize a practically preferable configuration.

  Note that “changing the mode of the predetermined image data” means that the predetermined image data is arranged in the virtual three-dimensional space so as to be in the same position as the object, and the predetermined image data is assigned to the object. "Replace with a three-dimensional image generated from predetermined image data" means to hide the two-dimensional object displayed on the display unit and to view the virtual three-dimensional space. , Projecting the predetermined image data onto a projection plane set based on the viewpoint, and generating drawing data based on the data projected onto the projection plane.

Feature A12. Operation means (operation switch 40) operated by the player;
Informing means (informing function in the display control device 500) for informing that the operation is effectively accepted,
The game machine according to any one of features A1 to A11, wherein the data generation means generates drawing data for second effect based on the operation of the operation means. .

  In the configuration in which the display effect is changed based on the player's operation, the sense of unity between the operation and the effect tends to decrease due to a decrease in responsiveness to the operation. In this regard, in this feature, it is possible to suppress the period until the object related to the predetermined image data is displayed at the place where the object that is the target of the second effect is displayed on the display screen. It can be suitably executed.

  In particular, by completing the reading of predetermined image data in advance, it is possible to reduce the processing to be executed at the time of operation and to improve the responsiveness.

  The above feature A group is effective when applied to the following problems.

  A gaming machine such as a pachinko gaming machine or a slot machine has a control board on which an element such as a memory storing a control program related to the game and a CPU are mounted, and a series of games are controlled by the control board. . A configuration is also known in which the CPU and the memory are not individually mounted on the control board, but are mounted on the control board in an integrated state.

  Among the above gaming machines, those equipped with a display device such as a liquid crystal display device having a display screen are known. Such a gaming machine is equipped with a memory for image data having image data stored in advance, and a predetermined image is displayed on the display screen using the image data read from the memory (for example, JP 2007-7465 gazette).

  The case where an image is displayed using two-dimensional image data will be described in more detail. The image data memory stores image data for displaying a background, image data for displaying a character, and the like. By reading out the image data, drawing data for displaying a character or the like in front of the background is formed. Then, the drawing data is stored in a storage means such as a VRAM, and a signal is output to the display device based on the drawing data, so that an image in which characters and the like are arranged in front of the background is displayed on the display screen. Is done.

  In recent years, an attempt has been made to display a more three-dimensional image by using image data defined in three dimensions rather than simply displaying a two-dimensional image. When the display is performed, a polygon that is 3D image data is arranged in the virtual 3D space, and a texture that is 2D image data such as a character or a pattern is pasted on the polygon. Drawing data is created by projecting the polygon to which the is pasted onto a plane from a desired viewpoint. A three-dimensional image is displayed on the display screen by outputting a signal to the display device based on the drawing data.

  Here, for example, by using image data having a large amount of data such as the above-described three-dimensional image data, it is possible to improve the appearance and diversify the display effect, and contribute to an increase in the degree of attention to the display effect. . However, as the amount of data increases, the processing load, the time required for processing, and the like increase. For example, when a local increase in processing load occurs, there is a concern that processing may be lost or the formation of drawing data may be delayed, and the smoothness of display effects may be impaired. This is not preferable because it may hinder improvement in the degree of attention to the display effect described above.

Feature B1. A display unit (design display device 94) having a display screen (display screen 94a);
First effect means (2D display CPU 520 or the like in the display control device 500) that performs the first effect as the display effect displayed on the display unit;
Similarly, a second effect means (3D display CPU 530 or the like in the display control device 500) that implements a second effect as a display effect displayed on the display unit,
A gaming machine that selects a first effect by the first effect means and a second effect by the second effect means to perform a display effect on the display unit when playing a game,
Data storage means (memory module 540 in the display control device 500) for storing the first effect image data related to the first effect and the second effect image data related to the second effect, respectively.
The first effect means has means for generating first effect drawing data using the first effect image data read from the data storage means,
The second effect means includes means for generating second effect drawing data using the second effect image data read from the data storage means,
Under a game mode in which the first effect by the first effect means is performed on the display unit, a determination unit that determines whether or not there is an execution request for the second effect to be performed on the display unit after the present time,
The second effect means is a second effect in which a predetermined second effect is displayed in the second effect among a plurality of types of second effects based on the determination that the determination means determines that there is an execution request. A gaming machine, wherein the player recognizes that a series of the production image and the first production image displayed in the first production being performed is recognized.

  For example, for a plurality of continuous effects, in the case where image data for continuous effects in which the entire contents are defined for each continuous effect is stored even though some of the continuous effects are common, the image data The total amount of can be enormous. In this regard, as shown in this feature, the first effect image data and the second effect image data are stored, and a series of effects are performed using the drawing data generated from each image data. If so, it is possible to reduce the amount of image data required for the production.

  In addition, since the image data related to the first effect and the image data related to the second effect can be handled individually, for example, the read start timing of each image data can be shifted. As a result, it is possible to suppress an increase in the amount of data handled at a time and contribute to a reduction in control load.

  However, when diversifying the production using a plurality of image data, there is a concern that the above-mentioned interest improvement effect will not be exhibited well because it becomes difficult for the player to grasp the relationship between the first production and the second production. Is done. Such an inconvenience can be prominent for a player who has little knowledge about the specifications of the gaming machine.

  In this regard, as shown in this feature, a predetermined second effect among a plurality of types of second effects is displayed in the second effect image displayed in the second effect and the first effect being executed. If the player is configured to recognize that the first production images are in a series, the relationship between the two productions can be easily understood by the player. Thereby, the interest improvement effect mentioned above can be exhibited suitably.

  Feature B2. In the display screen, when the transition from the first effect to the second effect is performed, the display area in which the first effect image is displayed last, and the display screen shifts from the first effect to the second effect. The gaming machine according to Feature B1, wherein a display area where the second effect image is displayed first is the same.

  According to the feature B2, the area where the first effect image is displayed at the end of the first effect is the same as the area where the second effect image is displayed at the start of the second effect. Thus, if the display area of the effect image at the time of effect transition is the same, it is easy to recognize that the first effect and the second effect are a series.

Feature B3. The first effect means has means for displaying a first effect character image as the first effect image,
The second effect means has means for displaying a second effect character image as an image of the second effect that is recognized by the player as having the same appearance as the first effect character image,
On the display screen, the second effect character image displayed when the first effect is shifted to the second effect is displayed when the first effect is transferred to the second effect. The gaming machine according to Feature B1 or Feature B2, wherein the effect character image and the character position and form are the same.

  According to the feature B3, the position and form (shape and size) of the character in the first effect image displayed at the end of the first effect and the second effect image displayed at the start of the second effect. Is the same. For this reason, when the transition is made from the first effect to the second effect, the second character image is replaced with the first character image, and the player can be recognized as if the display effect continues without interruption. Thereby, a player can be made to recognize that the image for 1st effects and the image for 2nd effects are a series.

Feature B4. Variable display means (display control device 500) for stopping and displaying the identification information in order to derive a game result after performing variable display of a plurality of types of identification information each identifiable on the display screen;
When the identification information stopped and displayed by the variable display means is a specific display result, the gaming machine shifts to a specific gaming state that is more advantageous to the player than usual,
After the second presentation means has reached a reach state in which the identification information stopped and displayed on the display screen constitutes a part of the specific display result and at least a part of the identification information is variably displayed. Implement the second production as a reach production,
The first effect means implements the first effect as a suggestion effect suggesting a second effect that can be executed after the reach state is reached in the same game round before the reach state. The gaming machine according to any one of features B1 to B3.

  According to the feature B4, by executing the first effect (suggesting effect) before the reach state is reached, it is possible to contribute to an improvement in the degree of attention to the display effect. After reaching the reach state, the second effect (reach effect) is executed in a series of the first effect (implying effect). Thereby, it can suppress that the relationship between a 1st effect and a 2nd effect becomes difficult to understand.

  In addition, the production can be performed consistently before and after reaching the reach state. There is no dependency on only the second effect executed after the display effect reaches the reach state, and the contents of the effect can be enhanced.

  For example, it is possible to enhance the contents of the production by setting the period after reaching the reach state, that is, the implementation period of the second production to be long. However, when such a configuration is adopted, the interest is improved. Although it can contribute to the game, the longer the period from the start to the end of the game times, the slower the operating rate of the gaming machine. In this regard, according to this feature, the production content can be enriched by using the period before reaching the reach state without lengthening the period after the reach state. This can be suitably suppressed.

  Feature B5. The first effect means stops displaying the first effect image on the display screen before entering the reach state, and the stopped display image remains stopped until the second effect is started. The gaming machine according to Feature B4.

  In the gaming machine of the type shown in the feature B4, whether or not the transition to the specific gaming state is performed is clearly indicated by the stop result of the identification information. It becomes easy to turn to. If the first effect is continued under such circumstances, the player's attention is temporarily separated from the effect image, so that the process of continuing to the second effect is easily overlooked. When the production progresses in a state where the player is not paying attention in this way, when the player moves to the second production and the player's attention returns, the player is given an impression that there is a gap in the production contents. It becomes easy to give. This may make it difficult to recognize the first effect and the second effect as a series.

  Therefore, as shown in this feature, if the effect image is temporarily stopped before reaching the reach state, and the effect image that has been stopped until then reaches the reach state, that is, a game is started. Such a problem can be made difficult to occur if the production is paused during a period in which the attention of the person is easily distracted.

Feature B6. As a step before shifting to the reach state, the vehicle is provided with a deceleration means (display control device 500) for reducing the variable display speed of the identification information.
The first effect means stops displaying the first effect image on the display screen before the variable display speed is lowered by the deceleration means, and stops displaying the image until the second effect is started. The gaming machine according to Feature B4, wherein the gaming machine is left as it is.

  In the gaming machine of the type shown in the feature B4, whether or not the transition to the specific gaming state is performed is clearly indicated by the stop result of the identification information. It becomes easy to turn to. In particular, in a reach state, the variable display speed of the identification information is reduced as a preceding stage, and if the reduction of the variable display speed is caught by the player's eyes, the player's attention is easily directed to the identification information. . As described above, when the first effect is continued in a situation where the player's attention is separated from the effect image, the process of continuing to the second effect is easily overlooked. Then, when the production progresses in a state in which the player is not paying attention, the player feels as if there is a gap in the production contents when the player's attention returns to the second production. It becomes easy to give. This may make it difficult to recognize the first effect and the second effect as a series.

  Therefore, as shown in this feature, if the effect image is temporarily stopped before reaching the reach state, and the effect image that has been stopped until then reaches the reach state, that is, a game is started. Such a problem can be made difficult to occur if the production is paused during a period in which the attention of the person is easily distracted.

Feature B7. When the first effect is being executed, a plurality of timings at which the first effect can be transferred to the second effect are set.
When the image data for the second effect shifts to the second effect, one-to-one correspondence to each timing that can be shifted so as to be continuous with the image for the first effect displayed on the display screen at that time. The gaming machine according to any one of features B1 to B6, wherein each of the gaming machines is stored.

  According to the feature B7, a plurality of transition patterns from the first effect to the second effect are set, and the diversification of the effects can be realized. If the technical idea shown in the feature B1 or the like is applied to such a configuration, a configuration in which the relevance between the first effect and the second effect can be easily grasped is realized. Thereby, even if it aims at diversification of production, it can control that it becomes difficult to understand the relevance of the 1st production and the 2nd production resulting from it. Therefore, it becomes easy to exhibit the interest improvement effect shown in the feature B1.

  In the combination with the features B4 to B6, the transition destination may be changed depending on the timing when the reach state is reached (the progress status of the first effect). In such a configuration, since the connection between the first effect and the second effect is secured, it is possible to avoid interruption when the flow of the effect is in the reach state.

Feature B8. The second rendering means is
Read out the predetermined image data (for example, polygon data) compressed from the data storage means (the memory module 540 in the display control device 500) before the second presentation is performed on the display unit in a decompressed state. Means (function of executing image data reading processing in the 3D display CPU 530);
Data generating means (drawing in the display CPU 530 for 3D) that generates second effect drawing data using the image data read by the reading means and temporarily stores the second effect drawing data in the temporary storage means (second VRAM 570). Function to execute data generation processing)
Display control means (VDP 580 of the display control device 500) for causing the display section to display the second effect drawing data stored in the temporary storage means when performing the second effect on the display unit. ,
A determination unit that determines whether or not there is an execution request for the second presentation to be performed on the display unit after the current time in a game mode in which the first presentation by the first presentation unit is performed on the display unit;
Based on the determination by the determining means that there is an execution request, at least the former of the reading of the image data by the reading means and the generation and temporary storage of the second rendering data by the data generating means, The gaming machine according to any one of features B1 to B7, further comprising preprocessing execution means that is executed as preparation processing for the second effect.

  According to the feature B8, a series of effects is divided into a first effect and a second effect, and image data corresponding to each effect is individually stored. It is possible to prevent the control load from becoming excessively large by adopting a configuration in which drawing data for the second effect performed after the first effect is read based on the determination means determining that there is an execution request. it can.

Feature B9. The second rendering means is
Read out the predetermined image data (for example, polygon data) compressed from the data storage means (the memory module 540 in the display control device 500) before the second presentation is performed on the display unit in a decompressed state. Means (function of executing image data reading processing in the 3D display CPU 530);
Data generating means (drawing in the display CPU 530 for 3D) that generates second effect drawing data using the image data read by the reading means and temporarily stores the second effect drawing data in the temporary storage means (second VRAM 570). Function to execute data generation processing)
Display control means (VDP 580 of the display control device 500) for causing the display section to display the second effect drawing data stored in the temporary storage means when performing the second effect on the display unit. ,
A determination unit that determines whether or not there is an execution request for the second presentation to be performed on the display unit after the current time in a game mode in which the first presentation by the first presentation unit is performed on the display unit;
Based on the determination by the determining means that there is an execution request, at least the former of the reading of the image data by the reading means and the generation and temporary storage of the second rendering data by the data generating means, A gaming machine according to any one of features B1 to B7, further comprising preprocessing execution means that is executed during execution of the first effect as a preparation process for the second effect. .

  According to the feature B9, a series of effects is divided into a first effect and a second effect, and image data corresponding to each effect is individually stored. By preparing the drawing data for the second effect performed after the first effect during the execution of the first effect, the transition to the second effect can be performed smoothly.

  The feature B9 and the feature B10 are remarkably exhibited by applying the configuration in which the data amount of the image data used in the second effect is larger than the data amount of the image data used in the first effect. Can be made.

Feature B10. Operation means (operation switch 40) operated by the player;
The operating means is operated during the effective period in which the operation of the operating means is valid during the period in which the first effect is being executed under the situation where the determining means determines that there is an execution request. An operation receiving means for receiving the operation, and
Informing means (informing function in the display control device 500) for informing that the operation is effectively accepted,
The second effect means performs the second effect when an operation is accepted by the operation accepting means,
The second rendering means is
Reading means for reading predetermined second effect image data (for example, polygon data) compressed from the data storage means (the memory module 540 in the display control device 500) until the effective period is reached. (A function of executing image data reading processing in the 3D display CPU 530);
Grasping means for grasping a display state of the first effect image by the first effect at a timing when the operation is accepted by the operation accepting means;
Data generating means (for 3D) for generating second effect drawing data using the second effect image data read by the reading means, and temporarily storing the second effect drawing data in the temporary storage means (second VRAM 570). Display data generation function in the display CPU 530),
The data generation means generates the second effect drawing data in correspondence with the display information concerning the first effect image grasped by the grasping means, whereby the first effect and the second effect are obtained. The gaming machine according to any one of features B1 to B7, wherein the player recognizes the game as a series.

  In the configuration in which the display effect is changed based on the player's operation, the sense of unity between the operation and the effect tends to decrease due to a decrease in responsiveness to the operation. In this regard, in this feature, when the player operates the operating means while the first effect is being performed on the display screen, the second effect is made corresponding to the display information relating to the first effect image. Drawing data is generated. Thereby, the series of both productions is secured.

  In particular, the second effect drawing data is generated using the second effect image data that has been read out before the period during which the operation is valid. By completing the reading of the image data in advance, it is possible to reduce processing to be executed at the time of operation, and to improve the responsiveness.

Feature B11. Operation means (operation switch 40) operated by the player;
The operating means is operated during the effective period in which the operation of the operating means is valid during the period in which the first effect is being executed under the situation where the determining means determines that there is an execution request. An operation receiving means for receiving the operation, and
Informing means (informing function in the display control device 500) for informing that the operation is effectively accepted,
The second effect means performs the second effect when an operation is accepted by the operation accepting means,
The second rendering means is
Reading means for reading predetermined second effect image data (for example, polygon data) compressed from the data storage means (the memory module 540 in the display control device 500) until the effective period is reached. (A function of executing image data reading processing in the 3D display CPU 530);
Data generating means (for 3D) for generating second effect drawing data using the second effect image data read by the reading means, and temporarily storing the second effect drawing data in the temporary storage means (second VRAM 570). A function of executing drawing data generation processing in the display CPU 530),
After the effective period, it has grasping means for grasping the display state of the first effect image by the first effect at a predetermined cycle,
The data generation means generates the second effect drawing data in correspondence with display information related to the first effect image grasped by the grasping means,
When the operation is accepted by the operation accepting unit, the second effect image is displayed by the second effect drawing data stored in the temporary storage unit at that time, whereby the first effect and The gaming machine according to any one of features B1 to B7, wherein the player is made to recognize that the second effect is a series.

  In the configuration in which the display effect is changed based on the player's operation, the sense of unity between the operation and the effect tends to decrease due to a decrease in responsiveness to the operation. In this regard, in this feature, when the operation means is operated by the player while the first effect is being performed on the display screen, the second effect drawing data generated so far is used. The second effect is started. Thus, by preparing the image data for 2nd effect and the drawing data for 2nd effect in advance, the responsiveness mentioned above is improved and the continuous of a 1st effect and a 2nd effect is implement | achieved suitably. be able to.

Feature B12. A display unit (design display device 94) having a display screen (display screen 94a);
First effect means (2D display CPU 520 or the like in the display control device 500) that performs the first effect as the display effect displayed on the display unit;
Similarly, a second effect means (3D display CPU 530 or the like in the display control device 500) that implements a second effect as a display effect displayed on the display unit,
A gaming machine that selects a first effect by the first effect means and a second effect by the second effect means to perform a display effect on the display unit when playing a game,
Data storage means (memory module 540 in the display control device 500) for storing the first effect image data related to the first effect and the second effect image data related to the second effect, respectively.
The first effect means has means for generating first effect drawing data using the first effect image data read from the data storage means,
The second effect means includes means for generating second effect drawing data using the second effect image data read from the data storage means,
The second effect means displays a predetermined second effect among a plurality of types of second effects as a second effect image displayed in the second effect and a first effect being executed. A gaming machine that is implemented so that a player recognizes that a series of images for one effect is in series.

  For example, for a plurality of continuous effects, in the case where image data for continuous effects in which the entire contents are defined for each continuous effect is stored even though some of the continuous effects are common, the image data The total amount of can be enormous. In this regard, as shown in this feature, the first effect image data and the second effect image data are stored, and a series of effects are performed using the drawing data generated from each image data. If so, it is possible to reduce the amount of image data required for the production.

  In addition, since the image data related to the first effect and the image data related to the second effect can be handled individually, for example, the read start timing of each image data can be shifted. As a result, it is possible to suppress an increase in the amount of data handled at a time and contribute to a reduction in control load.

  However, when diversifying the production using a plurality of image data, there is a concern that the above-mentioned interest improvement effect will not be exhibited well because it becomes difficult for the player to grasp the relationship between the first production and the second production. Is done. Such an inconvenience can be prominent for a player who has little knowledge about the specifications of the gaming machine.

  In this regard, as shown in this feature, a predetermined second effect among a plurality of types of second effects is displayed in the second effect image displayed in the second effect and the first effect being executed. If the player is configured to recognize that the first production images are in a series, the relationship between the two productions can be easily understood by the player. Thereby, the interest improvement effect mentioned above can be exhibited suitably.

  The technical ideas shown in the features B2 to B11 can be applied to this feature.

  The basic configuration of the gaming machine to which the above features can be applied is shown below.

  Pachinko gaming machine: operation means (game ball launching handle 45) operated by the player, game ball launching means (game ball launching mechanism 110) for launching a game ball based on the operation of the operation means, and the fired A ball path (guidance rail 100) for guiding a game ball to a predetermined game area (game area PE) and game parts arranged in the game area, and a predetermined passing portion (general winning prize) among these game parts A gaming machine that gives a privilege to a player when a game ball passes through the mouth 81 or the like.

  Slot machine, etc .: A variable display means that displays a symbol sequence consisting of a plurality of symbols in a variable manner and then stops and displays the symbol sequence. Special game advantageous to the player on the condition that the change of the symbol is stopped due to the operation of the operation means for stoppage or when a predetermined time elapses and the final stop symbol at the time of stoppage is a specific symbol A gaming machine that generates a state (bonus game, etc.).

  Ball-use belt-type game machine: Equipped with variable display means that displays the symbol sequence consisting of multiple symbols in a variably displayed state, and then stops and displays the symbol sequence. The special game state (bonus) that is advantageous to the player on the condition that the change of the symbol is stopped due to the operation of the operating means or when the predetermined time elapses, and the final stop symbol at the time of the stop is a specific symbol A throwing device that performs a throwing process for taking in a game ball from the ball tray and a payout device for paying out the game ball to the ball tray, A gaming machine configured such that the operation of the starting operation means is made effective when a game ball is inserted by.

  DESCRIPTION OF SYMBOLS 10 ... Pachinko machine, 94 ... Symbol display device, 94a ... Display screen, 143 ... Sound lamp control device, 162 ... Main control device, 500 ... Display control device, 510 ... General CPU, 520 ... Display CPU for 2D, 530 ... 3D Display CPU, 540 ... Memory module, 550 ... Work RAM, 554 ... Holding information storage area, 560 ... First VRAM, 570 ... Second VRAM, 571 ... Development buffer, 580 ... VDP.

Claims (1)

Information acquisition means for acquiring special information based on the establishment of a predetermined acquisition condition;
Determination means for determining whether or not the special information acquired by the information acquisition means corresponds to predetermined transition information;
Transition means for shifting to a specific gaming state that is more advantageous to the player than usual, based on the determination result by the determination means being a transition response result that corresponds to the transition information;
A display unit having a display screen;
After performing variable display of a plurality of pictures on the display screen, comprising variable display means for stopping and displaying the pictures in a combination corresponding to the determination result by the determination means,
A game in which a predetermined picture combination corresponding to the transition correspondence result is stopped and displayed on the display screen before the transition to the specific gaming state when the determination result by the determination means is the transition correspondence result. Machine,
First effect means for implementing a first effect as a display effect displayed on the display unit;
Second effect means for performing a second effect as a display effect displayed on the display unit;
Data storage means for storing image data for the first effect relating to the first effect and image data for the second effect relating to the second effect;
The first effect means has means for generating first effect drawing data using the first effect image data read from the data storage means,
The second effect means includes means for generating second effect drawing data using the second effect image data read from the data storage means,
The second effect means displays a predetermined second effect among a plurality of types of second effects as indicated by the second effect image displayed in the second effect and the first effect being performed. There is provided a means for performing so that the player recognizes that the first effect image shown is in a series,
The second effect is reached after reaching a reach state in which the picture stopped and displayed on the display screen constitutes a part of the predetermined picture combination and at least a part of the picture is variably displayed. It is configured to be performed as a production,
The first effect means implements the first effect as a suggestion effect that suggests a second effect that can be executed after the reach state in the same game times when the reach state is reached,
The first effect means sets the first effect image on the display screen to a predetermined display mode on the display screen before entering the reach state, and starts an image in the predetermined display mode until the second effect is started. A gaming machine characterized by maintaining.

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