JP6750281B2 - Amusement machine - Google Patents

Description

The present invention relates to a gaming machine.

As a kind of gaming machine, a pachinko gaming machine, a slot machine, etc. are known. As these game machines, those provided with a display device such as a liquid crystal display device are known. The game machine is equipped with a memory in which image data is stored in advance, and a predetermined image is displayed on the display unit of the display device by using the image data read from the memory. Becomes

In recent years, an attempt has been made to display a more stereoscopic image by using image data defined in three dimensions instead of simply displaying a two-dimensional image. When performing the display, an object that is three-dimensional image data is set in the virtual three-dimensional space, and generated data is generated by projecting the object on a plane from a desired viewpoint. Then, a signal is output to the display device based on the generated data, so that a stereoscopic image is displayed (for example, see Patent Document 1).

JP, 2008-295554, A

Here, in the gaming machine as illustrated above, a configuration capable of suitably performing display control is required, and there is still room for improvement in this respect.

The present invention has been made in view of the above-exemplified circumstances, and an object thereof is to provide a gaming machine capable of suitably performing display control.

In order to solve the above-mentioned problems, the invention according to claim 1 includes an arrangement means for arranging image data of an object which is three-dimensional information in a virtual three-dimensional space, and a viewpoint setting means for setting a viewpoint in the virtual three-dimensional space. , A drawing setting means for projecting image data of the object on a projection plane set based on the viewpoint and generating generation data based on the projection data projected on the projection plane. Storage means for storing the generated data generated,
Display control means for outputting and displaying an image corresponding to the generated data stored in the storage means on the display means;
In a gaming machine equipped with
The arranging means is
A means for arranging, in the virtual three-dimensional space, a partial corresponding object in which a projection target surface that is a part of a surface is a projection target and a non-projection target surface that is a part of a surface is not a projection target;
Means for setting an angle of the partial corresponding object so that the projection target surface is a projection target and the non-projection target surface is not a projection target;
Equipped with
The drawing setting means includes a corresponding use means that enables display of an image corresponding to the projection target surface by using corresponding texture data corresponding to the projection target surface,
The correspondence using means includes a range changing means for changing a range to be applied to the projection target surface in the corresponding texture data according to an angle of the partially corresponding object in the virtual three-dimensional space ,
The partial correspondence object has a structure for displaying a spherical surface as the projection target surface .

According to the present invention, it is possible to preferably perform display control.

It is a front view showing a pachinko machine. It is explanatory drawing for demonstrating the display content on the display surface of (a)-(j) symbol display device. (A), (b) It is explanatory drawing for demonstrating the display content on the display surface of a symbol display device. It is a block diagram which shows the electric constitution of a pachinko machine. It is an explanatory view for explaining the contents of various counters used for win/loss lottery. It is a flow chart which shows timer interruption processing performed in a main control unit. It is a flow chart which shows the normal processing performed in the main control unit. It is a flow chart which shows game time control processing performed with a main control unit. It is a flow chart which shows the fluctuation start processing performed by the main controller. It is a flow chart which shows V interruption processing performed by a display CPU. It is a flowchart which shows the task process performed by a display CPU. It is explanatory drawing for demonstrating the content of (a)-(c) drawing list. 7 is a flowchart showing a drawing process executed by VDP. FIG. 9 is an explanatory diagram for explaining a situation in which drawing data is created in accordance with execution of drawing processing. It is explanatory drawing for demonstrating the drawing data for meters in a meter display production. It is an explanatory view for explaining (a) a frame object, (b) an explanatory view for explaining a meter object, (c) an explanatory view for explaining a meter texture, and (d). ) It is an explanatory view for explaining the frame object and the meter object at the start timing, and (e) is an explanatory view for explaining the frame object and the meter object at the update timing. (A), (b) It is an explanatory view for explaining parallel projection mapping of the texture for the meter in the meter display effect that displays the frame, and (c) Projection for the meter when the texture for the meter is applied by UV mapping. It is an explanatory view for explaining a field. (A) It is explanatory drawing for demonstrating the display mode of the meter when a frame is not displayed, (b) It is explanatory drawing for demonstrating the object for meters, and a blank object, (c), (d) It is explanatory drawing for demonstrating the parallel projection mapping of the texture for meters in the meter display production which does not display a frame. It is a flow chart which shows grasp processing for meter display production performed by a display CPU. It is a flow chart which shows various data grasp processing for meter display production performed by a display CPU. It is a flowchart which shows the setting process of the object for meters performed by VDP. It is a flow chart which shows various object setting processing for meter display production performed by VDP. It is a flowchart which shows the application process of the texture for meters performed by VDP. It is explanatory drawing for demonstrating the structure which performs partial display of a meter using a blank object, without reducing an object in another form of (a)-(f) meter display production. (A) It is explanatory drawing for demonstrating the drawing data for spheres when a viewpoint is set above the sphere of a display target in a sphere display production, and (b) a viewpoint is set to the side of the sphere of a display target. It is an explanatory view for explaining drawing data for a sphere in the case of being. (A) It is a perspective view of a simplified version object, (b) is an explanatory view for explaining the 1st vertex and the 1st center, and (c) is an explanatory view for explaining the 2nd vertex and the 2nd center. Yes, (d) is an explanatory diagram for explaining the positional relationship of the vertices that form the simplified version object, (e) is a side view of the simplified version object, and (f) is a perspective view of the hemispherical object. (A) It is a front view of a simplified version object, and (b) is an explanatory view for explaining the relationship between the simplified version object and the screen area. (A) It is explanatory drawing for demonstrating the positional relationship of the simplified version object and a screen area|region at start timing, (b) Corresponding range of the sphere display texture applied to the projection data of the simplified version object at start timing. FIG. 6C is an explanatory diagram for explaining the positional relationship between the simplified version object and the screen area at the update timing, and FIG. 7D is a projection data of the simplified version object at the update timing. It is explanatory drawing for demonstrating the corresponding range of the applied sphere display texture. It is a flow chart which shows the calculation processing for sphere display production performed by the display CPU. (A) It is a flowchart which shows the setting process of the simplified version object performed by VDP, (b) It is a flowchart which shows the application process of the texture for sphere display performed by VDP. (A) It is explanatory drawing for demonstrating the drawing data for clouds in cloud display production, (b) It is explanatory drawing for demonstrating the object for cloud display, (c) Explaining the projection data of the object for cloud display FIG. 6 is an explanatory diagram for explaining the above, (d) is an explanatory diagram for explaining a cloud display texture, and (e) is an explanatory diagram for explaining two-dimensional data for cloud display. (A) It is explanatory drawing for demonstrating the object for clipping, (b) It is explanatory drawing for demonstrating the projection data of the object for clipping, (c) Explanation for demonstrating the two-dimensional data for frame display. It is a figure, (d) is an explanatory view for explaining a blur range, and (e) is a blur range table for setting a blur range. (A) It is explanatory drawing for demonstrating the arrangement|sequence of the dot which comprises two-dimensional data for frame display, (b), (c) is explanatory drawing for demonstrating a vertical scanning process, (d), (d). e) It is explanatory drawing for demonstrating a horizontal scanning process. It is explanatory drawing for demonstrating the method of moving the color information and transparency information set to (a)-(d) blurring range to a movement destination range, (e) 2D data for blurring frame display is demonstrated. It is explanatory drawing for doing. It is a flowchart which shows the calculation process for cloud display effects performed by a display CPU. It is a flow chart which shows grasp processing of various data for cloud display production performed by a display CPU. It is a flow chart which shows creation processing of drawing data for clouds performed by VDP. It is a flow chart which shows creation processing of two-dimensional data for cloud display performed by VDP. It is a flowchart which shows the projection process of the object for clipping performed by VDP. It is a flowchart which shows the clipping process performed by VDP. 7 is a flowchart showing a vertical scanning process executed by VDP. 7 is a flowchart showing a horizontal scan process executed by VDP. It is a flowchart which shows the range setting process performed by VDP. 9 is a flowchart showing a moving process of color information and the like executed by VDP. (A) It is explanatory drawing for demonstrating the character drawing data in an aura display production|presentation, (b) It is explanatory drawing for demonstrating the character drawing data for an aura. It is an explanatory view for explaining (a) a head object, (b) an explanatory view for explaining head projection data, and (c) an explanatory view for explaining a head aura object. FIG. 4D is an explanatory diagram for explaining the head projection data for the aura, FIG. 6E is an explanatory diagram for explaining two-dimensional data for the head aura, and FIG. It is an explanatory view for explaining two-dimensional data. It is explanatory drawing for demonstrating the two-dimensional data for parts with an aura in each part of (a)-(f) character. It is a flow chart which shows the calculation processing for aura display productions performed by a display CPU. It is a flow chart which shows grasp processing of various data for aura display production performed by display CPU. 8 is a flowchart showing a process of creating drawing data for an aura-added character executed by VDP. It is a block diagram which shows the electric constitution which concerns on the display control apparatus in 2nd Embodiment. It is an explanatory view for explaining V interruption processing performed by a display CPU. It is explanatory drawing for demonstrating the content of (a)-(c) drawing list. 7 is a flowchart showing a drawing process executed by VDP. It is a flowchart which shows the task process performed by a display CPU. (A) It is explanatory drawing for demonstrating the display mode of the character and outline which exist in an atmosphere area|region in outline display production, and (b) is explanatory drawing for demonstrating the display mode of the character which exists in a water area, (C) It is explanatory drawing for demonstrating the display mode of the character and outline which exist over an atmospheric area and a water area. It is an explanatory view for explaining (a) character sprite data, (b) an explanatory view for explaining an outline display field, and (c) an explanatory view for explaining a unit area of a frame field. FIG. 11D is an explanatory diagram for explaining a pixel of (d) sprite data. (A) It is explanatory drawing for demonstrating the positional relationship of a normal coordinate and special coordinates in a frame area|region, (b) For demonstrating the positional relationship in the frame area|region of the 1st head area-the 4th head area. It is explanatory drawing, (c) is explanatory drawing for demonstrating the outline display area of a head, (d) is explanatory drawing for demonstrating the protrusion area of a head, (e), (f) It is explanatory drawing for demonstrating the relationship between the sprite data for characters, and a protrusion area. (A) It is explanatory drawing for demonstrating the area|region for blurring outline display, (b)-(d) It is explanatory drawing for demonstrating the effect of the blurring process, (e) Sprite data for characters, and blurring-out area|region. It is explanatory drawing for demonstrating the relationship with, and (f) is explanatory drawing for demonstrating water image data. It is a flow chart which shows the arithmetic processing for outline display production performed by the display CPU. It is the flowchart which shows the drawing processing for outline display production which is executed with VDP. 9 is a flowchart showing a drawing process of an outline display area executed by VDP.

<First Embodiment>
Hereinafter, an embodiment of a pachinko gaming machine (hereinafter referred to as "pachinko machine"), which is a type of gaming machine, will be described with reference to the drawings. FIG. 1 is a front view of a pachinko machine 10.

As shown in FIG. 1, the pachinko machine 10 has an outer frame 11 forming an outer shell of the pachinko machine 10 and a gaming machine body 12 rotatably attached to the outer frame 11 forward. .. The gaming machine main body 12 includes an inner frame (not shown), a front door frame 14 arranged in front of the inner frame, and a back pack unit (not shown) arranged behind the inner frame.

The inner frame of the gaming machine body 12 is rotatably supported by the outer frame 11 with one of the left and right sides being the support side. A front door frame 14 is rotatably supported by the inner frame, and is rotatable forward with one of the left and right side portions being a support side. A back pack unit is rotatably supported by the inner frame, and is rotatable rearward with one of the left and right side portions being the support side.

The gaming machine main body 12 is provided with a locking device (not shown) at its rotating front end, and has a function of locking the gaming machine main body 12 with respect to the outer frame 11 so that it cannot be opened. In addition, it has a function of locking the front door frame 14 so that it cannot be opened with respect to the inner frame. Each of these locked states is released by performing an unlocking operation on the cylinder lock 17 exposed on the front surface of the pachinko machine 10 using an unlocking key.

A game board 20 is mounted on the inner frame. The game board 20 is formed with a plurality of large and small openings penetrating in the front-rear direction. A general winning opening 21, a variable winning device 22, an upper working opening 23, a lower working opening 24, a through gate 25, a variable display unit 26, a main display portion 33, a accessory display portion 34, etc. are provided in each opening. ing.

When a ball enters the general winning opening 21, the variable winning device 22, the upper working opening 23, and the lower working opening 24, it is detected by a detection sensor (not shown) arranged on the back side of the game board 20, Based on the detection result, a predetermined number of prize balls are paid out. In addition, an outlet 27 is provided at the bottom of the game board 20, and game balls that have not entered various winning openings are discharged from the game area through the outlet 27. Further, on the game board 20, a large number of nails 28 are planted in order to appropriately disperse and adjust the falling direction of the game balls, and various members such as a wind turbine are provided.

Here, the entry ball means that the game ball passes through a predetermined opening, and not only the aspect of being discharged from the game area after passing through the opening, but also discharging from the game area after passing through the opening. The mode which is not performed is also included. However, in the following description, in order to clearly distinguish it from the game ball entering the outlet 27, the game ball enters the variable winning device 22, the upper operating port 23, the lower operating port 24 or the through gate 25. Is also referred to as a prize.

The upper working port 23 and the lower working port 24 are unitized as a working port device and installed on the game board 20. Both the upper working port 23 and the lower working port 24 are open upward. Further, the two working ports 23, 24 are arranged in the vertical direction so that the upper working port 23 faces upward. The lower working port 24 is provided with an electric accessory 24a as a guide piece (support piece) composed of a pair of left and right movable pieces. In the closed state (non-supported state or non-guided state) of the electric accessory 24a, the game ball cannot win the lower working opening 24, and the electric working object 24a is in the open state (supported state or guided state) so that the lower working opening is reached. It is possible to win 24 prizes.

The variable winning device 22 is provided with a big winning opening 22a leading to the back side of the game board 20, and an opening/closing door 22b for opening and closing the big winning opening 22a. The opening/closing door 22b is normally in a closed state where a game ball cannot be won or is difficult to win, and when the game is won in the opening/closing execution mode in the internal lottery, it is switched to a predetermined open state in which the game ball is easily won. It is like this. Here, the open/close execution mode is a mode to be shifted to when the jackpot is won. The opening/closing execution mode will be described in detail later. As an opening mode of the variable winning device 22, the variable winning device 22 is repeatedly opened with a predetermined time (for example, 30 sec) or a predetermined number (for example, 10) of winnings as one round, and a plurality of rounds (for example, 15 rounds) as an upper limit. There is a mode.

The main display portion 33 and the accessory display portion 34 are provided on the lower side of the game area. On the main display portion 33, the variable display of the pattern is performed with the winning of the upper operating opening 23 or the lower operating opening 24 as a trigger, and as a result of the stop of the variable display, the winning of the upper operating opening 23 or the lower operating opening 24 is achieved. The result of the internal lottery performed based on this is clearly displayed. That is, in the pachinko machine 10, the winning of the upper working opening 23 and the winning of the lower working opening 24 are not distinguished in the internal lottery, and the winning is performed based on the winning of the upper working opening 23 or the lower working opening 24. The result of the selected internal lottery is clearly displayed on the main display section 33, which is a common display area. When the result of the internal lottery based on the winning of the upper operation opening 23 or the lower operation opening 24 is the winning result corresponding to the shift to the opening/closing execution mode, the predetermined stop result is displayed on the main display unit 33. After it is displayed and the variable display is stopped, the mode is changed to the open/close execution mode.

The main display unit 33 is composed of a segment display in which a plurality of segment light emitting units are arranged in a predetermined manner, but the present invention is not limited to this, and a liquid crystal display device, an organic EL display device, It may be configured by another type of display device such as a CRT or a dot matrix. In addition, as the pattern that is variably displayed on the main display unit 33, a plurality of types of characters are variably displayed, a plurality of types of symbols are variably displayed, a plurality of types of characters are variably displayed, or a plurality of types are variably displayed. A configuration in which the colors of the seeds are switched and displayed is possible.

On the accessory display unit 34, the variable display of the pattern is performed with the winning of the through gate 25 as a trigger, and the result of the internal lottery performed based on the winning of the through gate 25 is displayed as the stop result of the variable display. It is specified by the display. When the result of the internal lottery based on the winning in the through gate 25 is the winning result corresponding to the transition to the electric role open state, a predetermined stop result is displayed on the accessory display unit 34 and the variable display is displayed. After the power supply is stopped, the state is changed to the electric power release state. In the electric role open state, the electric accessory 24a provided in the lower operation port 24 is opened in a predetermined manner.

The variable display unit 26 is provided with a symbol display device 31 that variably displays a symbol, which is a type of symbol. Further, the variable display unit 26 is provided with a center frame 32 so as to surround the symbol display device 31. The upper portion of the center frame 32 extends forward of the pachinko machine 10. As a result, the game ball is prevented from falling in front of the display surface G of the symbol display device 31, and there is no inconvenience that the visibility of the display surface G is reduced due to the fall of the game ball. ing.

The symbol display device 31 is configured as a liquid crystal display device including a liquid crystal display, and display contents are controlled by a display control device 130 described later. The symbol display device 31 is not limited to the liquid crystal display device, and may be another display device such as a plasma display device, an organic EL display device, or a CRT.

In the symbol display device 31, variable display of symbols is started based on winning in the upper working opening 23 or the lower working opening 24. That is, when the variable display is performed on the main display portion 33, the variable display is performed on the symbol display device 31 accordingly. Then, for example, in the game times in which the game result is a jackpot result, symbols of a predetermined combination are stopped and displayed on the preset effective line in the symbol display device 31.

The display contents of the symbol display device 31 will be described in detail with reference to FIGS. 2 and 3. FIG. 2 is a diagram showing individually the symbols variably displayed on the symbol display device 31, and FIG. 3 is a diagram showing a display surface G of the symbol display device 31.

As shown in FIGS. 2(a) to 2(j), a design, which is a kind of design, is composed of nine types of main designs to which the numbers "1" to "9" are respectively attached and shell-shaped designs. It is composed of sub-patterns. More specifically, the numbers of "1" to "9" are respectively added to nine types of character designs such as octopus to form the main design.

As shown in FIG. 3A, on the display surface G of the symbol display device 31, as a plurality of display areas, three symbol rows SA1, SA2, and SA3 in the upper, middle, and lower rows are set. Each symbol row SA1 to SA3 is configured by arranging a main symbol and a sub symbol in a predetermined order. Specifically, in the upper symbol row SA1, nine types of main symbols “1” to “9” are arranged in descending numerical order, and one sub symbol is arranged between each main symbol. .. In the lower symbol row SA3, nine types of main symbols "1" to "9" are arranged in ascending order of the numbers, and one sub symbol is arranged between each main symbol.

That is, the upper symbol row SA1 and the lower symbol row SA3 are composed of 18 symbols. On the other hand, in the middle symbol row SA2, nine types of main symbols "1" to "9" are arranged in ascending order of numbers, and then between the main symbol "9" and the main symbol "1". The main symbols of "4" are additionally arranged, and one sub-symbol is arranged between these main symbols. That is, only in the middle symbol row SA2, 10 main symbols are arranged and configured by 20 symbols. Then, on the display surface G, the symbols of these symbol columns SA1 to SA3 are variably displayed so as to scroll in a predetermined direction with periodicity.

As shown in FIG. 3B, on the display surface G, three symbols are stopped and displayed for each symbol row, and as a result, a total of 3×3 nine symbols are stopped and displayed. It is like this. Further, five effective lines, that is, a left line L1, a middle line L2, a right line L3, a right downward line L4, and a right upward line L5 are set on the display surface G. Then, the variable display is stopped in the order of the upper symbol row SA1, the lower symbol row SA3, and the middle symbol row SA2, and all symbol rows SA1 are formed in a state in which a combination of symbols having the same numeral on any of the activated lines is formed. When the variable display of ~SA3 is completed, the jackpot moving image is displayed as the occurrence of a normal jackpot result or a 15R probability variation jackpot result described later.

In this pachinko machine 10, the main symbol with an odd number (1, 3, 5, 7, 9) is equivalent to the "specific symbol", and if the 15R probability variation jackpot result occurs, the same specific symbol The combination is stopped. Further, the main symbols with even numbers (2, 4, 6, 8) are equivalent to "non-specific symbols", and when a normal jackpot result occurs, the same non-specific symbol combination is stopped and displayed. It

Further, in the case of an explicit 2R probability variation jackpot result described later, the variable display of all the symbol rows SA1 to SA3 ends in a state where a predetermined symbol combination different from the same symbol combination is formed, and thereafter, An explicit video is displayed.

The mode of variable display of the symbols in the symbol display device 31 is not limited to the above, but is arbitrary, and the number of symbol columns, the direction of variable display of symbols in the symbol column, the number of symbols in each symbol column, etc. Can be changed as appropriate. Further, the picture variably displayed on the picture display device 31 is not limited to the above-mentioned picture, and for example, only numbers may be variably displayed as the picture.

Further, based on the winning of any one of the operation ports 23, 24, the variable display is started on the main display section 33 and the symbol display device 31, and a predetermined stop result is displayed until the variable display is stopped. It is equivalent to one game.

At the upper left portion on the front surface side of the center frame 32, a first display light emitting portion 35 corresponding to the main display portion 33 and the symbol display device 31 is provided. The maximum number of game balls that enter the upper working opening 23 or the lower working opening 24 is reserved up to 4, and the reserved quantity is displayed by turning on the first pending light emitting section 35.

In the upper right portion of the center frame 32, a second holding light emitting unit 36 corresponding to the accessory display unit 34 is provided. The number of times the game ball has passed through the through gate 25 is reserved up to a maximum of four times, and the number of reservations is displayed by turning on the second holding light emitting unit 36. The functions of the respective hold light emitting units 35 and 36 may be configured to be performed by the display in a partial area of the symbol display device 31.

A rail portion 37 is attached to the game board 20, the guide rail is configured by the rail portion 37, and is fired from a game ball firing mechanism 58 (not shown) mounted below the game board 20 in the inner frame. The game ball is guided to the upper part of the game area. The game ball launching mechanism 58 launches a game ball by operating the launch handle 41 provided on the front door frame 14.

A front door frame 14 is provided so as to cover the entire front surface side of the inner frame. As shown in FIG. 1, the front door frame 14 is provided with a window portion 42 that allows the entire game area to be viewed from the front. The window 42 has a substantially elliptical shape, and a window panel (not shown) is fitted therein. Although the window panel is made of glass to be colorless and transparent, the present invention is not limited to this and may be made of synthetic resin to be colorless and transparent.

A light emitting means is provided around the window 42. A display light emitting portion 44 is provided above the window portion 42 as a part of the light emitting means. Further, speaker units 45 are provided on the left and right sides of the display light emitting unit 44 to output a sound effect according to the game state.

Below the window portion 42 of the front door frame 14, an upper bulging portion 46 and a lower bulging portion 47 which bulge toward the front side are vertically arranged side by side. An upper plate 46a that opens upward is provided inside the upper bulging portion 46, and a lower plate 47a that also opens upward is provided inside the lower bulging part 47. The upper plate 46a has a function of temporarily storing the game balls paid out from the payout device 56, which will be described later, and guiding them to the game ball launching mechanism side while aligning them in a line. In addition, the lower plate 47a has a function of storing the game balls that are excessive in the upper plate 46a. The game balls dispensed from the dispensing device 56 mounted on the back pack unit are discharged to the upper plate 46a and the lower plate 47a.

In the area of the upper side bulging portion 46 that faces the front of the pachinko machine 10, a performance operation device 48 including an operation portion that is manually operated by the player is provided. The operation unit of the effect operation device 48 is manually operated by the player in order to make the effect contents on the display surface G of the symbol display device 31 the predetermined effect contents.

A main control device 50, a sound emission control device 60, and a display control device 130 are mounted on the back side of the inner frame. Further, the back pack unit is provided on the back surface of the inner frame as described above, and the back pack unit includes a payout mechanism unit including the payout device 56, a payout control device, a power supply and a firing control device. 57 and 57 are mounted. Hereinafter, the electrical configuration of the pachinko machine 10 will be described.

<Electrical structure of the pachinko machine 10>
FIG. 4 is a block diagram showing the basic electrical configuration of the pachinko machine 10.

<Main controller 50>
The main control device 50 includes a main control board 51 that controls the main game. In the main controller 50, a trace means for leaving a trace of the opening is provided to the substrate box that houses the main control substrate 51 or the like, or a trace structure for leaving the trace of the opening is provided. You can Examples of the trace means are a structure of a joint portion (caulking portion) that requires a plurality of case bodies constituting a substrate box to be inseparably joined together and requires a predetermined portion to be broken during the separation, or an adhesive layer to be peeled off to attach an adhesive layer. It is conceivable that a sealing sticker that leaves a trace that it has been peeled off by being left in the case is attached so as to straddle the boundary between a plurality of case bodies. In addition, as the trace structure, a configuration in which an adhesive is applied to a boundary between a plurality of case bodies forming the substrate box can be considered.

An MPU 52 is mounted on the main control board 51. The MPU 52 includes a ROM 53 that stores various control programs executed by the MPU 52 and fixed value data, and a memory that temporarily stores various data when the control program stored in the ROM 53 is executed. A RAM 54, an interrupt circuit, a timer circuit, a data input/output circuit, various counter circuits as a random number generator, etc. are built in.

As the ROM 53, a storage means (that is, a non-volatile storage means) that can be randomly accessed when reading a control program or fixed value data and does not require external power supply for storage is used. In addition, the configuration in which the control/calculation unit, the ROM 53, and the RAM 54 are integrated into one chip is not essential, and each function may be incorporated as a separate chip, and some functions may be included as separate chips. It may be installed.

The MPU 52 is provided with an input port and an output port, respectively. A power supply and firing control device 57 is connected to the input side of the MPU 52. The power supply and launch control device 57 is connected to, for example, a commercial power supply (external power supply) in a game arcade or the like. Then, based on the external power supplied from the commercial power source, the operating power necessary for each is generated for the main control board 51, and the generated operating power is supplied. Incidentally, the operating power is supplied not only to the main control board 51, but also to other devices such as a payout control device 55 and a display control device 130 described later.

A power failure monitoring board may be provided on the power path between the MPU 52 and the power supply/launch control device 57. In this case, the power failure monitoring board monitors the occurrence of the power failure, and when the occurrence of the power failure is confirmed, the power failure signal is transmitted to the MPU 52, so that the MPU 52 executes the processing for the power failure. It becomes possible to do.

Various sensors (not shown) are connected to the input side of the MPU 52. As a part of the various sensors, there are detection sensors provided in a one-to-one correspondence with the winning portion corresponding to the winning portion such as the general winning opening 21, the variable winning device 22, the upper working opening 23, the lower working opening 24 and the through gate 25. It is included, and the MPU 52 makes a prize determination (ball entry determination) for each ball entry portion. In addition, the MPU 52 executes the jackpot occurrence lottery and the jackpot result type lottery based on the winning of the upper operation mouth 23 and the lower operation mouth 24, and also executes the reach generation lottery for each game time and the determination lottery for the display continuation period.

Here, a configuration for performing various lottery in the MPU 52 will be described.

The MPU 52 uses various counter information at the time of playing a game, and performs jackpot occurrence lottery, setting of display of the main display section 33, setting of symbol display of the symbol display device 31, setting of display of the accessory display section 34, and the like. , Specifically, as shown in FIG. 5, jackpot random number counter C1 used for jackpot occurrence lottery, jackpot type counter C2 used when determining jackpot type such as probability variation jackpot result or normal jackpot result, and a symbol Reach random number counter C3 used for reach generation lottery when the display device 31 fluctuates and deviates, random number initial value counter CINI used for initial value setting of the jackpot random number counter C1, fluctuations in the main display portion 33 and the symbol display device 31 A variation type counter CS that determines the display time is used. Further, the electric accessory opening counter C4 used for the lottery for determining whether or not the electric accessory 24a of the lower operation port 24 is in the electric opening state is used. The counters C1 to C3, CINI, CS, and C4 are provided in the lottery counter area 54a of the main RAM 54.

Each of the counters C1 to C3, CINI, CS, and C4 is a loop counter in which 1 is added to the previous value each time it is updated, and after reaching the maximum value, it returns to 0. Each counter is updated at short time intervals. The information corresponding to the jackpot random number counter C1, the jackpot type counter C2, and the reach random number counter C3 is stored in the reserved ball storage area 54b as the acquired information storage means when a prize is paid to the upper working opening 23 or the lower working opening 24. Is stored.

The reserve ball storage area 54b includes a reserve area RE and an execution area AE. The holding area RE includes a first holding area RE1, a second holding area RE2, a third holding area RE3, and a fourth holding area RE4, and according to the winning history of the upper working opening 23 or the lower working opening 24. Numerical value information of the jackpot random number counter C1, the jackpot type counter C2, and the reach random number counter C3 are stored in any of the holding areas RE1 to RE4 as holding information.

In this case, in the first holding area RE1 to the fourth holding area RE4, when the winnings to the upper working opening 23 or the lower working opening 24 occur successively a plurality of times, the first holding area RE1→the second holding area RE1. Numerical information is stored in time series in the order of RE2→third holding area RE3→fourth holding area RE4. Since the four holding areas RE1 to RE4 are provided in this way, the winning history of the game balls to the upper working opening 23 or the lower working opening 24 can be held and stored up to a maximum of four. Further, the holding area RE is provided with a holding number storage area NA, and in order to specify the number of the holding history of the winning history of the upper working opening 23 or the lower working opening 24 stored in the holding number storage area NA. Information is stored.

Note that the number that can be reserved and stored is not limited to four, and may be any number, and may be another number such as two, three, or five or more, or may be a single number.

The execution area AE is an area for moving each value stored in the first holding area RE1 of the holding area RE when starting the variable display of the main display portion 33, and at the start of one game time. Based on the various numerical information stored in the execution area AE, the determination of win/fail is made.

Each of the above counters will be described in detail.

For details of each counter, the jackpot random number counter C1 is configured to be sequentially incremented by 1 within a range of 0 to 599, for example, and then returned to 0 after reaching the maximum value. 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 regularly updated and is stored in the reserved ball storage area 54b at the timing when the game ball wins the upper working opening 23 or the lower working opening 24.

The value of the random number that is a big hit is stored as a win/loss table in the win/loss table storage area as a win/loss information group storage unit in the ROM 53. As the win/loss table, a win/loss table for the low probability mode and a win/loss table for the high probability mode are set. That is, in the pachinko machine 10, the low-probability mode and the high-probability mode are set as the lottery modes in the win/loss lottery means.

In the gaming state in which the win/loss table for the low-probability mode is referred to in the lottery, the number of random numbers that is a big hit is two. On the other hand, in the gaming state in which the win/loss table for the high-probability mode is referred to in the above-mentioned lottery, the number of random numbers to be a big hit is 20. If the winning probability in the high-probability mode is higher than that in the low-probability mode, the number of random numbers to be won is arbitrary.

The jackpot type counter C2 is configured to be sequentially incremented by 1 within a range of 0 to 29, and after reaching the maximum value, returns to 0. The jackpot type counter C2 is regularly updated and is stored in the reserved ball storage area 54b at the timing when the game ball wins the upper working opening 23 or the lower working opening 24.

In this pachinko machine 10, a plurality of jackpot results are set. These plural jackpot results are (1) a mode of the opening/closing control of the variable winning device 22 in the opening/closing execution mode, (2) a lottery mode in the winning/losing lottery means after the opening/closing execution mode, and (3) a bottom after the opening/closing execution mode. A plurality of jackpot results are set by differentiating three conditions of the support mode in the electric accessory 24a of the operation port 24.

As an aspect of the open/close control of the variable winning device 22 in the open/close execution mode, the high frequency is set so that the frequency of winning the variable winning device 22 from the start to the end of the open/close execution mode is relatively high. A frequency winning mode and a low frequency winning mode are set. Specifically, in the high-frequency winning mode, the special winning opening 22a is opened and closed 15 times (high-frequency use times) from the start to the end of the opening/closing execution mode, and one opening is performed for 30 seconds (high-frequency time). ) Has elapsed or until the number of winnings to the special winning opening 22a reaches 10 (high frequency number). On the other hand, in the low frequency winning mode, the special winning opening 22a is opened and closed twice (the number of times for low frequency use) from the start to the end of the opening and closing execution mode, and one opening is 0.2 sec (low frequency time). Is continued or until the number of winnings to the special winning opening 22a becomes 6 (the number of low-frequency winnings).

In the pachinko machine 10, in the situation where the firing handle 41 is operated by the player, the game ball firing mechanism 58 is drive-controlled so that one game ball is fired toward the game area in 0.6 sec. .. On the other hand, in the low frequency winning mode, as described above, the opening time of one big winning opening 22a is 0.2 sec. That is, in the low frequency winning mode, the opening time of the big winning opening 22a once is shorter than the firing cycle of the game ball. Therefore, in the opening/closing execution mode according to the low frequency winning mode, the winning of the game ball does not substantially occur.

The number of times the special winning opening 22a is opened/closed in the high-frequency winning mode and the low-frequency winning mode, the opening limit time for one opening, and the opening limit number for one opening are different in the high-frequency winning mode from the low-frequency winning mode. The value is not limited to the above value and is arbitrary as long as the frequency of winning the variable winning device 22 from the start to the end of the opening/closing execution mode is high. Specifically, the high-frequency winning mode has a larger number of times of opening and closing than the low-frequency winning mode, and if the opening limit time for one opening is long or the opening limit number for one opening is set to be large. Good.

However, in order to clarify the difference in privilege between the high-frequency winning mode and the low-frequency winning mode, in the opening/closing execution mode of the low-frequency winning mode, the winning of the variable winning device 22 does not substantially occur. It is good to have a configuration. For example, in the high frequency winning mode, the product of the game cycle of the game ball and the opening limit number is set to be shorter than the opening time limit for one opening, while in the low frequency winning mode, the one time opening is performed. The product of the game cycle of the game ball and the release limit number may be set to be longer than the release limit time. Further, even if the interval between the game balls is shot and the opening time of one big winning opening 22a is not the above, in the low frequency winning mode, by setting the latter to be shorter than the former, It is possible to easily realize a configuration in which a winning is not substantially generated in the variable winning device 22.

As the support mode of the lower working port 24 in the electric accessory 24a, when comparing in a situation where the game balls are continuously emitted in a similar manner to the game area, the electric working object 24a in the lower working port 24 is Low frequency support mode (low frequency support state or low frequency guide state) and high frequency support mode (high frequency support state or high frequency guide state) so that the frequency of open state per unit time becomes relatively high or low. And are set.

Specifically, the low frequency support mode and the high frequency support mode have the same probability of winning the electric role open state in the electric role opening lottery using the electric role opening counter C4 (for example, both are 4/5). However, in the high-frequency support mode, the number of times the electric accessory 24a is in the open state when the electric role is released is set to be larger than in the low-frequency support mode, and one more opening is performed. The time is set long. In this case, in the high-frequency support mode, the electric power open state is won, and when the open state of the electric accessory 24a occurs a plurality of times, it is closed from the end of one open state to the start of the next open state. The time is set shorter than the one-time opening time. Furthermore, the high-frequency support mode is shorter than the low-frequency support mode in that the minimum secured time required to perform the next electric accessory release lottery after one electric accessory release lottery is performed is shorter. Is set to be selected.

As described above, in the high-frequency support mode, the probability of winning a prize in the lower working opening 24 is higher than in the low-frequency support mode. In other words, in the low frequency support mode, the probability of winning the upper working opening 23 is higher than in the lower working opening 24, but in the high frequency support mode, the lower working opening 24 is more likely to win than the upper working opening 23. The probability of winning is high. Then, when a prize is given to the lower working opening 24, a predetermined number of game balls are paid out, so in the high frequency support mode, the player plays the game while not reducing the number of balls he/she holds. be able to.

Note that the configuration for increasing the frequency of the high frequency support mode being in the electric role open state per unit time higher than that of the low frequency support mode is not limited to the above, and for example, the electric role open lottery It is also possible to adopt a configuration in which the probability of winning the electric role open state is increased. In addition, a securing time that is secured when the next electric accessory release lottery is performed after one electric accessory release lottery is performed (for example, in the accessory display unit 34 based on the winning of the through gate 25). In the configuration where multiple types of variable display time) are prepared, the high-frequency support mode is set so that a shorter securing time is easier to select or the average securing time is shorter than in the low-frequency support mode. It may have been done. Furthermore, the number of times of opening is increased, the time of opening is increased, and the securing time that is secured when the next electric accessory release lottery is performed after one electric accessory release lottery is performed (that is, , Shortening the one-time variable display time on the accessory display portion 34), shortening the average time of the securing time and increasing the winning probability, any one condition or a condition of any combination is applied. Therefore, the advantage of the high frequency support mode over the low frequency support mode may be increased.

The distribution destination of the game result for the jackpot type counter C2 is stored as a distribution table in a distribution table storage area as distribution information group storage means in the ROM 53. Then, the normal jackpot result, the explicit 2R certainty variation jackpot result, and the 15R certainty variation jackpot result are set as the distribution destinations.

The normal jackpot result is a jackpot result in which the opening/closing execution mode becomes the high-frequency winning mode, and after the opening/closing execution mode ends, the win/loss lottery mode becomes the low-probability mode and the support mode becomes the high-frequency support mode. However, the high frequency support mode shifts to the low frequency support mode when the number of games reaches the end reference number (specifically, 100 times) after the shift. In other words, the normal jackpot result is a jackpot result of shifting the game state to the normal jackpot state (low probability corresponding special game state).

The explicit 2R probability variable jackpot result is a jackpot result in which the opening/closing execution mode becomes the low-frequency winning mode, and after the opening/closing execution mode ends, the winning/winning lottery mode becomes the high-probability mode and the support mode becomes the high-frequency support mode. .. The high-probability mode and the high-frequency support mode are continued until the lottery result in the win/win lottery is a big hit state win and the big hit state is transitioned accordingly. In other words, the explicit 2R certainty variation jackpot result is a jackpot result of shifting the game state to the explicit 2R certainty variation jackpot state (explicit high probability corresponding gaming state).

The 15R probability variable jackpot result is a jackpot result in which the opening/closing execution mode becomes the high-frequency winning mode, and after the opening/closing execution mode ends, the winning/winning lottery mode becomes the high-probability mode and the support mode becomes the high-frequency support mode. The high-probability mode and the high-frequency support mode are continued until the lottery result in the win/win lottery is a big hit state win and the big hit state is transitioned accordingly. In other words, the 15R certainty variation jackpot result is a jackpot result of shifting the gaming state to the 15R certainty variation jackpot state (high probability corresponding special gaming state).

The normal game state in relation to each of the above-mentioned game states means a state in which the winning/winning lottery mode is the low-probability mode and the support mode is the low-frequency support mode.

In the distribution table, among the values of the jackpot type counter C2 of “0 to 29”, “0 to 9” correspond to the normal jackpot result, and “10 to 14” correspond to the explicit 2R certainty variation jackpot result. "15-29" corresponds to the 15R probability variation jackpot result.

As described above, since the explicit 2R probability variation jackpot result is set as the probability variation jackpot result, the manner of the probability variation jackpot result is diversified. That is, when comparing two types of probability variation jackpot results, the degree of advantage to the player is that the 15R probability variation jackpot result is the highest in the high-frequency winning mode in the opening/closing execution mode and the high frequency support mode in the support mode. In the support mode, which is the low-frequency winning mode, the high-frequency support mode is the high-frequency support mode. As a result, it is possible to suppress the monotony of the game and increase the degree of attention to the game.

As a kind of probability variation jackpot result, the opening/closing execution mode becomes the low frequency winning mode, and after the opening/closing execution mode ends, the winning/winning lottery mode becomes the high-probability mode and the support mode is maintained to the previous mode. The non-explicit 2R certainty variation jackpot result (the result of the non-explicit high probability corresponding game result or the latent probability variation state) may be included. In this case, the probability variation jackpot result is further diversified.

Furthermore, as a kind of the miss result in the win/loss lottery, a special miss result which does not occur in the win/win lottery mode and the support mode after the transition to the opening/closing execution mode of the low frequency winning mode may be included. .. In the configuration in which both the implicit 2R probability variable jackpot result and the special outlying result are set as described above, the opening/closing execution mode shifts to the low frequency winning mode, and the support mode is maintained to the previous mode. It is common to be done, but because the transition mode of the win/loss lottery mode is different, for example, when one of the implicit 2R certainty variation jackpot result or the special outlier result occurs in the normal gaming state, It is possible for the player to predict which result actually corresponds to.

The reach random number counter C3 is configured to be incremented by 1 in the range of 0 to 238, for example, and return to 0 after reaching the maximum value. The reach random number counter C3 is regularly updated and is stored in the reserved ball storage area 54b at the timing when the game ball wins the upper working opening 23 or the lower working opening 24.

Here, in the pachinko machine 10, an expected effect is set as a kind of display effect in the symbol display device 31. The expected effect is provided with a symbol display device 31 capable of performing variable display of symbols, and in the game times in which the open/close execution mode is the high frequency winning mode, the stop display result after the variable display is the special display result. In, in the stage before the variable display of the symbols on the symbol display device 31 is started and before the stop display result is derived and displayed, the display state for making the player think that the variable display state is likely to be the special display result is displayed. Say.

Two types of expected effects are set: the reach display and a notice display for expecting the reach display or the special display result in a stage before the reach display occurs.

In the reach display, the symbols are stopped and displayed for a part of the plurality of symbol columns displayed on the display surface G of the symbol display device 31, so that a combination of the jackpot symbols corresponding to the occurrence of the high-frequency winning mode. A combination of reach symbols that may be established is displayed, and in that state, a display state in which the symbols are variably displayed in the remaining symbol columns is included. Further, in the state where the reach symbol combination is displayed as described above, the reach display is performed by displaying the variable symbols in the remaining symbol columns and displaying a predetermined character or the like as a moving image in the background image. , A combination of reach patterns is reduced or hidden, and a predetermined character or the like is displayed as a moving image on substantially the entire display surface G to provide a reach effect.

Regarding the reach display related to the variable display of the symbols, specifically, as a step before ending the variable display of the symbols, on the preset effective line in the display surface of the symbol display device 31, the occurrence of the high frequency winning mode is generated. A reach line is formed by stopping and displaying the reach symbol combination in which the corresponding jackpot pattern combination may be established, and the variable display of the symbol is displayed by the final stop symbol row in the situation where the reach line is formed. Is to do.

Explaining the display contents of FIG. 3 in detail, first, the variable display of symbols is finished in the upper symbol row SA1, and the variable display of symbols is finished in the lower symbol row SA3. Reach lines are formed by stopping and displaying the main symbols with the same numbers on the lines L1 to L5, and in the situation where the reach lines are formed, the variable display of symbols is displayed in the middle symbol row SA2. Reach display will be given. Then, when the high-frequency winning mode occurs, the main symbol having the same number as the main symbol forming the reach line is stopped and displayed on the reach line, and in the symbol row SA2 in the middle row. The variable display of symbols is ended.

In the notice display, in a situation where the symbols are variably displayed in all the symbol columns SA1 to SA3 after the variable display of the symbols is started on the display surface G of the symbol display device 31, or in some symbol columns. In a situation in which the symbols are variably displayed in a plurality of symbol columns, a mode in which a character is displayed separately from the symbols on the symbol columns SA1 to SA3 is included. Further, a background image having a predetermined mode different from the previous modes, and a pattern on the symbol arrays SA1 to SA3 having a predetermined mode different from the previous modes are also included. Such advance notice display may occur at both game times when the reach display is performed and when the reach display is not performed, but the reach display is higher than the case where the reach display is not performed. It is set to occur with a probability.

The reach display is executed irrespective of the value of the reach random number counter C3 in the game time of shifting to the open/close execution mode which is the high frequency winning mode, and the reach random number in the game time of shifting to the open/close execution mode of the low frequency winning mode. It is not executed regardless of the value of the counter C3. Further, in the game times that do not shift to the open/close execution mode, the reach random number counter C3 acquired at a predetermined timing corresponds to the occurrence of the reach display by referring to the reach table stored in the reach table storage area of the ROM 53. Is executed if On the other hand, the decision as to whether or not to display the advance notice is made in the sound emission control device 60, not in the main control device 50.

The variation type counter CS is configured to be incremented by 1 in order within the range of 0 to 198, for example, and return to 0 after reaching the maximum value. The fluctuation type counter CS is used when the MPU 52 determines the fluctuation display time on the main display portion 33 and the fluctuation display time of the symbol on the symbol display device 31. The fluctuation type counter CS is updated once every time a normal process described later is executed once, and is repeatedly updated within the remaining time in the normal process. Then, the value of the fluctuation type counter CS is acquired when the fluctuation pattern is determined at the start of fluctuation display on the main display portion 33 and at the start of fluctuation of the symbol by the symbol display device 31. When determining the variable display time, the variable display time table stored in advance in the variable display time table storage area of the ROM 53 is referred to.

The electric accessory release counter C4 is configured to be incremented by 1 in the range of 0 to 250, for example, and then return to 0 after reaching the maximum value. The electric accessory release counter C4 is regularly updated and is stored in the electric accessory holding area 54c at the timing when the game ball wins the through gate 25. Then, at a predetermined timing, a lottery is performed on whether or not the electric accessory 24a is controlled to be in the open state based on the stored value of the electric accessory release counter C4.

On the output side of the MPU 52, the payout control device 55 is connected, and the power supply and firing control device 57 is connected. To the payout control device 55, for example, a prize ball command is transmitted based on the result of the prize determination to the prize-corresponding ball portion. The payout control device 55 causes the payout device 56 to perform payout control of prize balls and loan balls based on the prize ball command received from the main control device 50. A firing permission command is transmitted to the power supply and firing control device 57 based on the operation of the firing handle 41. The power supply and launch controller 57 drives the game ball launching mechanism 58 to launch the game ball toward the game area based on the launch permission command received from the main controller 50.

Further, the main display unit 33 and the accessory display unit 34 are connected to the output side of the MPU 52, and the display control of the main display unit 33 and the accessory display unit 34 is directly performed by the MPU 52. That is, the display control of the main display unit 33 is executed in the MPU 52 at each game time. Further, in the case of clearly indicating the lottery result of whether or not to open the electric accessory 24a, the display control of the accessory display unit 34 is executed in the MPU 52.

Further, the output side of the MPU 52 is connected to a variable winning a prize driving unit that opens and closes the opening and closing door 22b of the variable winning device 22 and an electric auditors product driving unit that opens and closes the electric auditors product 24a of the lower working port 24. .. That is, in the open/close execution mode, the MPU 52 executes the drive control of the variable winning drive unit so that the special winning opening 22a is opened and closed. When the electric accessory 24a is in the open state, the MPU 52 performs drive control of the electric accessory driving unit so that the electric accessory 24a is opened and closed.

Further, an audio emission control device 60 is connected to the output side of the MPU 52, and various production commands are transmitted to the audio emission control device 60.

<Processing executed by MPU 52 of main controller 50>
Next, the processing executed by the MPU 52 will be described.

The MPU 52 repeatedly executes a predetermined game progressing process after the power is turned on. In the pachinko machine 10, as the game progress processing, a normal processing repeatedly executed in the first cycle, and a second cycle shorter than the first cycle are started, and the normal processing is interrupted and executed. Timer interrupt processing is set.

FIG. 6 is a flowchart showing the timer interrupt processing. It should be noted that this processing is activated by the MPU 52 periodically (for example, in a cycle of 2 msec).

First, in step S101, a reading process is executed. In the reading process, the states of the various winning detection sensors are read, the states of these various winning detection sensors are determined, and the processing of saving the winning detection information is executed. When the winning detection sensor corresponding to the generation of the winning ball has detected the winning of the game ball, a winning ball command for instructing the payout controller 55 to pay out the winning ball is set.

In a succeeding step S102, the random number initial value counter CINI is updated. Specifically, the random number initial value counter CINI is incremented by 1, and when the counter value reaches the maximum value, it is cleared to 0.

In a succeeding step S103, 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 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 when they reach their maximum values, they are cleared to 0.

In a succeeding step S104, a through winning process associated with winning in the through gate 25 is executed. In the through winning process, the value of the electric accessory release counter C4 updated in the step S103 is changed to the electric role, provided that the number of the accessory holding storages stored in the electric role holding area 54c is less than 4. It is stored in the holding area 54c.

After that, in step S105, the winning process for the working openings associated with the winning of the working openings 23, 24 is executed. In the winning process for the working opening, if a winning has occurred in the upper working opening 23 or the lower working opening 24, the number of starting pending memories stored in the reserved ball storage area 54b is the upper limit number (for example, " 4”), the numerical information of the jackpot random number counter C1, the jackpot type counter C2, and the reach random number counter C3 updated in step S103 is stored in the holding area RE of the holding ball storage area 54b. .. In this case, it is stored in the first holding area among the empty holding areas RE1 to RE4 of the holding area RE, that is, in the holding area corresponding to the current number of starting holding storages. After executing the processing of step S105, the timer interrupt processing is ended.

FIG. 7 is a flowchart showing normal processing. The normal process is a process that is started after the main process that is started when the power is turned on is executed. As its outline, the processing of steps S201 to S209 is executed as a processing of a cycle of 4 msec, and the counter updating processing of steps S210 and S211 is executed in the remaining time.

In step S201, output data such as the 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/absence of a prize ball command is determined, and if the prize ball command is set, it is transmitted to the payout control device 55. If a predetermined effect command is set, it is transmitted to the sound emission control device 60.

In a succeeding step S202, the fluctuation type counter CS is updated. Specifically, the fluctuation type counter CS is incremented by 1, and the counter value is cleared to 0 when the counter value reaches the maximum value.

In a succeeding step S203, a game time control process for controlling a game in each game time is executed. In this game time control processing, jackpot determination, setting of variable display of symbols by the symbol display device 31, display control of the main display unit 33, and the like are performed.

Then, in step S204, a game state transition process for shifting the game state is executed. In the game state transition processing, when the game times corresponding to the jackpot winning are finished, the transition processing to the open/close execution mode is executed, and the open/close processing of the variable winning device 22 is started. It should be noted that various commands for the opening/closing execution mode are transmitted to the sound emission control device 60 when the opening/closing execution mode is started, during the opening/closing execution mode, and when the opening/closing execution mode is ended. Further, when the opening/closing execution mode ends, the shift of the win/loss lottery mode or the shift of the support mode is executed in correspondence with the jackpot type related to the game time that triggered the start of the mode.

In the following step S205, a demo display process is executed. In the process for displaying a demo, a predetermined start waiting period (for example, 0.1 sec) for starting a demo elapses without starting a new game time after the game time ends in a situation where the open/close execution mode is not set. The determination process of whether or not it is performed is executed. In addition, since the power supply to the MPU 52 is started or the pachinko machine 10 is reset, a predetermined start waiting period (for example, 3 seconds) for starting the demo is elapsed without the game time being newly started. The determination process of whether or not it is performed is executed. Then, if it is determined that the time has elapsed, a command for demonstration display is transmitted to the sound emission control device 60.

The demo display means a start waiting effect displayed on the display surface G of the symbol display device 31 when a predetermined start waiting period has elapsed. In the demo image, an image in which the symbols stopped and displayed on the symbol columns SA1 to SA3 are performing a predetermined operation is displayed, but the image is not limited to this. For example, the symbol performs a predetermined operation. After the image is displayed, or instead of it, a maker name, a model name, or a moving image of a predetermined character may be displayed. Further, in the configuration in which the demo display is performed by the animation of the symbols that are variably displayed on the symbol columns SA1 to SA3, the symbol that is finally stopped and displayed in the last game may be used as the symbol. In this case, the demo display can be diversified.

In a succeeding step S206, an electric power combination support process for driving and controlling the electric accessory 24a provided in the lower operation port 24 is executed. In this electric power support processing, it is determined whether to open the electric accessory 24a using the information stored in the electric power reserve area 54c of the RAM 54, the opening/closing process of the electric accessory 24a, and the accessory use. The display of the display unit 34 is controlled.

Then, in step S207, a game ball launch control process is executed. In the game ball launch control process, the solenoid of the game ball launch mechanism 58 is excited once in a predetermined period (for example, 0.6 sec) on condition that a launch permission signal is input from the power supply and the launch control device 57. .. As a result, the game ball is launched toward the game area.

In a succeeding step S208, it is determined whether or not the power interruption flag is stored in the RAM 54. The power failure flag is a flag that is stored when the occurrence of power failure is confirmed, and is erased in the next main process.

If the power interruption flag is not stored, it means that the last process of the plurality of processes to be repeatedly executed has ended, and therefore, in step S209, it is determined whether or not the execution timing of the next normal process is reached, that is, It is determined whether or not a predetermined time (4 msec in the present embodiment) has elapsed from the start of the normal processing. Then, the random number initial value counter CINI and the variation type counter CS are repeatedly updated within the remaining time until the execution timing of the next normal process.

That is, in step S210, the random number initial value counter CINI is updated. Specifically, the random number initial value counter CINI is incremented by 1, and when the counter value reaches the maximum value, it is cleared to 0. Further, in step S211, the variation type counter CS is updated. Specifically, the fluctuation type counter CS is incremented by 1, and when the counter values reach the maximum value, they are cleared to 0.

Here, since the execution time of each processing of steps S201 to S207 changes according to the state of the game, the remaining time until the execution timing of the next normal processing is not constant but fluctuates. Therefore, the random number initial value counter CINI (that is, the initial value of the jackpot random number counter C1) can be updated at random by repeatedly updating the random number initial value counter CINI using the remaining time. The fluctuation type counter CS can also be updated at random.

On the other hand, if it is determined in step S208 that the power failure flag is stored, it means that power shutoff has occurred, and therefore, the processing at the time of power failure after step S212 is executed. That is, in step S212, the generation of the timer interrupt process is prohibited, after that, the RAM determination value is calculated and stored in step S213, the access to the RAM 54 is prohibited in step S214, and then the power is completely cut off to perform the processing. Continue infinite loop until can no longer be executed.

Next, the game number control process of step S203 will be described with reference to the flowchart of FIG.

In the game time control process, first, in step S301, it is determined whether or not the opening/closing execution mode is in effect. If it is in the opening/closing execution mode, the present game number control processing is ended without executing the processing of step S302 and thereafter. That is, in the open/close execution mode, the game game is not started regardless of whether or not a prize has been paid to the operating ports 23, 24.

If it is not in the open/close execution mode, it is determined in step S302 whether or not the main display unit 33 is in the variable display. If the main display portion 33 is not in the variable display, the process proceeds to the game number starting process of steps S303 to S305.

In the process for starting game play, first, in step S303, it is determined whether or not the number N of balls to be reserved for starting is "0". The case where the number N of starting reserved balls is "0" means that the reserved information is not stored in the reserved ball storage area 54b. Therefore, this game time control processing is ended as it is.

If the number N of starting reserved balls is not "0", a data setting process for setting the data stored in the reserved area RE of the reserved ball storage area 54b for variable display is executed in step S304. Specifically, the data stored in the first holding area RE1 of the holding area RE is shifted to the execution area AE. After that, the data stored in the first holding area RE1 to the fourth holding area RE4 are sequentially shifted to the lower area side. After that, the variation start process is executed in step S305, and then the present game number control process is ended.

The fluctuation start process of step S305 will be described with reference to the flowchart of FIG.

In step S301, a win/loss determination process for determining whether or not the hold information corresponding to the current variation start process corresponds to the jackpot win. Specifically, it is determined whether or not the jackpot is won by referring to the numerical information relating to the jackpot random number counter C1 in the holding information shifted to the execution area AE and the hit/miss table corresponding to the current win/loss lottery mode. To do.

In a succeeding step S302, it is determined whether or not the jackpot is won. If it is a big hit, type determination processing is executed in step S303. In the type determination process, the jackpot type is specified by referring to the numerical information relating to the jackpot type counter C2 among the pending information shifted to the execution area AE and the distribution table.

In a succeeding step S304, a stop result setting process corresponding to the jackpot result is executed. Specifically, in the game time of the variation start of this time, the information of the mode of the pattern to be finally stopped and displayed on the main display unit 33 is specified from the stop result table for the jackpot result stored in advance in the ROM 53, The specified information is stored in the RAM 54. In the jackpot result stop result table, the type of the pattern mode stopped and displayed on the main display unit 33 is set to be different for each type of the jackpot result, and in step S304, it is specified in step S303. The RAM 54 stores information on the form of the pattern according to the type of the jackpot result.

On the other hand, if it is determined in step S302 that the jackpot has not been won, in step S305, a stop result setting process for out-of-range is executed. Specifically, in the game time related to the current fluctuation start, the information of the mode of the pattern to be finally stopped and displayed on the main display unit 33 is specified from the stop result table for disengagement stored in the ROM 53 in advance, The specified information is stored in the RAM 54. The information on the pattern mode selected in this case is different from the information on the pattern mode selected in the case of the jackpot result.

After the process of step S304 or step S305 is executed, the variable display time setting process is executed in step S306.

In this process, the value of the fluctuation type counter CS is acquired. Further, it is determined whether or not the reach display is generated on the symbol display device 31 at the current game time. Specifically, when the number of game times related to the start of fluctuation this time is a big hit result, it is determined that the reach display is generated. Further, even if it is not a jackpot result, if the numerical value information about the reach random number counter C3 stored in the execution area AE is the numerical value information corresponding to the occurrence of the reach, it is determined that the reach display occurs.

When it is determined that the reach display is generated, the reach display variable display time table stored in the ROM 53 is referred to, the variable display time information corresponding to the value of the current change type counter CS is acquired, and the change is obtained. The display time information is set in the variable display time counter provided in the RAM 54. On the other hand, when it is determined that the reach display does not occur, the variable display time information corresponding to the value of the current variation type counter CS is acquired by referring to the reach display table for reach non-occurrence stored in the ROM 53. Then, the variable display time information is set in the variable display time counter. Incidentally, the fluctuation display time that can be acquired by referring to the reach display variable display time table is different from the fluctuation display time that can be acquired by referring to the reach generation fluctuation display time table.

The variable display time information when the reach is not generated is set so that the variable display time becomes shorter as the number of starting pending balls increases. In addition, when the support mode is the high-frequency support mode, the reach non-reach time is selected so that a shorter variable display time is selected than in the case of the low-frequency support mode when the number of hold information is the same. The variable display time table for generation is set. However, the present invention is not limited to this, and a configuration in which the variable display time does not vary according to the number of balls to be held for start-up and the support mode may be adopted, and the above relationship may be reversed. Further, the above configuration may be applied to the variable display time when the reach occurs. Further, the variable display time table may be set individually for each of the various jackpot results, the case of the out-reach, and the case of the non-reach occurrence.

After the variable display time setting process is executed in step S306, the fluctuation command and the type command are set in step S307. The variation command includes information on the variation display time. Here, as described above, the fluctuation display time acquired by referring to the reach non-occurrence variable display time table is different from the fluctuation display time acquired by referring to the reach occurrence variable display time table. Even if the use command does not include the information about the presence or absence of the reach occurrence, the voice emission control device 60 that is the sub-side control device can identify the presence or absence of the reach occurrence from the information of the variable display time. In this respect, it can be said that the variation command includes information indicating whether or not reach is generated. It should be noted that the variation command may include information directly indicating whether or not the reach has occurred.

Further, the type command includes information on the game result. That is, the type command includes, as the game result information, any one of the information of the normal jackpot result, the information of the explicit 2R certainty variation jackpot result, the information of the 15R certainty variation jackpot result, and the out-of-range result.

The variation command and the type command set in step S307 are transmitted to the sound emission control device 60 in step S201 in the normal process (FIG. 7). After executing the process of step S307, variable display of the pattern is started on the main display unit 33 in step S308. Then, this fluctuation start process is terminated.

Returning to the explanation of the game time control process (FIG. 8 ), when the main display section 33 is in the variable display, the processes of steps S306 to S309 are executed. In the process, first, in step S306, it is determined whether or not the variation display time of the current game time has elapsed.

If the variable display time has not elapsed, the variable display process is executed in step S307. In the variable display process, the display mode on the main display unit 33 is changed. Then, this game time control processing is ended.

If the variation display time has elapsed, variation end processing is executed in step S308. In the fluctuation ending process, the information stored in the RAM 54 in the process of step S304 or step S305 is specified, and the main display unit 33 is displayed so that the pattern mode corresponding to the information is displayed on the main display unit 33. Display control.

In a succeeding step S309, a fluctuation end command is set. The fluctuation end command set here is transmitted to the sound emission control device 60 in step S201 in the normal process (FIG. 7). The sound emission control device 60 ends the effect in the game time, based on the received variation end command. Further, a command corresponding thereto is transmitted from the voice emission control device 60 to the display control device 130, and the display control device 130 finalizes and displays the final stop symbol combination in the game time (final stop display). Then, this game time control processing is ended.

<Voice emission control device 60>
Next, the sound emission control device 60 will be described.

The sound emission control device 60, as shown in FIG. 4, includes a sound emission control board 61 on which an MPU 62 is mounted. The MPU 62 includes a ROM 63 that stores various control programs executed by the MPU 62 and fixed value data, and a memory that temporarily stores various data when the control program stored in the ROM 63 is executed. A RAM 64, an interrupt circuit, a timer circuit, a data input/output circuit, various counter circuits as a random number generator, etc. are built in.

As the ROM 63, a storage means (that is, a non-volatile storage means) that can be randomly accessed when reading a control program or fixed value data and that does not require external power supply for storage is used. Further, the configuration in which the control/calculation unit, the ROM 63, and the RAM 64 are integrated into one chip is not indispensable, and each function may be mounted as a separate chip. It may be installed.

The MPU 62 is provided with an input port and an output port, respectively. The operation device 48 for production and the main control device 50 are connected to the input side of the MPU 62, and the various light emitting parts 35, 36, 44, the speaker part 45 and the display control device 130 are connected to the output side of the MPU 62. There is.

The MPU 62 recognizes that it is necessary to start the game use effect by receiving the variation command transmitted from the main control device 50, and executes the game use effect start process. In addition, by receiving the end command transmitted from the main control device 50, it recognizes that it is necessary to end the game use effect, and executes the game use effect ending process. Further, by receiving various commands for the jackpot effect transmitted from the main control device 50, it recognizes that the jackpot effect needs to be started or progressed, and the jackpot effect processing is executed. Further, by receiving the command for demo display transmitted from the main controller 50, it recognizes that it is necessary to start the demo display, and executes the demo display process.

Note that receiving a command from the main control device 50 in the MPU 62 is not limited to the configuration in which the command is directly received from the main control device 50, and includes a configuration in which the command relayed to the relay board is received.

In the game time production start process, based on both the command for variation and the command for type, the process of grasping the variable display time for grasping the variable display time of the corresponding game time, and the reach display grasping process for grasping the presence or absence of the reach display And a jackpot result occurrence grasping process for grasping the presence or absence of the jackpot result, and a jackpot type grasping process for grasping the jackpot type when the jackpot result occurs. Also, based on the grasp result in the reach display grasping process, the jackpot result occurrence grasping process, and the jackpot type grasping process, a symbol for determining the type of the symbol to be finally stopped and displayed on the display surface G of the symbol display device 31 in this game time. Execute the type recognition process. Then, based on the result of each grasping process, 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, the display control device. To 130.

In addition, in the game reproduction effect start process, in addition to the above-described grasping processes, a notice display lottery process of whether or not to perform a notice display is executed. In this case, in the lottery process, the type of lottery for the notice display is also executed. Then, if the advance notice display has been generated, the advance notice command including the information about the type of the advance notice display is transmitted to the display control device 130.

Further, in the game round effect starting process, the display light emitting table for game round and the voice table for game round are read from the ROM 63 based on the processing result of each of the above processes. The display light emission table for game times defines the light emission mode of the display light emitting unit 44 in the course of progress of the corresponding game time. In addition, the voice table for game times defines the output mode from the speaker unit 45 in the progress process of the corresponding game times.

In the game game effect ending process, the light emission control of the display light emitting unit 44 and the voice output control of the speaker unit 45 in the current game time are ended. Further, in the game turning effect ending process, an end command including information for ending the game turning effect is transmitted to the display control device 130.

In the jackpot performance process, based on various received jackpot performance commands, it grasps the production mode at the time of opening, each round, between each round, and ending, etc. Is transmitted to the display control device 130. Further, based on the grasped result, the display light emission table for the big hit effect and the sound table for the big hit effect are read out from the ROM 63, and the light emitting mode of the display light emitting unit 44 and the sound output mode from the speaker unit 45 during the big hit effect. Stipulate.

In the demo display process, the presentation mode of the demo display is grasped based on the received demo display command, and the demo display command corresponding to the grasped result is transmitted to the display control device 130. Further, based on the grasped result, the display light emission table for the demo display and the voice table for the demo display are read from the ROM 63, and the light emission mode of the display light emission unit 44 and the voice output mode from the speaker unit 45 during the demo display. Stipulate.

The process executed by the MPU 62 based on the command transmitted from the main control device 50 is not limited to the above process, but includes a process for controlling the light emission of the first holding light emitting unit 35 and the second holding light emitting unit 36. included.

Further, the MPU 62 recognizes that the effect operation device 48 has been operated by receiving an operation signal transmitted from the effect operation device 48 based on the operation unit of the effect operation device 48 being operated. Then, the operation corresponding process is executed. Further, even when the operated state is released, it is recognized by the fall of the operation signal and the operation handling process is executed.

Here, as a part of the effect corresponding to the operation of the effect operation device 48, an effect in which the display mode is changed is executed based on the operation of the effect operation device 48. The display mode is a state in which the type of the standby image displayed until the game time is started and the type of the game time image displayed when the game time is being executed are set to a predetermined type, and a plurality of types The display mode of is set. The detailed contents of the display mode and the processing configuration for switching the display mode based on the operation of the effect operation device 48 will be described later in detail.

<Display control device 130>
The hardware configuration of the display control device 130 will be described.

As shown in FIG. 4, the display control device 130 includes a display control board 136 on which a display CPU 131, a work RAM 132, a memory module 133, a VRAM 134, and a video display processor (VDP) 135 are mounted. ..

The display CPU 131 has a function as a main control unit in the display control device 130, and reads, interprets, and executes a control program and the like. More specifically, the display CPU 131 is connected to an input port 137 mounted on the display control board 136 via a bus, and various commands transmitted from the sound emission control device 60 are input to the display CPU 131 via the input port 137. To be done. Note that the reception of a command from the voice emission control device 60 in the display CPU 131 is not limited to the configuration of directly receiving the command from the voice emission control device 60, and includes the configuration of receiving the command relayed to the relay board. Be done.

The display CPU 131 is connected to the work RAM 132, the memory module 133, and the VRAM 134 via a bus, and based on the command received from the voice light emission control device 60, various data stored in the memory module 133 is stored in the work RAM 132 or the VRAM 134. Send a transfer instruction. Further, the display CPU 131 is connected to the VDP 135 via a bus, and based on a command received from the sound emission control device 60, a drawing instruction for causing the symbol display device 31 to display a three-dimensional image (3D image). To do. The memory module 133, the work RAM 132, the VRAM 134 and the VDP 135 will be described below.

The memory module 133 is a storage unit that stores control data including a control program and fixed value data in advance and various image data for displaying a three-dimensional image in advance. The memory module 133 has a non-volatile semiconductor memory that does not require external power supply for storage. Incidentally, although the storage capacity is 4 Gbits, such a storage capacity is arbitrary as long as the control in the display control device 130 is well executed. In addition, the memory module 133 is used as a non-writing and read-only memory (ROM) when the pachinko machine 10 is used.

The various image data stored in the memory module 133 includes image data for objects such as symbols and characters displayed on the symbol display device 31, image data for texture attached to the object, and one frame worth. Image data for the back surface that constitutes the backmost image in the image.

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

The texture is an image attached to each polygon of the object, and by attaching the texture to the object, an image corresponding to the object, for example, a display image including a design, a character, etc. is generated. The method of holding the image data for texture is arbitrary, but for example, it includes at least a combination of bitmap format data and a color palette table that is referred to when determining a display color at each pixel of the bitmap image. There is.

The rearmost image constitutes a two-dimensional image (2D image). The method of holding the image data for the back side 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, when the image data for the back surface is arranged in the world coordinate system, a plate polygon is used.

The work RAM 132 is a storage unit for temporarily storing the control data read from the memory module 133 and transferred, and also temporarily storing a flag and the like. The work RAM 132 has a volatile semiconductor memory that requires external power supply to retain the memory, and in particular, a DRAM is used as the semiconductor memory. However, the RAM is not limited to DRAM, and other RAM such as SRAM may be used. Note that the storage capacity is 1 Gbit, but the storage capacity is arbitrary as long as the control in the display control device 130 is satisfactorily executed. Further, the work RAM 132 is used for both reading and writing when the pachinko machine 10 is used.

Control data is transferred from the memory module 133 to the work RAM 132 based on a data transfer instruction from the display CPU 131 to the memory module 133. Then, the display CPU 131 reads the control data transferred to the work RAM 132 into an internal memory area (register group) as necessary, and executes various processes.

The VRAM 134 is a storage means for temporarily storing various data necessary for outputting an image to the symbol display device 31. The VRAM 134 has a volatile semiconductor memory that requires external power supply to retain the memory, and in detail, an SDRAM is used as the semiconductor memory. However, the RAM is not limited to SDRAM, and other RAM such as DRAM, SRAM, or dual port RAM may be used. It should be noted that the storage capacity is 2 Gbits, but the storage capacity is arbitrary as long as the control in the display control device 130 is satisfactorily executed. Further, the VRAM 134 is used for both reading and writing when using the pachinko machine 10.

The VRAM 134 includes a development buffer 141, and image data is transferred from the memory module 133 to the development buffer 141 based on a data transfer instruction from the display CPU 131 to the memory module 133. In this case, the image data is transferred in advance before the execution timing of the process in the VDP 135 using the image data. Further, the VRAM 134 is provided with a frame buffer 142 in which drawing data (generation data) is created by the VDP 135. Further, the VRAM 134 is provided with a Z buffer 143, a screen buffer 144, and a mode buffer 145, the details of which will be described later.

The VDP 135 is an image generation device that draws on the symbol display device 31 by specifically processing the data stored and held in the expansion buffer 141 based on a drawing instruction from the display CPU 131. It is a kind of drawing circuit that operates the image processing device 31b incorporated to drive and control the liquid crystal display unit 31a in the symbol display device 31. Since the VDP 135 is formed as an IC chip, it is also called a "drawing chip", and the substance thereof should be called a microcomputer chip containing a firmware dedicated to drawing.

More specifically, the VDP 135 includes a geometry calculation unit 151, a rendering unit 152, a register 153, a display mode control unit 154, and a display circuit 155. Further, these circuits are connected to each other via a bus, and are also connected to the I/F 156 for the display CPU 131 and the I/F 157 for the VRAM 134.

The I/F 156 for the display CPU 131 causes the register 153 to store the drawing list as the drawing instruction information transmitted from the display CPU 131. The geometry calculation unit 151 arranges the object designated as the arrangement target in the world coordinate system based on the drawing list stored in the register 153. Further, the geometry calculation unit 151 executes various coordinate conversion processes when and after the object is arranged in the world coordinate system. Then, finally, the object is clipped in correspondence with the three-dimensional space corresponding to the screen coordinates of the display surface G.

The rendering unit 152 adjusts the light source and pastes the texture on each clipped object based on the drawing list stored in the register 153 to determine the appearance of the object. In addition, the rendering unit 152 projects each object onto a predetermined two-dimensional plane to create two-dimensional data, and performs various adjustments based on depth information to perform one-frame drawing data, which is two-dimensional data, in a frame buffer. 142. The drawing data for one frame means the data necessary to display the image at one update timing in the configuration in which the image on the display surface G of the symbol display device 31 is updated at a predetermined update timing. Say.

Note that all the control programs for operating the geometry calculation unit 151 and the rendering unit 152 may be provided by the drawing list. A memory in which the control program is stored in advance is incorporated in the VDP 135, and the control program and the drawing list are included. The geometry calculation unit 151 and the rendering unit 152 may be configured to execute processing depending on the content of the above. Alternatively, the control program may be read in advance from the memory module 133. Further, the geometry calculation unit 151 and the rendering unit 152 may be configured to execute the process only by the operation of the hardware circuit corresponding to the drawing list without using the program.

Here, the frame buffer 142 is provided with a plurality of frame areas 142a and 142b. Specifically, a first frame area 142a and a second frame area 142b are provided. Each of these frame areas 142a and 142b is set to a capacity capable of storing drawing data for one frame. Specifically, each of the frame areas 142a and 142b includes a large number of unit areas corresponding to dots (pixels) of the liquid crystal display section 31a (that is, the display surface G) at a predetermined magnification. Each unit area has a storage capacity capable of storing data for specifying which color is displayed. More specifically, the full color system is adopted, and it is possible to set 256 colors for each of R (red), G (green), and B (blue) in each dot. Correspondingly, 1 byte (8 bits) is assigned to each RGB color in each unit area. That is, each unit area has a storage capacity of at least 3 bytes.

The storage capacity is not limited to the full-color method. For example, in a configuration in which only 256 colors can be displayed in each dot, the storage capacity required to store color information in each unit area may be 1 byte.

Since the frame buffer 142 is provided with the first frame area 142a and the second frame area 142b, in the situation where drawing on the symbol display device 31 is being executed using drawing data created in one frame area. , Drawing data to be used in the future is created for other frame areas. That is, the double buffer method is adopted as the frame buffer 142.

In the display circuit 155, an image signal corresponding to each dot of the liquid crystal display unit 31a is generated based on the drawing data created in the first frame area 142a or the second frame area 142b, and the image signal is displayed in the display circuit 155. It is output to the symbol display device 31 through the connected output port 138. Specifically, the drawing data is transferred from the output target frame areas 142a and 142b to the display circuit 155. The transferred drawing data is resolution-adjusted by a scaler (not shown) so as to correspond to the resolution of the pattern display device 31, and converted into gradation data. Then, an image signal corresponding to each dot of the symbol display device 31 is generated and output based on the gradation data. The display circuit 155 also outputs a synchronizing signal such as a horizontal synchronizing signal or a vertical synchronizing signal.

Further, the display mode control unit 154 executes a predetermined process based on the drawing list stored in the register 153 when displaying an image corresponding to the display mode. The predetermined process will be described later.

<Basic Processing in Display CPU 131>
Next, basic processing in the display CPU 131 will be described.

<Main processing>
First, the main processing that is started when the supply of operating power to the display CPU 131 is started or when the pachinko machine 10 is reset will be described. In the main process, first, the initial setting process is executed.

In the initial setting process, a scaler initial adjustment process of the display circuit 155 is executed. In the initial adjustment processing, when the image signal is output based on the drawing data created in each of the frame areas 142a and 142b of the VRAM 134, the image signal is output corresponding to the number of dots of the liquid crystal display unit 31a. As described above, the resolution initial adjustment command is transmitted to the VDP 135. This initial adjustment value is adjusted at the design stage of the pachinko machine 10, and the adjustment result is set as a resolution initial adjustment command.

By transmitting the resolution initial adjustment command to the VDP 135, numerical information corresponding to the initial adjustment value is stored in the scaler resolution adjustment area in the register 153 of the VDP 135. Accordingly, when the image signal is output from the VDP 135 to the symbol display device 31, the image signal corresponding to the drawing data is output in a state adjusted to the number of dots of the liquid crystal display unit 31a.

Further, in the initial setting process, an initial adjustment process of the background color is executed. In the initial adjustment processing, the ground color initial adjustment command is transmitted to the VDP 135 so that the numerical information set as the initial value in the unit area of each of the frame areas 142a and 142b of the VRAM 134 becomes the initial numerical information. This initial numerical value information is adjusted at the design stage of the pachinko machine 10, and the adjustment result is set as a ground color initial adjustment command.

The VDP 135 stores the initial numerical value information in the area for ground color adjustment in the register 153 of the VDP 135 by transmitting the ground color initial adjustment command. As a result, the background color is displayed at the dots corresponding to the unit areas for which the initial numerical value information was not updated when the drawing data was created. Although black is set as the initial ground color in the pachinko machine 10, it is not limited to this and is arbitrary.

After executing the initial setting process, various interrupts are enabled. This allows the display CPU 131 to execute the command interrupt process and the V interrupt process. Then, in the main process, the process of permitting various interrupts is repeated.

<Command interrupt processing>
Next, the command interrupt process will be described.

The command interruption process is a process that is activated with the highest priority when a strobe signal is received from the sound emission control device 60, whatever the process is being executed at that time. In the command interrupt processing, the command received at the input port 137 is transferred to the command buffer provided in the work RAM 132, and a flag indicating that a command has been newly received is set in the corresponding area. After that, the command interrupt processing is terminated, and the processing before the activation of the command interrupt processing is restored.

<V interrupt processing>
Next, the V interrupt processing will be described with reference to the flowchart of FIG. The V interrupt process is repeatedly activated in a predetermined cycle, specifically, a 20 msec cycle.

When the VDP 135 outputs the image signal for one frame to the symbol display device 31, it starts outputting the image signal from the dot in the upper left corner portion of the display surface G, and on the horizontal line including the dot at one end. The image signal is sequentially output to the aligned dots, and the image signal is sequentially output to the dots from left to right for each horizontal line. Then, the image signal is finally output to the dots in the lower right corner portion of the display surface G. In this case, the VDP 135 outputs a V interrupt signal to the display CPU 131 at the timing of outputting the image signal for the last dot, and causes the display CPU 131 to recognize that the update of the image of one frame is completed. The output cycle of this V interrupt signal is 20 msec. In this respect, the V interrupt processing can be regarded as being activated in synchronization with the reception of the V interrupt signal. However, even if the V interrupt signal is not received, if 20 msec has elapsed since the previous V interrupt process was started, the V interrupt process is newly started.

In the V interrupt process, first, in step S501, a command analysis process is executed. Specifically, the content of the command stored in the command buffer of the work RAM 132 is analyzed. In a succeeding step S502, it is determined whether or not a new command is received, based on the analysis result of the step S501. If a new command has been received, command corresponding processing is executed in step S503.

In the command handling process, the data table for executing the program corresponding to the received command is read from the memory module 133. The data table is defined as the processing required to display an image for one frame at each image update timing when a moving image corresponding to the received command is displayed on the display surface G of the symbol display device 31. It is an information group.

Here, as the commands that the display CPU 131 receives from the sound emission control device 60, there are a fluctuation pattern command, a symbol designating command, and a notice command, as already described. When these commands are received, the data table necessary for executing the game rendition corresponding to each of these commands on the symbol display device 31 is read. Further, as the command to be received, there is an end command, and when the command is received, the data table necessary for finally stopping the currently playing game diversion effect is read. Further, as the command to be received, there are various commands for jackpot performance, and when the command is received, the data table necessary for executing the jackpot performance is read. Further, as the command to be received, there is a command for demo display, and when the command is received, the data table necessary for executing the demo display is read. Further, based on the read data table, other program data necessary for executing the processing is also read.

After executing the command corresponding process in step S503, the pointer updating process is executed in step S504. In the pointer update processing, the pointer information set in the data table is updated so as to advance by one frame. As a result, it becomes possible for the display CPU 131 to understand the processing required to display the image for one frame corresponding to the update timing of this time.

In the following step S505, task processing is executed. In the task processing, in order to display the image for one frame corresponding to the update timing of this time, the parameters necessary for instructing the VDP 135 to draw are calculated. Details of the task processing will be described later.

In a succeeding step S506, a drawing list output process is executed. In the drawing list output process, a drawing list for displaying an image for one frame corresponding to the update timing related to the current processing time is created, and the created drawing list is transmitted to the VDP 135. In this case, in the drawing list, the image grasped in the immediately preceding task process is the drawing target, and the parameter information updated in the task process is also set. The VDP 135 creates drawing data in the frame areas 142a and 142b of the VRAM 134 according to this drawing list. The processing in the VDP 135 will be described in detail later. Then, this V interrupt process is completed.

<Task processing in display CPU 131>
Here, the task processing will be described with reference to the flowchart of FIG.

In the task process, first, in step S601, a control start setting process is executed. In the setting process for control start, a process for setting an individual image for which the control (calculation) is newly started in the display CPU 131 at the current processing time is executed. An individual image is a two-dimensional image defined by still image data such as image data for the back surface, or a three-dimensional image defined by a combination of image data for an object and image data for a texture. It is an image.

Regarding the setting process for control start, specifically, first, based on the currently set data table, it is determined whether or not there is an individual image to be the control start target in this processing time. If it exists, it searches the work RAM 132 for a free buffer area for performing various calculations in controlling the individual image, and makes a one-to-one correspondence with the individual image grasped as the control start target. To secure a free buffer area. Further, the initialization process is executed for all the secured free buffer areas, and the control start parameters are set for the initialized free buffer areas according to the individual image.

In the following step S602, the control update target is grasped. This control update target is an individual image for which the control start processing has been completed and which may be included in one frame of images after the current processing.

In the following step S603, the background arithmetic processing is executed. In the background calculation processing, the coordinates of the background image, which constitutes the background image, and the background character, the rotation angle, the scale, the light information for adding and contrasting the light, and the projection are calculated. A process for calculating and deriving various parameters necessary for creating a drawing list such as camera information for performing and a Z test designation is executed.

In a succeeding step S604, effect calculation processing is executed. In the effect calculation process, a process of calculating and deriving the various parameters described above is performed for individual images to be displayed in various effects such as reach display, notice display, and jackpot effect.

In a succeeding step S605, symbol calculation processing is executed. In the symbol calculation process, a process of calculating and deriving the various parameters described above is executed for the image of the symbol to be displayed in a variable manner in each game.

By the way, in each process of step S603 to step S605, a process of updating the control start parameter set in step S601 is executed. In addition, in each processing of step S603 to step S605, animation data set so as to change various parameters of the individual image according to a specific pattern each time the image update timing comes. This animation data is stored in advance in the memory module 133 and is determined according to the type of individual image.

After that, in step S606, the process of grasping the arrangement target in the world coordinate system is executed, and then this task process is ended. In the grasping process of the arrangement target in the world coordinate system, the process of grasping the individual image to be set as the drawing target in the current drawing list among the individual images that are the control update targets by the processes of steps S603 to S605. To execute. The grasping is performed based on the currently set data table. The individual image grasped here is set as a drawing target in the drawing list.

In other words, the number of individual images to be controlled by the display CPU 131 is set to be larger than the number of individual images to be controlled by the VDP 135, so that adjustment is performed in step S606. However, the present invention is not limited to this, and the individual image to be controlled by the display CPU 131 and the individual image to be controlled by the VDP 135 may be the same. In this case, the process of step S606 is executed. There is no need.

In the setting process for control start in step S601, the control start timing of each individual image may be set in a dispersed manner so as to disperse the processing load of the display CPU 131.

<Basic processing in VDP135>
Next, the basic processing executed by the VDP 135 will be described.

In the VDP 135, a process of setting the value of the register 153 based on the command transmitted from the display CPU 131, a process of creating drawing data in the frame areas 142a and 142b of the frame buffer 142 based on the drawing list transmitted from the display CPU 131, At least a process of outputting an image signal to the symbol display device 31 is executed based on the drawing data created in the frame areas 142a and 142b.

Of the above processes, the process of setting the value of the register 153 is executed each time a command is received by a circuit (not shown) attached to the I/F 156 for the display CPU 131. Further, the process of creating drawing data is repeatedly executed at a predetermined cycle (for example, 20 msec) by the cooperation of the geometry calculation unit 151 and the rendering unit 152. The process of outputting the image signal is executed by the display circuit 155 at a predetermined image signal output start timing.

Hereinafter, the process of creating the drawing data will be described in detail. Prior to the description of the process, the contents of the drawing list transmitted from the display CPU 131 to the VDP 135 will be described. 12A to 12C are explanatory diagrams for explaining the contents of the drawing list.

Header information is set in the drawing list. In the header information, information of the target buffer, which is information indicating which of the first frame area 142a and the second frame area 142b is to be created, is set for the image of one frame related to the drawing list. There is. Further, various designation information is set in the header information. The contents of various designation information will be described later. When moving image data is included as image data handled by the VDP 135, whether or not decoding is designated and moving image data to be decoded in the header information includes information on an address stored in the memory module 133. It may be set.

In the drawing list, in addition to the above header information, a plurality of types of image data to be placed in the world coordinate system at the time of creating the drawing data this time are set, and further information on the drawing order of each image data, The parameter information of each image data is set. Specifically, the drawing order information is set so as to be serially-numbered numerical information, and the parameter information is set in a one-to-one correspondence with each numerical information.

In the drawing list of FIG. 12A, the back image data 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. There is. Further, the image data for effect is set as a sequence after the image data for background, for example, the object A for effect is set as m-th, the object for effect B is set as m+1-th, and so on. There is. Further, as the order after the image data for these effects, the image data for symbols is set, for example, the object A for symbols is set as the nth, the object for symbols B is set as the n+1th, and so on. There is.

Note that the order in which each image data is set in the drawing list is not limited to the above, and the set order may be the reverse of the above. Image data for effect or image data for background may be set after the data, and image data for symbols is set in order between the image data for predetermined effect and the image data for other effects. It may have been done.

Parameter information P(1), P(2), P(3),..., P(m), P(m+1),..., P(n), P(n+1),. Has multiple types of parameters set. Regarding the parameter P(1) of the image data for the back side, specifically, as shown in FIG. 12B, the address information of the area where the image data for the back side is stored in the memory module 133 and the information for the back side Information (X value information, Y value information, Z value information) indicating the position in the world coordinate system when setting the image data of, and the world coordinate system when setting the back image data Angle information that indicates the rotation angle inside, and scale information that indicates the magnification when setting the world coordinate system for the scale that is set as the initial state of the image data for the back side, and the image for the back side Information of a uniform α value indicating the entire transparent information (or transparent information) when setting data is set.

Here, the coordinate information is individually set for all vertices of the image data for the object. Further, the information on the coordinates is set for the image data for the object, but is not set for the image data for the texture. In the image data for texture, the coordinate value of each pixel is predetermined in association with each vertex of the image data for object. This coordinate value is a UV coordinate value different from the coordinate value in the world coordinate system, and is stored in the memory module 133 in a state of being attached to a combination of object image data and texture image data. This UV coordinate value is referred to by the VDP 135 when performing texture mapping. In this way, UV mapping is a mapping performed using a texture existing in a UV coordinate system different from the world coordinate system.

In the parameter (P1), the camera information including the coordinate and orientation information of the virtual camera when the back image data is projected on the virtual two-dimensional plane for rendering, and the back image data are rendered. The information of the light including the information of the position and the direction of the virtual light source that determines the shadow in (4) is set.

In the parameter (P1), Z test designation information indicating whether or not the Z buffer method, which is a kind of hidden surface erasing method, is applied is set. The Z-buffer method is each pixel (or each voxel, each pixel, each polygon) arranged on the Z-axis when many objects and two-dimensional images are overlapped in the depth direction (Z-axis direction) in the world coordinate system. Is sequentially referred to the distance from the viewpoint, and the numerical value information set to the pixel closest to the viewpoint is set to the corresponding unit area in the frame areas 142a and 142b. When applying the Z buffer method, the Z buffer 143 provided in the VRAM 134 is used.

In addition to the Z-buffer method, a 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, for each pixel arranged on the Z axis, the numerical information set for each pixel is sequentially set in the corresponding unit area in the frame regions 142a and 142b. When the Z sort method is applied, the α value set for each pixel is referred to, and the corresponding α value is applied to the numerical information corresponding to the color information of each pixel arranged on the Z axis. In this state, the addition processing of these numerical information and the calculation processing for fusion are executed. The description of the specific processing configuration of the hidden surface processing by Z sort is omitted, but it is activated when the effect image is displayed.

The parameter (P1) includes α data designation information indicating whether or not α data is applied and an application target, fog designation information indicating whether fog is applied or not, and a background created to display a background image. The information of the separate save designation indicating whether or not the image drawing data is separately saved 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 the α data. The uniform α value is transparency information applied to all pixels of one image data, and is numerical information derived as a calculation result in the display CPU 131. The uniform α value is uniformly applied to all pixels of the image data. On the other hand, the α data is transparency information applied to each pixel of two-dimensional still image data and texture image data, and is stored in the memory module 133 in advance as image data. The α data can have different transparency information for each pixel within the range of the same still image data or the same image data for texture. This α data has a larger data capacity than the program data for setting a uniform α value.

By uniformly setting the α value and the α data as described above, the transparency of the two-dimensional still image data or the image data for texture is not controlled finely in pixel units, but is uniform for all pixels. In the situation where it is only necessary to control with, it is possible to reduce the required data capacity by being able to deal with a uniform α value, and it is also possible to finely control the transparency in pixel units by applying α data.

The fog is information for adjusting the degree of brightness with respect to a position in a predetermined direction in the world coordinate system, specifically, the Z-axis direction. Fog is used to represent fog and the inside of 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 fixed manner. Alternatively, a plurality of fogs may be applied to the entire image for one frame. In this case, if the same fog as other objects is applied to the object arranged on the back side in the Z-axis direction, a different fog is set for the object in a situation in which the texture is not obtained due to being too dark. It is good to have a configuration. As a result, it is possible to obtain the effect of setting the fog while not impairing the texture.

The separate saving means that the drawing data for the background image once created is written and saved in the mode buffer 145 provided separately from the frame areas 142a and 142b so that it can be used as it is in the subsequent frames. As shown in FIG. 4, the mode buffer 145 is provided with a first mode area 145a and a second mode area 145b so as to correspond to each display mode in a one-to-one manner.

In other parameters such as the parameter P(2), as shown in FIG. 12C, instead of the information of the image data for the back surface in the various information of FIG. 12B, the information of the object and the texture Information and are set. As these pieces of information, information on addresses of areas in which objects and textures are stored in the memory module 133 is set.

Drawing processing in the VDP 135 will be described with reference to the flowchart in FIG. In the following description, how the drawing data is created as the drawing process is performed will be described with reference to FIG.

First, in step S701, it is determined whether a new drawing list is received from the display CPU 131. If a new drawing list has been received, background setting processing is executed in step S702.

In the setting process for the background, out of the image data specified in the drawing list this time, the image data for the back face for displaying the background image and the object for the character are grasped. Then, it is determined whether or not the image data and the character object are already arranged in the world coordinate system.

If not arranged, a free buffer area to be referred to for arrangement in the world coordinate system is searched for each image data, and if a free buffer area is secured, initialization processing of that area is executed. After that, the memory module 133 grasps and reads the address where the image data is stored, and at the same time, the coordinate value of the local coordinate system for the image data is set so that the coordinates, the rotation angle, and the scale are designated in the drawing list. The world conversion processing for converting the coordinate value into the coordinate value of the world coordinate system is executed, and is set in the secured buffer area.

If it is arranged, update processing of various parameters set in the already secured buffer area is executed. Further, in the background setting process, the control ending process is executed to erase the background image data that is not specified in the current drawing list among the image data already arranged in the world coordinate system.

In a succeeding step S703, effect setting processing is executed. In the setting process for effect, the object for displaying the effect image is grasped from the image data specified in the current drawing list. Then, it is determined whether or not the grasped object is already arranged in the world coordinate system. If not arranged, the process for starting the arrangement is executed as in the case described in the background setting process. If they are arranged, update processing of various parameters is executed. Further, in the setting process for effect, a control ending process is executed to delete the image data for effect that is not specified in the current drawing list among the image data already arranged in the world coordinate system.

In a succeeding step S704, a symbol setting process is executed. In the design setting process for the design, the object for displaying the design is grasped in the image data specified in the drawing list this time. Then, it is determined whether or not the grasped object is already arranged in the world coordinate system. If not arranged, the process for starting the arrangement is executed as in the case described in the background setting process. If they are arranged, update processing of various parameters is executed. Further, in the symbol setting process, a control ending process is executed to erase the image data for symbols not designated in the current drawing list among the image data already arranged in the world coordinate system.

By executing the processes of steps S702 to S704, as shown in FIG. 14, the drawing list specifies the placement target in the world coordinate system defined by the X axis, the Y axis, and the Z axis. The setting of the scene in which the rearmost image PC1 and the various objects PC2 to PC10 are arranged at the coordinates, the rotation angle, and the scale that are also designated by the drawing list is completed.

Note that FIG. 14 simply shows a state in which the rearmost image PC1 and various objects PC2 to PC10 are arranged. Further, the backmost image PC1 does not need to have the Z-axis coordinate set to the back side with respect to all of the various objects PC2 to PC10. For example, the backmost image PC1 is bent or inclined. By arranging in, the coordinates in the Z-axis direction may be on the front side of some objects. However, in the area of the backmost image PC1 in which the coordinates in the X-axis direction and the coordinates in the Y-axis direction are the same as those of some of the objects, the coordinates in the Z-axis direction are farther from the object, so that The object is not covered by the backmost image PC1.

In the following step S705, conversion processing to the camera coordinate system (camera space) is executed. In the conversion process to the camera coordinate system, the coordinates and the direction of the viewpoint are determined by the information of the camera specified by the drawing list, and the world coordinate system is set as the origin of the viewpoint based on the coordinates and the direction of the viewpoint. Convert to camera coordinate system (camera space). As a result, as shown in FIG. 14, the viewpoint PC11 shown by the camera shape is set, and the coordinate system corresponding thereto is set.

Here, the camera information is set for each individual image (the backmost image PC1 and various objects PC2 to PC10), and in reality, a camera coordinate system exists for each individual image. By setting the camera coordinate system for each individual image in this way, viewpoint switching can be performed individually, and the degree of freedom in creating drawing data is increased. However, for convenience of explanation, FIG. 14 shows a state in which all individual images are set to a single viewpoint.

In a succeeding step S706, conversion processing to the visual field coordinate system (visual field space) is executed. In the conversion processing into the visual field coordinate system, each of the camera coordinate systems described above is converted into a visual field coordinate system corresponding to the visual field (viewing angle) from the viewpoint. As a result, for each individual image, if it is included in the field of view of the corresponding viewpoint, it is extracted, and the individual image near the viewpoint is enlarged and the individual image far from the viewpoint is reduced.

In a succeeding step S707, clipping processing is executed. In the clipping process, each individual image extracted in step S706 is recognized with the corresponding viewpoint as a common origin. Then, in this state, the space corresponding to the screen area PC12 (see FIG. 14) corresponding to the drawing target frame areas 142a and 142b (that is, the display surface G of the symbol display device 31) is used as a reference for extraction in step S706. Clip each clipped individual image.

In a succeeding step S708, lighting processing is executed. In the lighting process, the type, coordinates, and direction of the virtual light source are determined based on the light information specified by the drawing list, and the shadow, reflection, etc. of each object extracted by the clipping process are calculated based on the virtual light source. ..

In subsequent steps S709 and S710, two-dimensional data is created. The two-dimensional data is extracted in step S707, and each individual image subjected to the lighting process in step S708 is projected (for example, perspective projection or parallel projection) on the screen area PC12 that is a virtual two-dimensional plane. Created by.

Specifically, first, in step S709, background drawing data creation processing is executed. In the drawing data creation process for the background, the two-dimensional data used for the background is created by projecting the background image and the object set as the background image onto the screen area PC12 while performing hidden surface removal. To do.

Here, the VRAM 134 is provided with a screen buffer 144 as shown in FIG. 4, and a background buffer in which the background drawing data is written in the screen buffer 144, and the drawing data and the design for the effect. The effect and the pattern buffer into which the drawing data for writing are collectively written are set. An area having the same number of dots as the number of pixels of the screen area PC12 is set in the background buffer and the effect/symbol buffer. The two-dimensional data used for the background created in step S709 is written in the background buffer.

Then, color information is set for the two-dimensional data. In the setting of the color information, the drawing data corresponding to each object in the virtual three-dimensional space is created by setting the color information in pixel units or in vertex units with respect to the two-dimensional data obtained by projection. .. In the setting of such color information, basically, texture mapping processing for attaching a corresponding texture to the two-dimensional data obtained by projection is executed. Depending on the situation, bump mapping processing and transparency mapping processing are also executed. If the image data for the background is not specified in the drawing list, the drawing data for the background is not created.

In a succeeding step S710, processing for creating two-dimensional data used for effects and symbols is executed. In the process of creating the two-dimensional data used for the effect and the pattern, the object set as the effect image and the object set as the pattern are projected on the screen area PC12 while the hidden surface is erased. The two-dimensional data used for the effect and the design are created in the effect buffer and the design buffer in the screen buffer 144.

Then, color information is set for the two-dimensional data. In the setting of the color information, the drawing data corresponding to each object in the virtual three-dimensional space is created by setting the color information in pixel units or in vertex units with respect to the two-dimensional data obtained by projection. .. In the setting of such color information, basically, texture mapping processing for attaching a corresponding texture to the two-dimensional data obtained by projection is executed. Depending on the situation, bump mapping processing and transparency mapping processing are also executed. If the rendering and design image data are not specified in the rendering list, rendering data for the rendering and designs are not created.

Then, in step S711, the drawing data combining process is executed, and then the present drawing process is ended. In the drawing data synthesizing process of step S711, the background drawing data and the effect and pattern drawing data individually written in the screen buffer 144 by the processes of step S709 and step S710 are respectively combined, The composition result is written in the drawing target frame areas 142a and 142b as drawing data for one frame.

In this case, the writing order is defined such that the drawing data for the background, the drawing data for the effect, and the drawing data for the symbols are arranged in this order from the back side to the front side. Therefore, the drawing data for the background is first written in the frame areas 142a and 142b to be drawn, and then the drawing data for the effect and the pattern is written. At this time, if the completely transparent α value is set for the pixel for which drawing is performed, the image on the back side is used as it is, and if the semi-transparent α value is set, the α value is set. The image on the back side and the image on the front side are fused at the standard ratio, and when the opaque α value is set, the image on the front side is overwritten on the image on the back side. Then, the fusion operation is executed.

Here, the fusion calculation will be described in more detail. Each numerical value information of RGB of each dot in the drawing target frame areas 142a and 142b is set to the drawing target pixel in the rendering data for the effect and the design. Based on the α value
R: "R value of back side image" x ("1"-"α value") + "R value of front side image" x "α value"
G: “G value of back side image”×(“1”−“α value”)+“G value of front side image”דα value”
B: “B value of back side image”×(“1”−“α value”)+“B value of front side image”דα value”
Becomes

By the way, although each drawing data is defined to have an area for one frame, the α value of complete transparency is set for a blank portion which is not projected in the drawing data for effect and design.

The drawing data for one frame is created so as to be completed within the range of 20 msec cycle. Further, an image signal is output from the display circuit 155 to the symbol display device 31 based on the created drawing data, but since the double buffer method is adopted as already described, the output of the image signal is the output. This is performed in parallel with the creation of the drawing data for one frame after that frame. Further, the display circuit 155 has a selector circuit which alternately switches the frame regions 142a and 142b to be referred to each time the output of the image signal for one frame is completed, and the selector circuit switches the selector circuit to switch the drawing data. The frame areas 142a and 142b, which are drawing targets, are regulated so as not to be output targets for outputting image signals.

Note that steps S702 to S707 are processes executed by the geometry calculation unit 151, and steps S708 to S711 are processes executed by the rendering unit 152.

<Structure for performing meter display production>
Next, a configuration for performing a meter display effect will be described.

The meter display effect is an effect in which meters 241a to 241e whose lengths change according to the points owned by the characters 221 to 225 are displayed below the five characters 221 to 225. FIG. 15 is an explanatory diagram for explaining meter drawing data 229 created as drawing data for effect in the meter display effect. As shown in FIG. 15, in the meter drawing data 229, meters 241a to 241e are individually set for the plurality of characters 221 to 225. The characters 221 to 225 move during the meter display effect. Further, when the corresponding characters 221 to 225 move, the meters 241a to 241e move following the characters 221 to 225.

The points owned by each of the characters 221 to 225 decrease at different speeds as the production progresses. Therefore, the length of each of the meters 241a to 241e at each update timing is individually set. In the pachinko machine 10, as the meter display effects, a low-expectancy effect that is performed when the jackpot expectation is low and a high-expectation effect that is performed when the jackpot expectation is high are performed. The reduction rate of the points owned by each of the characters 221 to 225 is different between the low-expectation meter display effect and the high-expectation meter display effect, and the types of the characters 221 to 225 whose points finally become “0” are also included. different. Therefore, by grasping the amount of decrease in the points owned by each of the characters 221-225, the player can know whether or not the expectation of the jackpot is high.

The meters 241a to 241e and 242 displayed in the meter display effect include meters 241a to 241e in which frames 231a to 231e are displayed around and meters 242 (FIG. 17) in which frames 231a to 231e are not displayed in the surroundings. First, the meters 241a to 241e around which frames 231a to 231e are displayed will be described. The display of the meters 241a to 241e with the frames 231a to 231e on the periphery is performed using the frame object 231, the meter object 261, and the meter texture 281 stored in the memory module 133.

The lengths of the rectangular meters 241a to 241e are determined by the distance between the side existing at one end in the longitudinal direction and the side existing at the other end in the longitudinal direction among the four sides forming the outer shape of the meters 241a to 241e. .. One end in the longitudinal direction is a fixed end, and the side existing at the fixed end is always displayed at the same position with respect to the characters 221 to 225. On the other hand, the other end in the longitudinal direction is a moving end, and the side existing at the moving end moves to the fixed end side every time the points owned by the characters 221 to 225 decrease.

16A shows the frame object 231 and FIG. 16B shows the meter object 261. Further, FIG. 16C shows a texture 281 for a meter. As shown in FIG. 16A, the frame object 231 is a plate-shaped polygon having a rectangular inner circumference and a rectangular outer circumference slightly larger than the inner circumference of the rectangle. Of the four sides forming the inner circumference of the frame object 231, the side existing at one end in the longitudinal direction is the side A, and the side existing at the other end in the longitudinal direction is the side B. Here, the side A is a side on the fixed end side of the meters 241a to 241e, and the side B is a side on the moving end side of the meters 241a to 241e.

As shown in FIG. 16B, the meter object 261 is a plate-shaped polygon, and its outer shape is the same shape and size as the inner circumference of the frame object 231. The side existing at one end in the longitudinal direction of the meter object 261 is defined as side C, and the side existing at the other end in the longitudinal direction is defined as side D. Here, the side C is a side corresponding to the fixed ends of the meters 241a to 241e, and the side D is a side corresponding to the moving ends of the meters 241a to 241e. The meter object 261 is stored in the memory module 133 with the size corresponding to the case where the points owned by the characters 221 to 225 are maximum as an initial state.

The memory module 133 stores meter animation data for setting the meter object 261 at five different locations in the world coordinate system. In the animation data, parameters of the meter object 261 are set so that the meters 241a to 241e move in the world coordinate system so as to follow the characters 221 to 225. Regarding the animation data for the meter, specifically, a plurality of pointer information is set so as to be a serial number, and the meter object 261 is set at each of five points in the world coordinate system for each pointer information. The parameters for setting are set. The parameter includes a reduction ratio in the longitudinal direction of the meter object 261, a coordinate, a rotation angle, and a scale. At the update timing, the display CPU 131 sets the parameters set in the meter animation data in the drawing list. Further, the VDP 135 reduces the meter object 261 based on the reduction ratio in the longitudinal direction set in the drawing list. Then, the reduced meter object 261 is set in the world coordinate system. As a result, meter objects 261 having different lengths are set in the world coordinate system according to the points owned by the characters 221 to 225.

It should be noted that one meter object 261 is stored in the memory module 133, and the VDP 135 accesses the address where the meter object 261 is stored five times to set the same meter object 261 to five different locations. By doing so, five meters 241a to 241e are displayed on the display surface G of the symbol display device 31.

Further, the memory module 133 stores frame animation data for setting the frame object 231 at five different locations in the world coordinate system. In the animation data, parameters of the frame object 231 are set so that the frames 231a to 231e move in the world coordinate system in a manner to follow the characters 221 to 225. Regarding the frame animation data, specifically, a plurality of pointer information is set so as to be serial numbers, and the frame object 231 is set at each of five points in the world coordinate system for each pointer information. The parameters for setting are set. The parameters include the coordinates, the rotation angle, and the scale of the frame object 231.

The frame object 231 is set in the world coordinate system in such a manner that the side A on the fixed end side of the frame object 231 matches the side C corresponding to the fixed end of the meter object 261 at the start timing and each update timing. .. At the start timing when the meter object 261 is not reduced, the frame object 231 is set to the world in such a manner that the side B on the moving end side of the frame object 231 and the side D corresponding to the moving end of the meter object 261 match. Set to the coordinate system. Further, at the update timing when the reduced meter object 261 is set, a side D corresponding to the moving end of the meter object 261 is provided between the side A on the fixed end side and the side B on the moving end side of the frame object 231. The frame object 231 is set in the world coordinate system in a manner in which is positioned.

Note that one frame object 231 is stored in the memory module 133, and the VDP 135 accesses the address where the frame object 231 is stored five times to set the same frame object 231 to five different locations. By doing so, five frames 231a to 231e are displayed on the display surface G of the symbol display device 31.

At the start timing, since the points owned by the five characters 221 to 225 are all maximum values, the meter object 261 is set in the world coordinate system with the initial size. Specifically, as shown in FIG. 16D, the side A on the fixed end side of the frame object 231 and the side C corresponding to the fixed end of the meter object 261 coincide, and the frame object 231 moves. The frame object 231 and the meter object 261 are set in the world coordinate system in such a manner that the side B on the end side and the side D corresponding to the moving end of the meter object 261 coincide with each other.

When the number of points owned by the characters 221 to 225 is less than the maximum value at the update timing, the meter object 261 is reduced in the longitudinal direction. In this case, as shown in FIG. 16(e), the side A on the fixed end side of the frame object 231 and the side C corresponding to the fixed end of the meter object 261 coincide with each other and the moving end of the meter object 261 coincides with the side. The frame object 231 and the meter object 261 are set in the world coordinate system such that the corresponding side D is located between the side A on the fixed end side and the side B on the moving end side of the frame object 231. ..

The VDP 135 applies the meter texture 281 (FIG. 16C) to the projection data of the meter object 261 by parallel projection mapping to create the meter drawing data 229. As shown in FIG. 16C, the meter texture 281 is image data corresponding to the meter object 261, and has the same rectangular outer shape as the meter object 261. Of the four sides forming the outer shape of the texture 281 for a meter, the side existing at one end in the longitudinal direction is a side E, and the side existing at the other end in the longitudinal direction is a side F. Here, the side E of the meter texture 281 is a side corresponding to the fixed ends of the meters 241a to 241e, and the side F of the meter texture 281 is a side corresponding to the moving ends of the meters 241a to 241e.

The parallel projection mapping will be described with reference to FIGS. 17(a) and 17(b). FIG. 17A is an explanatory diagram for explaining a method of creating projection data of the meter object 261 and the frame object 231.

The meter object 261 and the frame object 231 are projected on the screen area PC12 to create projection data. Since the size of the screen area PC12 is the same as the size of the display surface G of the symbol display device 31, the size of the projection data created is also the same as the size of the display surface G of the symbol display device 31. In the projection data, the area where the frame object 231 is actually projected is referred to as a frame projection area 252. By the projection of the frame object 231, information that allows the user to know that the frame object 231 is projected is set to all the dots included in the frame projection area 252. Then, gray color information is set to the dots for which the information is set. The color information is stored in the memory module 133 as color information for displaying the frames 231a to 231e, and is set in the drawing list by the display CPU 131.

Further, in the frame projection area 252, the area in which the side B on the moving end side of the frame object 231 is projected becomes the reference data 264 on the moving end side. The moving end side reference data 264 is reference data that defines the end on the moving end side of the parallel projection area, which is the area in which the meter texture 281 is projected in parallel. The dots included in the reference data 264 on the moving end side are set with information that can be grasped as the dots forming the reference data 264 on the moving end side.

In the projection data, the area where the meter object 261 is actually projected is referred to as a meter projection area 251. By the projection of the meter object 261, information that allows the user to know that the meter object 261 is projected is set to all the dots included in the meter projection area 251. Further, in the meter projection area 251, the area where the side C of the meter object 261 on the fixed end side is projected becomes the reference data 263 on the fixed end side. The reference data 263 on the fixed end side is reference data that defines the end on the fixed end side of the parallel projection area, which is the area in which the meter texture 281 is projected in parallel. The dots included in the reference data 263 on the fixed end side are set with information that can be understood as dots forming the reference data 263 on the fixed end side.

At the update timing when the points owned by the characters 221 to 225 are decreasing, the meter object 261 is contracted in the longitudinal direction, so that the side D on the moving end side of the meter object 261 is the side C on the fixed end side. Exists in a position close to. In this case, in the world coordinate system, the area sandwiched between the side D on the fixed end side of the meter object 261 and the side B on the moving end side of the frame object 231 becomes a blank area 253 where no object exists. Further, in the projection data of the meter object 261 and the frame object 231, a region in which the side D on the moving end side of the meter object 261 is projected and a region in which the side B on the moving end side of the frame object 231 is projected. The area sandwiched by the reference data 264 on the moving end side is a blank corresponding area 254 corresponding to the blank area 253. No object is projected in the blank corresponding area 254, and black color information is set to all the dots forming the blank corresponding area 254.

At the start timing when the points owned by the characters 221 to 225 have the maximum value, the meter object 261 is not reduced in the longitudinal direction, and thus the side D on the moving end side of the meter object 261 in the world coordinate system. And the side B on the moving end side of the frame object 231 exist at the same position. Therefore, the blank area 253 and the blank corresponding area 254 do not exist.

FIG. 17B is an explanatory diagram for explaining a method of applying the meter texture 281 to the projection data of the meter object 261 and the frame object 231. As shown in FIG. 17B, the area on which the meter texture 281 is projected in parallel is a parallel projection area defined by the reference data 263 on the fixed end side and the reference data 264 on the moving end side. The parallel projection area is an area sandwiched between the fixed end side reference data 263 and the moving end side reference data 264, and is an area formed by the meter projection area 251 and the blank corresponding area 254.

In the meter texture 281, the side E on the fixed end side of the meter texture 281 is projected on the reference data 263 on the fixed end side, and the side F on the moving end side of the meter texture 281 is the reference data 264 on the moving end side. Is projected in parallel onto the parallel projection area. Then, the color information and the transparency information of the meter texture 281 are set only in the dots forming the meter projection area 251 in the parallel projection area. On the other hand, the black color information set in the dots forming the blank corresponding area 254 in the parallel projection area is not changed by the parallel projection of the meter texture 281.

The process of setting the color information and the transparency information of the meter texture 281 in the meter projection area 251 will be described below. The VDP 135 sets one dot included in the meter projection area 251 as a target dot. When one pixel of the meter texture 281 is projected on the target dot, the color information and the transparency information set on the pixel are set on the target dot. For example, when the shape and size of the meter projection area 251 is the same as the shape and size of the meter texture 281, one pixel of the meter texture 281 is projected onto one dot of the meter projection area 251.

When a plurality of pixels of the meter texture 281 are projected on the target dot, color information and transparency information are selected. In the selection of color information and transparency information, among the plurality of pixels projected on the target dot, the color information and transparency information set on the pixel with the largest area projected on the target dot is set on the target dot. To do. For example, when the size of the meter projection area 251 is smaller than the size of the meter texture 281, a plurality of pixels of the meter texture 281 are projected on one dot of the meter projection area 251.

If the pixels of the meter texture 281 projected on the target dot do not exist and a plurality of pixels of the meter texture 281 are projected around the target dot, the color information and the transparency information are complemented. I do. In complementing the color information and the transparency information, the color information and the transparency information of a plurality of pixels projected around the target dot are weighted according to the distance from the target dot, and then the plurality of pixels The color information and the transparency information are blended, and the color information and the transparency information obtained by the blending are set to the target dot. For example, when the size of the meter projection area 251 is larger than the size of the meter texture 281, the pixels of the meter texture 281 projected on one dot of the meter projection area 251 do not exist, and A plurality of pixels are projected on the periphery.

At the update timing when the viewpoint PC11 is switched, the shape of the meter projection area 251 may be different from the shape of the meter texture 281. Also in this case, when the meter texture 281 is projected in an area smaller than the meter texture 281, the color information and the transparency information are selected, and the meter texture 281 is wider than the meter texture 281. When projected onto the area, the texture 281 for the meter is applied to the projection area 251 for the meter by complementing the color information and the transparency information.

The target dot is updated until the color information and the transparency information of the meter texture 281 are set in all the dots forming the meter projection area 251. As a result, the color information and the transparency information of the meter texture 281 are set in the meter projection area 251. At the start timing when the longitudinal reduction of the meter object 261 is not performed, the parallel projection area and the meter projection area 251 match, and the blank corresponding area 254 does not exist. Therefore, the meter texture is displayed in the meter projection area 251. The entire image of 281 is displayed without being deformed. Specifically, the numbers 1 to 5 are displayed in the projection area 251 for the meter without being deformed.

In parallel projection mapping, when an object is deformed, the mapping does not follow the surface of the object, so that the correspondence between the texture and the object deviates. At the update timing when the meter object 261 is contracted in the longitudinal direction, the blank corresponding area 254 exists, so that part of the image of the meter texture 281 is deformed only in the meter projection area 251 of the parallel projection area. Displayed without. For example, as shown in FIG. 17B, the numbers 1 to 3 of the texture for a meter 281 are displayed and are displayed without being deformed. In this case, the numbers 4 and 5 are not displayed and are not displayed. In the meter texture 281, the range to be displayed changes according to the reduction ratio of the meter object 261 in the longitudinal direction. Specifically, as the meter object 261 is reduced in size, shorter meters 241a to 241e are displayed. In this case, the number of the texture 281 for the meter is not deformed and is displayed on the meters 241a to 241e.

Next, a case where the meter texture 281 is applied to the meter projection area 251 by UV mapping will be described. In UV mapping, the meter texture 281 existing in the UV coordinate system is used. Further, in UV mapping, even if the object corresponding to the texture is deformed, the mapping follows the deformation of the object, and therefore the correspondence relationship between the texture and the object cannot be lost.

When the meter object 261 is contracted in the longitudinal direction and set in the world coordinate system at the update timing, the entire meter texture 281 is displayed in the meter projection area 251, as shown in FIG. 17C. Is reduced. Specifically, the numbers 1 to 5 of the meter texture 281 are reduced and displayed in the meter projection area 251 at the update timing, which is smaller in area than the meter projection area 251 at the start timing. In this case, the numbers displayed on the meters 241a to 241e are smaller in the longitudinal direction than the numbers on the meter texture 281. Even if the lengths of the meters 241a to 241e change, the number of numbers displayed on the meters 241a to 241e does not change, so it is difficult for the player to know that the points owned by the characters 221 to 225 have decreased.

When using the UV mapping to display a part of the meter texture 281 without deforming it, it is necessary to convert the UV coordinates of the meter texture 281 according to the reduction ratio of the meter object 261. The processing load increases. On the other hand, by using parallel projection mapping instead of UV mapping, it is possible to perform partial display of the meter texture 281 while suppressing an increase in processing load. Here, the partial display of the meter texture 281 is a display in which the moving end sides of the meters 241a to 241e are missing. In particular, when a plurality of meter displays are individually performed as in the present meter display effect, parallel projection mapping can effectively prevent an increase in processing load.

By using the parallel projection mapping, it is possible to perform the meter display in such a manner that the numbers displayed on the meters 241a to 241e decrease, and the points owned by the characters 221 to 225 decrease. Can be easily understood by the player.

Next, a method of independently displaying the meter 242 in which the frames 231a to 231e are not displayed in the periphery will be described. FIG. 18A is an explanatory diagram for explaining the meter 242 displayed alone below the character 226. When the meter 242 is displayed without displaying the frames 231a to 231e on the periphery, the meter object 261, the blank object 291, and the meter texture 281 are used.

FIG. 18B is an explanatory diagram for explaining a state in which the meter object 261 and the blank object 291 reduced in the longitudinal direction are set in the world coordinate system. The blank object 291 is a line segment connecting two vertices and is a one-dimensional object. Since the completely transparent transparency information (α value of “0”) is set in the blank object 291, the blank object 291 is not displayed on the display surface G of the symbol display device 31. Further, the side C corresponding to the fixed end of the meter object 261 and the blank object 291 are set in the world coordinate system so as to always have a fixed positional relationship.

The memory module 133 stores blank animation data for setting blank objects 291 at five different locations in the world coordinate system. Parameters are set in the animation data so that the blank object 291 moves in the world coordinate system in a manner to follow the characters 221 to 225. With respect to the animation data for blank, specifically, a plurality of pointer information is set so as to be a serial number, and a blank object 291 is set in each of the pointer information at five locations in the world coordinate system. The parameters for are set. The parameters include the coordinates of the blank object 291, the rotation angle, and the scale.

The interval between the side C corresponding to the fixed end of the meter object 261 and the blank object 291 at the start timing and each update timing is the side C corresponding to the fixed end of the meter object 261 at the start timing and the side corresponding to the moving end. It is the same as the first interval which is the interval with D. In the VDP 135, the positional relationship between the side C corresponding to the fixed end of the meter object 261 and the blank object 291 is the side C corresponding to the fixed end of the meter object 261 at the start timing and the side D corresponding to the moving end. The blank object 291 is set at the same interval as the first interval from the meter object 261 in the same manner as the positional relationship.

When the meter 242 is displayed alone, the method of defining the parallel projection area in which the meter texture 281 is projected in parallel is different from the case where the frames 231a to 231e are displayed around the meter 242. The processing in which the meter texture 281 is projected in parallel onto the parallel projection area and the color information and the transparency information of the meter texture 281 are set in the meter projection area 251, is displayed in the case where the meter 242 is displayed alone and in the surrounding frame. This is the same as when displaying 231a to 231e. FIG. 18C is an explanatory diagram for explaining a process of projecting the meter object 261 and the blank object 291 on the screen area PC12.

First, the meter object 261 and the blank object 291 set in the world coordinate system are projected on the screen area PC12 to create projection data. The projection data includes a meter projection area 251 on which the meter object 261 is actually projected. Information that allows the user to know that the meter object 261 has been projected is set to all the dots forming the meter projection area 251.

Further, in the meter projection area 251, the area where the side C on the fixed end side of the meter object 261 is projected becomes the reference data 298 on the fixed end side. The fixed end side reference data 298 is reference data for defining the end on the fixed end side of the parallel projection area in which the meter texture 281 is projected in parallel. The dots included in the reference data 298 on the fixed end side are set with information that can be grasped as dots forming the reference data 298 on the fixed end side.

Further, the area where the blank object 291 is projected becomes the reference data 292 on the moving end side. The moving end side reference data 292 is reference data for defining the end on the moving end side of the parallel projection area in which the meter texture 281 is projected in parallel. The dots included in the reference data 292 on the moving end side are set with information that can be understood as dots forming the reference data 292 on the moving end side.

At the update timing when the points owned by the characters 221 to 225 are decreasing, the meter object 261 is contracted in the longitudinal direction, so that the side D on the moving end side of the meter object 261 is the side C on the fixed end side. Exists in a position close to. In this case, in the world coordinate system, the area sandwiched between the side D on the fixed end side of the meter object 261 and the blank object 291 becomes a blank area 255 where no object exists. Further, in the projection data of the meter object 261 and the blank object 291, the area in which the side D of the meter object 261 on the moving end side is projected and the reference data 292 on the moving end side which is the area in which the blank object 291 is projected. The area sandwiched by and becomes a blank corresponding area 256 corresponding to the blank area 255. No object is projected in the blank corresponding region 256, and color information is not set in all the dots forming the blank corresponding region 256, but transparency information of complete transparency is set.

At the start timing when the points owned by the characters 221 to 225 have the maximum value, the meter object 261 is not reduced in the longitudinal direction, and thus the side D on the moving end side of the meter object 261 in the world coordinate system. And the blank object 291 are present at the same position. Therefore, the blank area 255 and the blank corresponding area 256 do not exist.

FIG. 18D is an explanatory diagram for explaining a method of applying the meter texture 281 to the projection data of the meter object 261 and the blank object 291. As shown in FIG. 18D, the area in which the meter texture 281 is projected in parallel is a parallel projection area defined by the reference data 298 on the fixed end side and the reference data 292 on the moving end side. The parallel projection area is an area sandwiched between the reference data 298 on the fixed end side and the reference data 292 on the moving end side, and is an area composed of the meter projection area 251 and the blank corresponding area 256.

In the meter texture 281, the side E on the fixed end side of the meter texture 281 is projected on the reference data 298 on the fixed end side, and the side F on the moving end side of the meter texture 281 is the reference data 292 on the moving end side. Is projected in parallel onto the parallel projection area. Then, the color information and the transparency information of the meter texture 281 are set only in the dots forming the meter projection area 251 in the parallel projection area. On the other hand, the completely transparent transparency information set in the dots forming the blank corresponding region 256 in the parallel projection region is not changed by the parallel projection of the meter texture 281.

As described above, by using the blank object 291, it is possible to define a parallel projection area in which the meter texture 281 is projected in parallel without using the frame object 231, and corresponds to the fixed end of the meter texture 281. Partial display in which a part of the side E is displayed can be performed. By using the blank object 291, it is possible to independently display the meter 242 without the frames 231a to 231e.

The VDP 135 creates drawing data for effects and symbols in the drawing data creation process for effects and symbols in step S710 of the drawing process (FIG. 13). Specifically, the drawing data 229 for the meter and the drawing data for the symbol display, which are individually created, are used for the screen in such a manner that the drawing data 229 for the meter is arranged on the back side and the drawing data for the symbol display is arranged on the front side. By writing in the buffer 144, drawing data for effects and symbols is created.

Further, the VDP 135 sets the background drawing data and the effect and design drawing data individually written in the screen buffer 144 in the drawing data combining process in step S711 of the drawing process (FIG. 13) to the background. The drawing data for one line is created on the back side, and the drawing data for the effect and the pattern is written on the front side for writing in the frame areas 142a and 142b to be drawn, thereby creating one frame of drawing data. It should be noted that each drawing data has the same outer shape, and the number of pixels forming each drawing data is also the same.

In the case of creating drawing data for effects and patterns and in the case of creating drawing data for one frame, if the pixel for which drawing is executed is set to the α value of complete transparency, the back side When the semi-transparent α value is set, the color information of the image is used as it is, and the color information of the image on the back side and the color information of the image on the front side are blended at a ratio based on the α value. When the opaque α value is set, the color information of the image on the back side is overwritten with the color information of the image on the back side. As a result, the images of the characters 221 to 225 and the images of the meters 241a to 241e, 242 are displayed as images for effect at positions on the front side of the background image and on the back side of the design image. .. A background image is displayed in the blank corresponding region 256 in which the transparency information of complete transparency is set, and in which a pattern image is not displayed in front.

Hereinafter, a specific processing configuration for executing the meter display effect will be described.

FIG. 19 is a flowchart showing the grasping process for the meter display effect executed by the display CPU 131. The grasping process for the meter display effect is performed by the effect calculation process in step S604 of the task process (FIG. 11). Further, the grasping process for the meter display effect is activated when the data table corresponding to the game time in which the meter display effect is executed is set.

First, in step S801, it is determined based on the currently set data table whether or not the meter display effect is being executed. When the meter display effect is not being executed (step S801: NO), it is determined in step S802 whether or not it is the start timing of the meter display effect. If it is not the start timing, the present grasping process is ended as it is, and if it is the start timing, the process proceeds to step S803.

In step S803, character animation data for displaying the five characters 221 to 225 in the world coordinate system is read. A plurality of pieces of pointer information are set in the character animation data so as to be serial numbers, and 5 pieces of character objects for displaying the five characters 221 to 225 are included in each piece of pointer information. Parameters for people are set. The parameters include the coordinates of the character object, the rotation angle, and the scale.

In step S804, based on the currently set data table, it is determined whether or not the expectation level for the jackpot in the current game game is low. When the expectation of the big hit is low (step S804: YES), the meter animation data for the low expectation is read in step S805. On the other hand, when the expectation of the big hit is high (step S804: NO), the meter animation data for the high expectation is read in step S806.

After the meter animation data is read in step S805 or step S806, it is determined in step S807 whether or not to display the frames 231a to 231e based on the currently set data table. When displaying the frames 231a to 231e (step S807: YES), the frame animation data for grasping the parameters necessary for setting the frame object 231 in the world coordinate system is read in step S808. .. A mode in which the side C corresponding to the fixed end of the meter object 261 and the side A on the fixed end side of the frame object 231 overlap the animation data, and the meter object 261 and the frame object 231 exist on the same plane. Then, a parameter for setting the frame object 231 is set.

On the other hand, when the frames 231a to 231e are not displayed (step S807: NO), blank animation data for grasping the parameters necessary for setting the blank object 291 in the world coordinate system is read in step S809. .. In the animation data, the positional relationship between the side C corresponding to the fixed end of the meter object 261 and the blank object 291 is the side corresponding to the fixed end of the meter object 261 at the start timing and the side corresponding to the moving end. Parameters for setting the blank object 291 are set in the same manner as the positional relationship with D.

When an affirmative determination is made in step S801, it is determined in step S810 based on the currently set data table whether or not it is the update timing for reducing the meter object 261 in the longitudinal direction. If it is the update timing for performing reduction (step S810: YES), reduction instruction information is stored in step S811.

After step S808, after step S809, after step S811, or after making a negative determination in step S810, various data grasping processing for meter display effect is executed in step S812.

Here, the various data grasping process for the meter display effect will be described with reference to the flowchart of FIG. FIG. 20 is a flowchart showing a process of grasping various data for the meter display effect, which is executed by the display CPU 131. The character object for displaying the characters 221-225, the frame objects 231-235, the blank object 291, the meter object 261, and the meter texture 281 are stored in advance in the memory module 133.

First, in step S901, use instruction information of a character object for displaying the characters 221 to 225 is stored based on the currently set data table, and in step S902, the already-read character animation data is stored. And grasp the parameters of the five character objects.

In step S903, the use instruction information of the meter object 261 is stored based on the currently set data table, and the meter object 261 is referenced by referring to the meter animation data that has already been read in step S904. Understand 5 parameters. Then, in step S905, the use instruction information of the meter texture 281 is stored based on the currently set data table.

In step S906, it is determined whether to display the frames 231a to 231e based on the currently set data table. When displaying the frames 231a to 231e (step S906: YES), in step S907, the use instruction information of the frame object 231 is stored based on the currently set data table. Then, in step S908, the parameter for setting the frame object 231 in the world coordinate system is grasped by referring to the already read frame animation data. In the following step S909, the gray color information is grasped as the color information for displaying the frames 231a to 231e, and in the step S910, the black color information is grasped as the color information for setting in the blank corresponding area 254. ..

When the frames 231a to 231e are not displayed (step S906: NO), use instruction information of the blank object 291 is stored in step S911. Then, in step S912, the parameter for setting the blank object 291 in the world coordinate system is grasped by referring to the already read blank animation data, and this grasping process is ended.

Returning to the explanation of the grasping process for the meter display effect (FIG. 19), after executing various data grasping process for the meter display effect in step S812, the designation information is stored in step S813 and the grasping process is ended. .. In step S813, start designation information is stored when it is the start timing of the meter display effect, and update designation information is stored when it is the update timing of the meter display effect.

When the grasping process for the meter display effect is executed as described above, an object for displaying the characters 221 to 225, the meter object 261 and the meter are included in the drawing list created in the subsequent drawing list output process. Use instruction information of the texture 281 is set. When the frames 231a to 231e are displayed, the use instruction information of the frame object 231 is set, and when the frames 231a to 231e are not displayed, the use instruction information of the blank object 291 is set. In the drawing list, the parameter of the object for displaying the characters 221 to 225 and the parameter of the meter object 261 are also set. When displaying the frames 231a to 231e, the parameters of the frame object 231, the gray color information set in the frames 231a to 231e, and the black color information set in the blank corresponding area 254 are set. If the frames 231a to 231e are not displayed, the parameters of the blank object 291 are set. Reduction instruction information is also set at the update timing when the length reduction of the meter object 261 is performed. Further, the start designation information is stored at the start timing, and the update designation information is set at the update timing.

Next, a meter object setting process executed by the VDP 135 will be described with reference to FIG. The setting process of the meter object is executed by the effect setting process in step S703 of the drawing process (FIG. 13).

First, in step S1001, the drawing list of this time is referred to, and the address where the object for displaying the characters 221 to 225 is stored in the memory module 133 is grasped and read. In a succeeding step S1002, the drawing list of this time is referred to and the parameters of five objects for displaying the characters 221 to 225 are grasped. Then, in step S1003, processing for setting objects for displaying the characters 221 to 225 in five different locations in the world coordinate system is performed based on the parameters grasped in step S1002. Then, in step S1004, various object setting processing for meter display effect is executed.

Here, various object setting processing for the meter display effect will be described with reference to the flowchart of FIG. FIG. 22 is a flowchart showing the various object setting process for the meter display effect executed by the VDP 135.

First, in step S1101, the drawing list of this time is referred to and it is determined whether or not the use instruction information of the frame object 231 is set. When the use instruction information of the frame object 231 is set (step S1101: YES), “1” is added to the variable k in step S1102. Here, the variable k is an integer of 1 from 0 to 5. The variable k represents the number of frame objects 231 set in the world coordinate system, and when the frame objects 231 are set at five different positions in the world coordinate system, “0” is cleared in step S1107. ..

In step S1103, the drawing list of this time is referred to, and the address where the frame object 231 is stored in the memory module 133 is grasped and read. In a succeeding step S1104, the drawing list of this time is referred to, and the k-th parameter of the frame object 231 is grasped. Here, the kth parameter of the frame object 231 is a parameter for displaying the frames 231a to 231e below the kth characters 221 to 225 (FIG. 15). For example, when k=1, it is a parameter for displaying the frame 231a below the first character 221, and when k=2, it is a parameter for displaying the frame 231b below the second character 222. It is a parameter.

In step S1105, the frame object 231 is set in the world coordinate system based on the k-th parameter grasped in step S1104, and it is determined in step S1106 whether k is 5. That is, it is determined whether or not the five frame objects 231 are set in the world coordinate system. If k is less than “5” (step S1106: NO), the process returns to step S1102 and the frame object 231 is set in the world coordinate system again. On the other hand, when k is "5" (step S1106: YES), k is cleared to "0" in step S1107, and the present setting process ends.

If there is no use instruction information for the frame object 231 (step S1101: NO), “1” is added to the variable j in step S1108. Here, the variable j is an integer of 0 to 5. The variable j represents the number of blank objects 291 set in the world coordinate system, and is cleared to "0" in step S1113 when the blank objects 291 are set at five different places in the world coordinate system.

In step S1109, the drawing list of this time is referred to, and the address where the blank object 291 is stored in the memory module 133 is grasped and read. In a succeeding step S1110, the j-th parameter of the blank object 291 is grasped by referring to the drawing list of this time. Here, the j-th parameter of the blank object 291 is a parameter for independently displaying the meter 242 without the frames 231a to 231e below the j-th character (FIG. 15). For example, when j=1, it is a parameter for displaying the meter 242 alone below the first character 221, and when j=2, the meter 242 alone is displayed below the second character 222. Is a parameter for.

In step S1111, the blank object 291 is set in the world coordinate system based on the j-th parameter grasped in step S1110, and it is determined in step S1112 whether the variable j is “5”. That is, it is determined whether or not five blank objects 291 have been set in the world coordinate system. If the variable j is less than "5" (step S1112: NO), the process returns to step S1108 to set the blank object 291 in the world coordinate system again. On the other hand, when the variable j is "5" (step S1112: YES), the variable j is cleared to "0" in step S1113, and this setting process ends.

Returning to the description of the meter object setting process (FIG. 21 ), after performing various object setting processes for the meter display effect in step S1004, “1” is added to the variable m in step S1005. Here, the variable m is an integer of any one of 0-5. The variable m represents the number of meter objects 261 set in the world coordinate system, and is cleared to "0" in step S1012 when five meter objects 261 are set in the world coordinate system.

In step S1006, the drawing list of this time is referred to, and the address where the meter object 261 is stored in the memory module 133 is grasped and read. In a succeeding step S1007, the m-th parameter of the meter object 261 is grasped by referring to the drawing list this time. Here, the mth parameter of the meter object 261 is a parameter for displaying the meters 241a to 241e located below the mth characters 221 to 225 (FIG. 15). For example, when m=1, it is a parameter for displaying the meter 241a located below the first character 221, and when m=2, the meter 241b located below the second character 222 is displayed. Is a parameter for.

In step S1008, it is determined whether reduction instruction information is set in the current drawing list. If the reduction instruction information is set (step S1008: YES), the meter object 261 is reduced in the longitudinal direction in step S1009. The reduction is executed based on the m-th parameter grasped in step S1007. After making a negative determination in step S1008 or after step S1009, in step S1010, the meter object 261 is set in the world coordinate system based on the m-th parameter.

In step S1011 it is determined whether the variable m is "5". When the variable m is less than “5” (step S1011: NO), the process returns to step S1005 and the meter object 261 is set in the world coordinate system again. On the other hand, when the variable m is "5" (step S1011: YES), the variable m is cleared to "0" in step S1012, and the meter texture application process is performed in step S1013 to perform the main setting. The process ends.

Next, the processing for applying the meter texture will be described with reference to FIG. FIG. 23 is a flowchart showing the meter texture application processing executed by the VDP 135.

In step S1201, the object set in the world coordinate system is projected on the screen area PC12 to create projection data. In the case of the meter display effect of displaying the frames 231a to 231e, the meter object 261 and the frame object 231 set in the world coordinate system are projected. In the case of the meter display effect in which the frames 231a to 231e are not displayed, the meter object 261 and the blank object 291 set in the world coordinate system are projected.

In the projection of the meter object 261, information that allows the user to know that the meter object 261 is projected on all the dots included in the meter projection area 251 is set. In the case of the meter display effect that displays the frames 231a to 231e, the area in which the side B on the moving end side of the frame object 231 is projected becomes the moving end side reference data 264, and is included in the moving end side reference data 264. Information is set to all the dots to be recognized as dots forming the reference data 264 on the moving end side. In addition, the area where the side C on the fixed end side of the meter object 261 is projected becomes the reference data 263 on the fixed end side, and the reference data 263 on the fixed end side is set to all the dots included in the reference data 263 on the fixed end side. Information is set so that it can be understood that the dots are constituent dots.

Further, in the case of the meter display effect in which the frames 231a to 231e are not displayed, the area on which the blank object 291 is projected becomes the reference data 292 on the moving end side, and moves to all the dots included in the reference data 292 on the moving end side. Information is set so that it can be recognized that the dots form the reference data 292 on the edge side. Further, the area where the side C on the fixed end side of the meter object 261 is projected becomes the reference data 298 on the fixed end side, and the reference data 298 on the fixed end side is set to all the dots included in the reference data 298 on the fixed end side. Information is set so that it can be understood that the dots are constituent dots.

In step S1202, "1" is added to the variable n. Here, the variable n is an integer of 0 to 5. The variable n represents the number of times the meter texture 281 is applied to the projection data of the meter object 261, and the meter texture 281 is applied five times to the projection data of the five meter objects 261. Then, in step S1214, "0" is cleared.

In step S1203, the drawing list of this time is referred to, and it is determined whether or not the use instruction information of the frame object 231 is set. When the use instruction information of the frame object 231 is set (step S1203: YES), a gray color for setting the frame projection area 252 with reference to the current drawing list in step S1204. Information is read from the memory module 133. In the following step S1205, gray color information is set for all the dots included in the frame projection area 252. In step S1206, the black color information for setting the blank corresponding area 254 is read from the memory module 133 by referring to the drawing list this time. In the following step S1207, black color information is set in the blank corresponding area 254.

In step S1208, in the projection data of the meter object 261 and the frame object 231, the position information of the n-th moving end side reference data 264 is grasped. On the other hand, if the use instruction information of the frame object 231 is not set (step S1203: NO), in the projection data of the meter object 261 and the blank object 291, the n-th moving end side in step S1209. The position information of the reference data 292 is grasped.

After grasping the reference data 264 and 292 on the n-th moving end side in step S1208 or step S1209, in step S1210, the drawing list of this time is referred to, and the texture 281 for the meter is stored in the memory module 133. Grasp and read the address. In step S1211, the position information of the n-th fixed end side reference data 263, 298 in the projection data is grasped. In detail, in the case of the meter display effect of displaying the frames 231a to 231e, the position information of the reference data 263 on the n-th fixed end side is grasped in the projection data of the meter object 261 and the frame object 231. In the case of the meter display effect in which the frames 231a to 231e are not displayed, the position information of the reference data 298 on the n-th fixed end side is grasped in the projection data of the meter object 261 and the blank object 291.

In step S1212, the meter texture 281 is applied to the nth meter projection area 251 by parallel projection mapping. Here, the n-th meter projection area 251 is the projection area of the meter object 261 set in the world coordinate system to display the meters 241a to 241e located below the nth character (FIG. 15). It is 251.

The parallel projection mapping of the texture for a meter 281 is performed by projecting the side E corresponding to the fixed end of the texture for a meter 281 onto the reference data 263, 298 on the fixed end whose position information is grasped in step S1211, and The side F corresponding to the moving end of 281 is projected on the moving end side reference data 264 whose position information is grasped in step S1208 or the moving end side reference data 292 whose position information is grasped in step S1209. Be seen. That is, the meter texture 281 is projected in parallel onto the parallel projection area defined by the fixed end side reference data 263 and 298 and the moving end side reference data 264 and 298.

In the parallel projection mapping, the color information and the transparency information set in the pixels of the meter texture 281 projected on the target dot in the meter projection area 251 are set in the target dot. When a plurality of pixels are projected on the target dot, the color information and the transparency information are selected and the color information and the transparency information are set on the target dot. When there is no pixel projected on the target dot, the color information and the transparency information are complemented to set the color information and the transparency information on the target dot. The target dot is updated until the setting of the color information and the transparency information of the meter texture 281 is completed for all the dots in the meter projection area 251. As a result, the meter texture 281 is applied to the n-th meter projection area 251.

In step S1213, it is determined whether n is "5". When n is less than “5” (step S1213: NO), the process returns to step S1202, and the process of applying the meter texture 281 to the projection data of the meter object 261 is executed again. On the other hand, when n is “5” (step S1213: YES), n is cleared to “0” in step S1214, and this application process is ended.

As described above, in the meter display effect, by applying the texture 281 for the meter to the projection area 251 for the meter by the parallel projection mapping, only the object 261 for the meter is reduced in the longitudinal direction, and the characters 221 to 225 have the property. It is possible to display a state in which the side D side corresponding to the moving end, which is the moving end of the meter 241, is missing in accordance with the point. Compared with the case where UV coordinate conversion is performed and the meter texture 281 is applied to the meter projection area 251 by UV mapping, the meter 241 that is missing from the side D corresponding to the moving end is displayed. It is possible to reduce the processing load.

In order to display the meter 241 by selecting the parallel projection mapping as the method of applying the meter texture 281 to the meter projection area 251, since the five meters 241a to 421e having different lengths are displayed in the meter display effect. The processing load of can be effectively reduced.

The side E corresponding to the fixed end of the meter texture 281 corresponds to the side C corresponding to the fixed end of the meter object 261, and the side F corresponding to the moving end of the meter texture 281 becomes a line segment of another object. By performing the parallel projection mapping of the meter texture 281 in a corresponding manner, the meter texture 281 can be applied to the meter projection area 251 in a manner in which the length of the meter 241 other than the length in the longitudinal direction does not change. When the frames 231a to 231e are displayed, the side B on the moving end side of the frame object 231 is used to specify the range in which the meter texture 281 is projected in parallel. Even if the reduction is performed, the range in which the meter texture 281 is projected can be defined regardless of the position of the side D corresponding to the moving end of the meter object 261. Further, as compared with the case where a dedicated object is separately set to set the projection range of the meter texture 281, the data capacity of the object stored in the memory module 133 in advance can be reduced and the processing performed in real time can be performed. The load can be reduced.

When the frames 231a to 231e are not displayed, the blank object 291 is used to specify the range in which the texture 281 for the meter is projected in parallel, so that the meter object 261 can be reduced in the longitudinal direction. The range in which the meter texture 281 is projected can be defined regardless of the position of the side D corresponding to the moving end of the meter object 261. Since the blank object 291 is a one-dimensional object including two vertices and a line segment connecting the two vertices, the meter texture 281 can be applied to the meter object 261 with a small data capacity. Since the transparency information of complete transparency is set in the blank object 291, the projection range of the meter texture 281 can be defined without changing the display mode of the meter 241.

The number of the frame object 231, the meter object 261, and the blank object 291 stored in the memory module 133 is set to 1, and the VDP 135 sets the frame object 231, the meter object 261, and the blank object 291 to the addresses stored therein. The frame object 231, the meter object 261, and the blank object 291 are set a plurality of times in the world coordinate system by accessing a plurality of times. Further, the number of the meter textures 281 stored in the memory module 133 is set to one, and the VDP 135 accesses the address where the meter textures 281 are stored a plurality of times to project the projection areas 251 of the plurality of meter objects 261. The texture 281 for the meter is applied to. In the configuration, at the update timing, the lengths of the five meters 241 can be individually changed by reducing the meter object 261 in the longitudinal direction according to the points owned by the characters 221 to 225. Compared with the configuration in which the objects and textures for displaying the five meters 241 are stored for each meter 241, the data capacity of the objects and textures stored in advance can be minimized.

<Another form of meter display production>
In the configuration for executing the above-described meter display effect, the content of the meter texture 281 is not limited to the number of points owned by the characters 221 to 225. For example, the meter texture 281 composed of five areas of different colors may be used, and the number of displayed areas may be reduced each time the points owned by the characters 221 to 225 decrease. Specifically, in the initial state, five regions having different colors are displayed, and when one point is reduced, the displayed region is reduced by one and four regions having different colors are displayed. As a result, it is possible to easily display that the points owned by the characters 221 to 225 have decreased.

Further, in the display of the meter 242 that does not display the frames 231a to 231e, the display mode of the blank corresponding region 256 is not limited to the mode of displaying the background image with the blank corresponding region 256 being completely transparent. For example, the blank corresponding area 256 may be displayed as a black area.

Specifically, in the projection data created by projecting the meter object 261 and the blank object 291, the area in which the side D corresponding to the moving end of the meter object 261 is projected and the blank object 291 are projected. Black color information is set for all the dots included in the area sandwiched between the area and the area. As a result, the amount of decrease in the points owned by the characters 221 to 225 can be displayed by the area of the black region, and the amount of change from the initial state can be displayed to the player in an easily understandable manner.

The size of the meter object 261 in the initial state is not limited to the maximum size of the meter object 261 set in the world coordinate system in the meter display effect. For example, the size of the meter object 261 in the initial state may be the minimum size of the meter object 261 set in the world coordinate system in the meter display effect. By enlarging the meter object 261 according to the points owned by the characters 221-225, it is possible to display the meters 241a-241e of various lengths by using one meter object 261.

Further, in the parallel projection mapping of the meter texture 281, the timing of parallel projection of the meter texture 281 is not limited to after the meter object 261 is projected on the screen area PC12, and the meter texture 281 is displayed on the surface of the meter object 261. After the projection, the meter object 261 may be projected on the screen area PC12.

First, the case of the meter display effect of displaying the frames 231a to 231e will be described. The meter texture 281 is projected on the area defined by the side C on the fixed end side of the meter object 261 and the side B on the moving end side of the frame object 231 in the world coordinate system. Specifically, the side E on the fixed end side of the meter texture 281 is projected on the side C on the fixed end side of the meter object 261, and the meter texture 281 of the meter texture 281 is displayed on the side B on the moving end side of the frame object 231. The meter texture 281 is projected in parallel in a manner in which the side F on the moving end side is projected.

Next, a case of a meter display effect in which the frames 231a to 231e are not displayed will be described. The meter texture 281 is projected onto the area defined by the side C on the fixed end side of the meter object 261 and the blank object 291 in the world coordinate system. Specifically, the side E on the fixed end side of the meter texture 281 is projected on the side C on the fixed end side of the meter object 261, and the side F on the moving end side of the texture 281 for meter is projected on the blank object 291. In this manner, the meter texture 281 is projected in parallel.

When the meter texture 281 is projected in parallel, the VDP 135 sets one dot on the surface of the meter object 261 as a target dot. When there is one pixel of the meter texture 281 projected on the target dot, the color information and the transparency information set on the pixel are set on the target dot. When a plurality of pixels are projected on the target dot, color information and transparency information are selected, and color information and transparency information are set on the target dot. When there is no pixel projected on the target dot, the color information and the transparency information are complemented, and the color information and the transparency information are set on the target dot.

The target dot is updated until the setting of the color information and the transparency information for all the dots on the surface of the meter object 261 is completed. As a result, the color information and the transparency information of the meter texture 281 are set in all the dots on the surface of the meter object 261.

After that, the meter object 261 is projected on the screen area PC12. The color information and the transparency information set in the dots on the surface of the projected meter object 261 are set in the respective dots forming the meter projection area 251. Specifically, the VDP 135 sets one dot forming the meter projection area 251 as a target dot. When one dot on the surface of the meter object 261 is projected on the target dot, the color information and the transparency information set on the dot are set on the target dot. When a plurality of dots on the surface of the meter object 261 are projected on the target dot, the color information and the transparency information set for the dot having the largest area projected on the target dot are set as the target dot. Set to.

The target dot is updated until the setting of the color information and the transparency information is completed for all the dots forming the meter projection area 251. As a result, an image of the meter texture 281 is set in the meter projection area 251. At the start timing at which the longitudinal reduction of the meter object 261 is not performed, the entire image of the meter texture 281 is displayed without being deformed. Further, at the update timing when the meter object 261 is reduced in the longitudinal direction, a part of the image of the meter texture 281 is displayed without being deformed.

The configuration for performing partial display of the meters 241a to 241e, 242 is not limited to the configuration in which the meter object 261 is reduced in the longitudinal direction and set in the world coordinate system. For example, the blank object 293 may be used to perform partial display of the meters 241a to 241e, 242 without reducing the object.

FIG. 24A is an explanatory diagram for explaining the plate-shaped object 282 for displaying the frames 231a to 231e and the meters 241a to 241e. As shown in FIG. 24A, the plate-shaped object 282 is a rectangular plate-shaped polygon, and its two short sides are sides G and H. The plate-like object 282 is used to display the meters 241a to 241e that are missing from the side H to the side G. In the memory module 133, as a texture corresponding to the plate-like object 282, a framed meter texture 283 (FIG. 24(b)) capable of displaying the frames 231a to 231e and the meters 241a to 241e is stored. There is. Then, for each dot on the surface of the plate-like object 282, the position information of one pixel forming the framed meter texture 283 is set as the position information of the corresponding pixel.

FIG. 24B is an explanatory diagram for explaining the framed meter texture 283 applied to the projection area of the plate-like object 282. The framed meter texture 283 has a rectangular outer shape that is congruent with the plate-shaped object 282. The two short sides of the framed meter texture 283 are referred to as sides I and J. The framed meter texture 283 includes a frame area for displaying a frame and a meter area for displaying a meter. The meter area is rectangular and is located at the center of the framed meter texture 283. The numbers 1 to 5 are arranged in the meter area. Specifically, the number closest to the side I is 1, the number increases by 1 from the side I to the side J, and the number closest to the side J is 5. Red color information is set in the meter area, and gray color information is set in the frame area.

A side I of the framed meter texture 283 corresponds to a side G of the plate-shaped object 282, and a side J of the framed meter texture 283 corresponds to a side H of the plate-shaped object 282. Specifically, the position information of one pixel on the side I of the framed meter texture 283 is set to each dot on the side G of the plate object 282, and the side H of the plate object 282 is set. The position information of one pixel on the side J of the framed meter texture 283 is set to each dot above.

The plate object 282 is set in the world coordinate system at the start timing and each update timing. At the update timing when the points owned by the characters 221 to 225 are decreasing, the blank object 293 is set in the world coordinate system in addition to the plate-like object 282. Here, the blank object 293 is a one-dimensional object composed of two vertices and one line segment connecting the two vertices, and the length of the blank object 293 is the short side of the plate-like object 282. It is the same as the length of G and side H.

FIG. 24C is an explanatory diagram for explaining the plate-like object 282 and the blank object 293 set in the world coordinate system at the update timing. As shown in FIG. 24C, at each update timing, the blank object 293 is set to be parallel to the sides G and H of the plate-like object 282. Further, the blank object 293 is set in the area sandwiched by the side G and the side H of the plate-like object 282. The blank object 293 is an object for defining an area to be displayed in the framed meter texture 283. Specifically, in the framed meter texture 283, a part of the area on the side I side is a display target, and the remaining area on the side J side is not a display target.

At the start timing, the VDP 135 sets the entire framed meter texture 283 as a display target. On the other hand, at each update timing, the VDP 135 sets a part of the framed meter texture 283 as a display target. The display target is the portion applied to the area sandwiched between the side G of the plate-shaped object 282 and the blank object 293 in FIG.

FIG. 24D is an explanatory diagram for explaining a state in which the framed meter texture 283 is applied to the projection area of the plate object 282. First, the plate object 282 and the blank object 293 are projected on the screen area PC12 to create rectangular projection data. The projection data includes a projection area 294 where the plate-shaped object 282 is actually projected. Further, when the plate-shaped object 282 is projected on the screen area PC12, information on one dot of the plate-shaped object 282 projected on the dot is set to each dot forming the projection area 294 of the plate-shaped object 282. To be done. Then, the framed meter texture 283 is applied to the projection area 294 of the plate-like object 282 by UV mapping.

The VDP 135 sets one of the dots forming the projection area 294 of the plate-shaped object 282 as the target dot, and grasps one dot of the plate-shaped object 282 based on the information set in the target dot. Then, one color information is grasped based on the positional information of one pixel of the framed meter texture 283 set to the grasped dot of the plate object 282. Then, the grasped color information is set to the target dots forming the projection area 294 of the plate object 282. The target dot is updated until color information is set for all the dots forming the projection area 294 of the plate-like object 282. As a result, the framed meter texture 283 is applied to the projection area 294 of the plate-shaped object 282.

The method of applying the framed meter texture 283 to the projection area 294 of the plate-like object 282 is not limited to UV mapping. It is also possible to use parallel projection mapping and apply the framed meter texture 283 to the projection area 294 of the plate object 282. In this case, the side I of the framed meter texture 283 is projected onto the side G of the plate-shaped object 282, and the side J of the framed meter texture 283 is projected onto the side H of the plate-shaped object 282. Then, the framed meter texture 283 is projected in parallel onto the plate-like object 282.

After that, with respect to the projection area 294 of the plate-shaped object 282 to which the framed meter texture 283 is applied, the VDP 135 has the area 295 where the blank object 293 is projected and the area H where the side H of the plate-shaped object 282 is projected. A process of changing the color information set for all the dots included in the area sandwiched between the area 296 and 296 into the same gray color information as the frame area of the framed meter texture 283 is performed. Accordingly, the meter area of the framed meter texture 283 can be partially displayed.

FIG. 24E is an explanatory diagram for explaining a state in which a part of the meter area of the framed meter texture 283 is displayed in the projection area 294 of the plate-like object 282. As shown in FIGS. 24D and 24E, the meter area of the framed meter texture 283 applied to the projection area 294 of the plate object 282 is more plate-shaped than the area 295 onto which the blank object 293 is projected. Only the area 297 side on which the side G of the object 282 is projected is displayed. The area of the meter area to be displayed changes according to the position of the blank object 293 with respect to the sides G and H of the plate-like object 282.

At the update timing when the points owned by the characters 221 to 225 decrease, the blank object 293 is set to be shifted to the side G side of the plate-like object 282 so that the side J side is missing in the meter area of the framed meter texture 283. You can display how you are going. According to the length of the meters 241a to 241e to be displayed, the meter object 261 for displaying the meters 241a to 241e is reduced, and the frame object 231 for displaying the frames 231a to 231e and the meter 241a to Compared with the configuration in which the meter object 261 for displaying 241e and the meter object 261 are separately set in the world coordinate system, the processing load for performing partial display of the meter region can be reduced.

Further, the meters 241a to 241e displayed by the method are not limited to the meters 241a to 241e with the frames 231a to 231e, and the meter 242 without the frames 231a to 231e may be displayed by using the method. In this case, as the texture corresponding to the plate-like object 282, the frameless meter texture 284 including only the meter area is used. FIG. 24F is an explanatory diagram for explaining the frameless meter texture 284. The frameless meter texture 284 has a rectangular outer shape that is congruent with the plate-shaped object 282. The two short sides of the frameless meter texture 284 are defined as sides K and L. The numbers 1 to 5 are arranged on the frameless meter texture 284. Specifically, the number near the side K in the frameless meter texture 284 is 1, and the number increases by 1 from the side K to the side L. The numeral 5 is the closest number to the side L in the frameless meter texture 284.

By using the frame-less meter texture 284, it is possible to perform partial display of the meter 242 without reducing the meter object 261 for displaying the meter 242 according to the length of the meter 242.

In the configuration for executing the above-described meter display effect, the target displayed by using the meters 241a to 241e is not limited to the points owned by the characters 221 to 225. For example, a time limit may be set and an effect of displaying the remaining time using the meter 241 may be executed.

<Structure for executing ball display effect>
Next, a configuration for executing the ball display effect will be described.

The sphere display effect is an effect of stereoscopically displaying the sphere 341 using the simplified version object 321. Here, the simplified version object 321 is a three-dimensional object having a simplified structure of a hemispherical three-dimensional object composed of many vertices and many polygons. The simplified version object 321 is composed of fewer vertices and fewer polygons than a hemispherical three-dimensional object.

The ball display effect is performed as an effect for informing the player of the degree of expectation of a big hit. In the sphere display effect, the viewpoint PC 11 is switched to display the sphere 341 viewed from various angles. The timing at which the viewpoint PC 11 is switched is predetermined according to the expectation of the big hit. In the low-anticipation effect where the jackpot expectation is low, the viewpoint PC 11 is switched at regular intervals. On the other hand, in the high-expectation effect in which the expectation of the jackpot is high, the interval at which the viewpoint PC 11 is switched becomes shorter with the passage of time. The player can grasp the expectation degree of the jackpot by seeing whether or not the switching speed of the viewpoint PC 11 changes.

In the sphere display effect, the VDP 135 creates sphere drawing data 341a and 341b, which are drawing data for displaying the sphere 341, as drawing data for effect. FIG. 25A is an explanatory diagram for explaining the sphere drawing data 341a when the viewpoint PC11 is set above the sphere 341 to be displayed. Further, FIG. 25B is drawing data 341b for a sphere when the viewpoint PC11 is set to the side of the sphere 341 to be displayed. The sphere 341 is always displayed in a form having a circular outer shape regardless of the position where the viewpoint PC11 exists in the world coordinate system. Even if the relative relationship between the sphere 341 and the viewpoint PC11 in the world coordinate system changes, the outer shape of the sphere 341 displayed on the display surface G is circular and does not change. On the other hand, the pattern of the sphere 341 displayed on the display surface G changes according to the position of the sphere 341 in the world coordinate system, the position of the viewpoint PC11, and the orientation of the viewpoint PC11.

In the sphere display effect, the sphere 341 is displayed using the simplified version object 321 (FIGS. 26A and 26E) and the sphere display texture (FIGS. 28B and 28D). FIG. 26A shows a perspective view of the simplified version object 321. The simplified version object 321 is a three-dimensional object that is convex upward. The simplified version object 321 is hollow and has a structure that opens downward. When the viewpoint PC11 is set above the simplified version object 321 and the simplified version object 321 is projected onto the screen area PC12, the outline of the projection area of the simplified version object 321 becomes substantially circular. The detailed structure of the simplified version object 321 will be described below.

FIG. 26B is an explanatory diagram for explaining the positional relationship of the first vertex 331 a, which is one of the three types of vertices forming the simplified object 321. In FIG. 26B, a regular twenty square 331 is shown. The twenty-four vertices forming the regular quadrilateral 331 are referred to as first vertices 331a, and the center of the regular quadrilateral 331 is referred to as a first center 331b. Here, the first center 331b is the center of the circumscribing circle of the regular quadrangle 331. FIG. 26C is an explanatory diagram for explaining the positional relationship of the second vertex 332a, which is one of the three types of vertices that make up the simplified version object 321. A regular dodecagon 332 is shown in FIG. The twelve vertices forming the regular dodecagon 332 are the second vertices 332a, and the center of the regular dodecagon 332 is the second center 332b. Here, the second center 332b is the center of the circumscribed circle of the regular dodecagon 332. The diameter of the circumscribing circle of the regular dodecagon 332 is slightly smaller than the diameter of the circumscribing circle of the regular quadrilateral 331. Specifically, the diameter of the circumscribed circle of the regular dodecagon 332 is 95% of the diameter of the circumscribed circle of the regular quadrilateral 331.

FIG. 26D is an explanatory diagram for explaining the positional relationship between the three types of vertices 331a, 332a, 333 that form the simplified version object 321. In a virtual three-dimensional space, a first center 331b of a regular quadrilateral 331 is used as a starting point, a line segment perpendicular to the regular quadrilateral 331 is drawn, and an end point of the line segment is a tip vertex 333. In a mode in which the second center 332b of the regular dodecagon 332 overlaps with one point on the line segment connecting the first center 331b and the tip apex 333, and the regular dodecagon 332 and the regular quadrilateral 331 are parallel to each other. A regular dodecagon 332 is arranged.

FIG. 26D is a side view of the regular twenty square 331, the regular dodecagon 332, and the tip apex 333 arranged in the virtual three-dimensional space. In the figure, a total of 37 of the 24 first vertices 331a forming the regular twenty-square 331, the twelve second vertices 332a forming the regular dodecagon 332, and one tip apex 333 are included. The vertices are arranged in a virtual three-dimensional space. The simplified version object 321 is composed of a plurality of plane polygons formed by connecting the 37 vertices with line segments. Here, the direction from the first center 331b to the tip apex 333 is defined as the upper side of the simplified version object 321. A straight line passing through the first center 331b and the tip apex 333 is set as the central axis 336 of the simplified version object 321.

Next, a plurality of plane polygons forming the simplified object 321 will be described with reference to FIG. FIG. 26E is a side view of the simplified version object 321. First, of the 37 vertices arranged in the virtual three-dimensional space, the adjacent second vertices 332a are connected by 12 line segments. Then, twelve second vertices 332a and one tip apex 333 are connected by twelve line segments. Twelve first plane polygons 334 are formed by a total of 24 line segments. The shape of the first plane polygon 334 is an isosceles triangle having one tip vertex 333 and two second vertexes 332a adjacent to each other as vertices.

Next, for the twelve second vertices 332a, the second vertex 332a and one first vertex 331a closest to the second vertex 332a are connected by a line segment. Then, each second vertex 332a and the two first vertices 331a second closest to the second vertex 332a are connected by a line segment. Further, adjacent first vertices are connected by 24 line segments. As a result, 36 second plane polygons 335 are newly formed. The simplified version object 321 is a three-dimensional object composed of 12 first plane polygons 334 and 36 second plane polygons 335.

As shown in FIG. 26E, the inclination of the first plane polygon 334 and the inclination of the second plane polygon 335 are different. Specifically, the inclination of the first plane polygon 334 near the tip vertex 333 with respect to the screen area PC12 is gentle, and the inclination of the second plane polygon 335 far from the tip vertex 333 with respect to the screen area PC12 is steep. For this reason, the pattern located on the first plane polygon 334 is displayed wide, and the pattern located on the second plane polygon 335 is displayed narrow, so that the sphere 341 can be displayed three-dimensionally.

The sphere 341 can be displayed by setting a spherical object having a smooth sphere structure in the world coordinate system. In this case, the projection data of the spherical object obtained by projecting the spherical object on the screen area PC12 does not change regardless of the relative relationship between the spherical object in the world coordinate system and the viewpoint PC11. In the projection data, the projection area, which is the area where the spherical object is actually projected, is always circular.

However, a spherical object having a smooth sphere structure has a large amount of data because it has many vertices and many polygons. Therefore, by using the spherical object, the data capacity of the object stored in advance in the memory module 133 increases and the processing load for displaying the sphere 341 also increases. On the other hand, as shown in FIG. 26F, by displaying the sphere 341 using the hemispherical object 311 having a smooth hemisphere structure, the number of vertices of the object for displaying the sphere 341 and The number of polygons can be halved.

Further, by displaying the sphere 341 by using the simplified version object 321 (FIGS. 25A and 25B) having a structure in which the vertices of the hemispherical object 311 are thinned, the object for displaying the sphere 341 has. The number of vertices and the number of polygons can be further reduced. Specifically, by changing from the hemispherical object 311 to the simplified version object 321, the number of vertices is reduced from 241 to 37, and the number of polygons is reduced from 240 to 48. As a result, the data capacity of the object stored in advance in the memory module 133 can be reduced and the processing load for displaying the sphere 341 can be reduced as compared with the case of using the spherical object.

FIG. 27A is a front view of the simplified version object 321. The outer shape of the front view of the simplified version object 321 is substantially circular. However, the outer shape of the perspective view (FIG. 26A) of the simplified version object 321 is not substantially circular. Further, the outer shape of the side view (FIG. 26E) of the simplified version object 321 is not substantially circular. When the simplified version object 321 is projected on the screen area PC12, the projection angle at which the outline of the projection area of the simplified version object 321 is substantially circular is limited.

The sphere 341 to be displayed has a circular outer shape when viewed from any angle. That is, in order to display the sphere 341 using the simplified version object 321, the outline of the projection area of the simplified version object 321 needs to be substantially circular. By keeping the projection angle of the simplified version object 321 at an angle at which the projection area of the simplified version object 321 is substantially circular, it is possible to display the sphere 341 using the simplified version object 321. A method for setting the simplified version object 321 in the world coordinate system in such a manner that the projection area of the simplified version object 321 is substantially circular at the start timing and each update timing will be described below.

The memory module 133 stores a parameter table of the simplified version object 321 for setting the simplified version object 321 in the world coordinate system. The parameter table of the simplified version object 321 stored in the memory module 133 is a parameter table for high-expectancy effect and a parameter table for low-expectancy effect. Since the timing of switching the viewpoint PC 11 is different between the high expectation effect and the low expectation effect, the contents of the parameter table are different. The display CPU 131 reads one parameter table based on the data table at the start timing.

In the parameter table of the simplified version object 321, pointer information corresponding to each of the start timing, the update timing at which the parameter of the simplified version object 321 changes, and the update timing at which the parameter of the viewpoint PC 11 changes are set. A parameter for setting the simplified version object 321 in the world coordinate system is set in each of the pointer information. Here, the parameters of the simplified version object 321 include the coordinates of the tip vertex 333 in the world coordinate system, the rotation angle of the simplified version object 321, and the scale of the simplified version object 321.

At the start timing and each update timing, the display CPU 131 refers to the parameter table of the simplified version object 321, grasps the parameters of the simplified version object 321, and sets them in the drawing list. The parameters set in the parameter table of the simplified version object 321 are parameters for setting the simplified version object 321 in the world coordinate system such that the outline of the projection area of the simplified version object 321 is substantially circular at each timing. Is.

The relation between the simplified version object 321 and the screen area PC12 in the world coordinate system is that the coordinate of the simplified version object 321 changes, the coordinate of the viewpoint PC11 changes, and the rotation angle of the viewpoint PC11 changes. Each changes.

FIG. 27B is an explanatory diagram for explaining the relationship between the simplified version object 321 and the screen area PC12. The parameters of the simplified version object 321 are set so that the screen area PC12 is always located above the simplified version object 321. The parameters of the simplified version object 321 are always set such that the central axis 336 of the simplified version object 321 and the screen area PC12 are orthogonal to each other. Therefore, when the simplified version object 321 is projected onto the screen area PC12, the outline of the projection area of the simplified version object 321 is always kept substantially circular, and the sphere 341 can be displayed.

Next, the sphere display texture 342 (FIGS. 28B and 28D) is applied to the projection area of the simplified version object 321, and the sphere drawing data 341a and 341b (FIGS. 25A and 25B). A method of creating the will be described. As shown in FIGS. 25A and 25B, the surface of the sphere 341 to be displayed is patterned. In order to display the pattern, the sphere display texture 342 existing in the UV coordinate system is applied to the projection area of the simplified object 321 by UV mapping.

The corresponding UV coordinate value is set for each dot on the surface of the simplified version object 321. Further, the projection of the simplified version object 321 onto the screen area PC12 is performed in such a manner that the dot information on the surface of the simplified version object 321 projected on each dot in the projection area of the simplified version object 321 can be grasped. Since the size of the screen region PC12 is the same as the size of the display surface G of the symbol display device 31, the size of the projection data of the simplified version object 321 is also the same as the size of the display surface G of the symbol display device 31.

The VDP 135 grasps dot information on the surface of the simplified version object 321 corresponding to each dot in the projection area of the simplified version object 321, and grasps the coordinate value of UV coordinates corresponding to the dot on the surface of the simplified version object 321. Then, the color information set to the coordinate value of the sphere display texture 342 existing in the UV coordinate system is set to each dot in the projection area of the simplified version object 321. As a result, the sphere display texture 342 is applied to the projection area of the simplified version object 321.

A configuration in which the mode for applying the sphere display texture 342 to the projection area of the simplified version object 321 is not changed at the timing when the parameter of the simplified version object 321 in the world coordinate system is changed or when the parameter of the viewpoint PC 11 is changed. Then, the same pattern is displayed in the effect of viewing the sphere 341 to be displayed from any angle. Such a display is unnatural and gives the player a feeling of strangeness. On the other hand, at the timing when the parameters of the simplified object 321 in the world coordinate system are changed or the parameters of the viewpoint PC 11 are changed, the projection area of the simplified object 321 is changed according to the change in the relative relationship. By shifting the corresponding range of the sphere display texture 342 to be applied as a result, it is possible to display how the pattern of the sphere 341 changes.

28A shows the positional relationship between the simplified version object 321 and the viewpoint PC 11 at the start timing, and FIG. 28B shows the sphere display texture 342 applied to the projection area of the simplified version object 321 at the start timing. The corresponding range is shown. As shown in FIG. 28A, at the start timing, the simplified version object 321 is set in front of the viewpoint PC 11.

As shown in FIG. 28B, the sphere display texture 342 is set in a UV coordinate system different from the world coordinate system. The sphere display texture 342 has a square shape. One side of the square is on the u-axis and the other side is on the v-axis. The side on the u axis and the side on the v axis are orthogonal to each other. At the start timing, the coordinates of the four vertices of the sphere display texture 342 are (0,0), (1,0), (1,1), and (0,1). At the start timing, the projection area of the simplified object 321 is applied with a range surrounded by a circle having a radius of 0.25 centered on a point having coordinates (0.5, 0.5) in the UV coordinate system. It

At the update timing when the coordinates of the viewpoint PC11 in the world coordinate system move from the source to the destination, the simplified version object 321 rotates so that the destination viewpoint PC11 is located in front of the simplified version object 321. Then, the corresponding range of the sphere display texture 342 applied to the projection area of the simplified version object 321 is changed according to the rotation direction and the rotation amount of the rotation. Specifically, the direction in which the corresponding range is moved on the sphere display texture 342 is determined according to the rotation direction of the simplified version object 321, and the sphere display texture 342 is displayed according to the rotation amount of the simplified version object 321. Determines the amount to move in the corresponding range. Regarding the movement amount of the corresponding range, the rotation amount of the simplified version object 321 and the movement amount of the corresponding range have a one-to-one correspondence, and as the rotation amount of the simplified version object 321 increases, the movement amount of the corresponding range is linear. It is decided by the mode of increasing to.

The change of the corresponding range is performed by converting the UV coordinates of the sphere display texture 342. The UV coordinate conversion of the sphere display texture 342 is performed based on the coordinate conversion table stored in the memory module 133. The memory module 133 stores a coordinate conversion table for high-expectancy effect and a coordinate conversion table for low-expectancy effect. Since the timing at which the viewpoint PC 11 is switched is different between the high-expectation effect and the low-expectation effect, the coordinate conversion timing is also different. The display CPU 131 reads one coordinate conversion table based on the data table.

The coordinate conversion table of the sphere display texture 342 has pointers corresponding to the update timing at which the coordinates of the viewpoint PC 11 change, the update timing at which the orientation of the viewpoint PC 11 changes, and the update timing at which the coordinates of the simplified object 321 change. Information is set. A movement amount for moving the UV coordinates of the sphere display texture 342 in the u-axis direction and a movement amount for moving the UV coordinates in the v-axis direction are set in each of the pointer information.

The display CPU 131 refers to the coordinate conversion table and sets the movement amount in the u-axis direction and the movement amount in the v-axis direction in the drawing list. The VDP 135 performs UV coordinate conversion of the sphere display texture 342 based on the two movement amounts set in the drawing list, and then applies the sphere display texture 342 to the simplified object 321. As a result, it is applied to the projection area of the simplified version object 321 at the update timing at which the coordinates of the viewpoint PC 11 change, the update timing at which the orientation of the viewpoint PC 11 changes, and the update timing at which the coordinates of the simplified version object 321 change. The corresponding range of the sphere display texture 342 changes and the pattern of the sphere 341 displayed changes. The simplified version object 321 and the sphere display texture 342 can be used to give the player the impression that the sphere 341 is displayed in three dimensions.

The coordinate conversion table is created at the design stage. First, at the update timing when the relationship between the simplified object 321 and the screen area PC12 changes, the coordinates and rotation angle of the viewpoint PC11 in the world coordinate system are determined. The screen area PC12 is located above the simplified version object 321, and the parameter for setting the simplified version object 321 in the world coordinate system is such that the central axis 336 of the simplified version object 321 is orthogonal to the screen area PC12. To be grasped.

From the rotation angle information included in the parameter of the simplified version object 321, the rotation direction and the amount of rotation of the simplified version object 321 from the initial state are grasped. From the rotation direction of the simplified version object 321, the direction in which the UV coordinate is moved is known in the UV coordinate conversion. In addition, the movement amount of the UV coordinates can be grasped from the radius of the sphere 341 and the rotation amount of the simplified version object 321 that are assumed at the design stage. Then, the movement amount in the u-axis direction and the movement amount in the v-axis direction in the UV coordinate conversion are grasped from the movement amount and the movement direction of the UV coordinate, and are set in the coordinate conversion table.

As an example, with respect to the update timing at which the viewpoint PC 11 moves from the front of the simplified version object 321 to the left side of the simplified version object 321 (the right side when viewed from the simplified version object 321, refer to FIGS. 28C and 28D). While explaining.

FIG. 28C shows the positional relationship between the simplified version object 321 and the viewpoint PC 11 at the update timing when the viewpoint PC 11 is switched, and FIG. 28D shows the projection area of the simplified version object 321 at that timing. The corresponding range of the applied sphere display texture 342 is shown. As shown in FIG. 28C, the simplified version object 321 rotates clockwise this time. In this case, as shown in FIG. 28D, the range of the sphere display texture 342 applied to the projection area of the simplified version object 321 moves to the left (the negative direction of the u axis). The moving distance changes according to the rotation amount of the simplified version object 321. With the clockwise rotation of the simplified version object 321, the range of the sphere display texture 342 applied to the projection area of the simplified version object 321 is 0. to the left side (negative direction of the u axis) in the UV coordinate system. The case of moving 25 times will be described with reference to FIG.

The UV coordinates corresponding to each dot on the surface of the simplified version object 321 are set, and the UV coordinates do not change even if the viewpoint PC11 is changed. That is, the coordinate range of the sphere display texture 342 applied to the projection area of the simplified version object 321 has a radius of 0.25 centered on a point having coordinates (0.5, 0.5) in the UV coordinate system. The area surrounded by the circle does not change. Therefore, by converting the UV coordinates of the sphere display texture 342, the range of the sphere display texture 342 applied to the projection area of the simplified object 321 is changed.

When the range of the sphere display texture 342 applied to the projection area of the simplified object 321 moves 0.25 in the negative direction of the u axis in the UV coordinate system, the entire sphere display texture 342 in the UV coordinate system. , UV coordinate conversion is performed in a manner of 0.25 translation in the positive direction of the u-axis.

Specifically, the coordinates of the vertex that was (0,0) changed to (0.25,0), and the coordinates of the vertex that was (1,0) changed to (1.25,0). To do. Further, the coordinates of the vertex that was (0, 1) change to (0.25, 1), and the coordinates of the vertex that was (1, 1) change to (1.25, 1). On the other hand, since the coordinate range of the sphere display texture 342 applied to the projection area of the simplified object 321 is constant, the pattern drawn in the coordinate range changes. As a result, it is possible to display how the pattern of the sphere 341 changes as the parameters of the viewpoint PC 11 change.

The VDP 135 creates drawing data for effects and symbols in the drawing data creation process for effects and symbols in step S710 of the drawing process (FIG. 13). In detail, the drawing data 341a, 341b for the sphere and the drawing data for the symbol display, which are individually created, are lined up on the back side while the drawing data 341a, 341b for the ball are lined up on the back side. Writing to the screen buffer 144 in a mode creates drawing data for effects and symbols.

Further, the VDP 135 sets the background drawing data and the effect and design drawing data individually written in the screen buffer 144 in the drawing data combining process in step S711 of the drawing process (FIG. 13) to the background. The drawing data for one line is created on the back side, and the drawing data for the effect and the pattern is written on the front side for writing in the frame areas 142a and 142b to be drawn, thereby creating one frame of drawing data. It should be noted that each drawing data has the same outer shape, and the number of pixels forming each drawing data is also the same.

In the case of creating drawing data for effects and patterns and in the case of creating drawing data for one frame, if the pixel for which drawing is executed is set to the α value of complete transparency, the back side When the semi-transparent α value is set, the color information of the image is used as it is, and the color information of the image on the back side and the color information of the image on the front side are blended at a ratio based on the α value. When the opaque α value is set, the color information of the image on the back side is overwritten with the color information of the image on the back side. As a result, the image of the sphere 341 is displayed as an effect image at a position on the front side of the background image and on the back side of the design image.

Hereinafter, a specific processing configuration for executing the ball display effect will be described. FIG. 29 is a flowchart showing the calculation processing for ball display effect executed by the display CPU 131. The calculation process for the ball display effect is activated when the data table corresponding to the game time in which the ball display effect is executed is set.

First, in step S1301, it is determined based on the currently set data table whether or not the ball display effect is being executed. When the ball display effect is not being executed (step S1301: NO), it is determined in step S1302 whether or not it is the start timing of the ball display effect. If it is not the start timing (step S1302: NO), this operation processing is ended as it is, and if it is the start timing (step S1302: YES), the process proceeds to step S1303.

In step S1303, the parameter table of the simplified version object 321 is read based on the currently set data table. When the high expectation effect is performed, the parameter table for the high expectation effect is read, and when the low expectation effect is performed, the parameter table for the low expectation effect is read. In step S1304, the coordinate conversion table for converting the UV coordinates of the sphere display texture 342 is read based on the currently set data table. When the high-expectancy effect is performed, the coordinate conversion table for the high-expectancy effect is read, and when the low-expectation effect is performed, the coordinate conversion table for the low-expectancy effect is read.

In step S1305, the use instruction information of the simplified version object 321 is stored based on the currently set data table, and the world is referred by referring to the parameter table of the simplified version object 321 already read in step S1306. Understand the parameters this time in the coordinate system. Here, the parameters include the coordinates, the rotation angle, and the scale of the simplified object 321.

In step S1307, the use instruction information of the sphere display texture 342 is stored based on the currently set data table, and in step S1308, the start designation information is stored and the present arithmetic processing ends. When the calculation process for the sphere display effect is executed as described above, the drawing list created in the subsequent drawing list output process includes the usage instruction information of the simplified version object 321 and the usage instruction of the sphere display texture 342. Information is set. Further, parameters for setting the simplified object 321 in the world coordinate system and start designation information are also set.

When the ball display effect is being performed (step S1301: YES), in step S1309, the use instruction information of the simplified version object 321 is stored based on the currently set data table, and in step S1310, the current state is displayed. Based on the set data table, the use instruction information of the sphere display texture 342 is stored. In a succeeding step S1311, it is determined based on the currently set data table whether or not it is the update timing at which the parameter of the simplified object 321 or the parameter of the viewpoint PC 11 changes.

If it is the update timing when the parameter of the simplified version object 321 or the parameter of the viewpoint PC 11 changes (step S1311: YES), based on the parameter table of the simplified version object 321 already read in step S1312, The parameters of the simplified version object 321 are updated. In step S1313, the parameter for performing the UV coordinate conversion of the sphere display texture 342 is updated based on the already read coordinate conversion table. Here, the parameters for coordinate conversion are the amount of movement of the sphere display texture 342 in the u-axis direction and the amount of movement in the v-axis direction.

In step S1314, coordinate conversion instruction information for causing the VDP 135 to execute the process of converting the UV coordinates of the sphere display texture 342 is stored, and in step S1315, the update designation information is stored and the present arithmetic processing ends. When the calculation process for the sphere display effect is executed as described above, the drawing list created in the subsequent drawing list output process includes the usage instruction information of the simplified version object 321 and the usage instruction of the sphere display texture 342. Information is set. Further, a parameter for setting the simplified object 321 in the world coordinate system, a parameter for performing UV coordinate conversion of the sphere display texture 342, coordinate conversion instruction information, and update designation information are set.

If it is not the update timing when the parameter of the simplified version object 321 or the parameter of the viewpoint PC 11 changes (step S1311: NO), the parameter of the simplified version object 321 stored in the work RAM 132 is grasped in step S1316. In a succeeding step S1317, it is determined whether or not the coordinate conversion of the sphere display texture 342 is performed based on the currently set data table. The coordinate conversion of the sphere display texture 342 is performed when the rotation angle or scale for setting the simplified version object 321 in the world coordinate system is not the same as the initial value. When performing coordinate conversion (step S1317: YES), the parameter of the coordinate conversion stored in the work RAM 132 is grasped in step S1318, and the coordinate conversion instruction information is stored in step S1319.

After making a negative determination in step S1317 or after step S1319, in step S1320, the update designation information is stored and the present arithmetic processing ends. When the calculation process for the sphere display effect is executed as described above, the drawing list created in the subsequent drawing list output process includes the usage instruction information of the simplified version object 321 and the usage instruction of the sphere display texture 342. Information is set. Further, parameters for setting the simplified version object 321 in the world coordinate system and update designation information are set. Further, when it is determined that it is the update timing at which the coordinate conversion is performed, the coordinate conversion parameter and the coordinate conversion instruction information are set in the drawing list.

Next, FIG. 30 shows the simplified object setting process executed by the VDP 135.
A description will be given with reference to (a). The simplified version object setting process is executed in the rendering setting process in step S703 of the drawing process (FIG. 13). Further, the simplified version object setting process is started when the start designation information or the update designation information of the sphere display effect is set in the drawing list.

First, in step S1401, the address where the simplified version object 321 is stored in the memory module 133 is grasped based on the drawing list this time, and the simplified version object 321 is read. In step S1402, a parameter for setting the simplified version object 321 in the world coordinate system is grasped based on the current drawing list.

In step S1403, the simplified version object 321 is set in the world coordinate system based on the parameters grasped in step S1402. The simplified version object 321 is always set above the simplified version object 321, and the screen area PC12 is set in the world coordinate system in such a manner that the central axis 336 of the simplified version object 321 and the screen area PC12 are orthogonal to each other. In this case, the simplified version object 321 is projected from the front onto the screen area PC12. As shown in FIG. 27A, the outer shape of the front view of the simplified version object 321 is substantially circular. By making the outline of the projection area of the simplified version object 321 always substantially circular, it is possible to give the player the impression that the sphere 341 is three-dimensionally displayed.

Next, the sphere display texture application processing executed by the VDP 135 will be described with reference to FIG. The sphere display texture application process is executed in the rendering and design drawing data creation process in step S710 of the drawing process (FIG. 13). The sphere display texture applying process is activated when the sphere display effect start designation information or the sphere display effect update designation information is set in the drawing list.

In step S1501, the simplified version object 321 set in the world coordinate system is projected onto the screen area PC12, and projection data of the simplified version object 321 is created. The projection data includes a substantially circular projection area on which the simplified version object 321 is actually projected. The projection of the simplified version object 321 onto the screen area PC12 is performed in a manner that the information on the dots on the surface of the simplified version object 321 projected on each dot of the screen area PC12 can be grasped. Specifically, for each dot in the projection area, information of one dot on the surface of the simplified version object 321 projected on the dot is set. When a plurality of dots on the surface of the simplified version object 321 are projected onto one dot in the projection area, among the plurality of dots of the simplified version object 321, the dot with the largest area projected on the dot in the projection area is displayed. Information is set for the dots in the projection area. As a result, information on one dot on the surface of the simplified object 321 is set for each dot in the projection area.

In step S1502, the address where the sphere display texture 342 is stored in the memory module 133 is grasped based on the drawing list this time, and the sphere display texture 342 is read. Then, in step S1503, it is determined whether or not the coordinate conversion instruction information is set in the drawing list this time. When the coordinate conversion instruction information is set in the drawing list this time (step S1503: YES), in step S1504, the UV coordinates of the sphere display texture 342 are converted based on the drawing list this time. Understand the parameters. Specifically, in the conversion of UV coordinates, the amount of movement of the sphere display texture 342 in the u-axis direction and the amount of movement in the v-axis direction are grasped. Then, in step S1505, coordinate conversion of the sphere display texture 342 is executed based on the parameters grasped in step S1504.

Specifically, in the coordinate conversion of the sphere display texture 342, when the entire sphere display texture 342 moves a in the positive direction of the u axis and moves b in the positive direction of the v axis, the sphere in the UV coordinates. While a is added to the u component of each coordinate of the display texture 342, b is added to the v component. Here, a and b are real variables.

Since the coordinate range of the sphere display texture 342 applied to the projection area of the simplified version object 321 is always constant, it is set in the projection area of the simplified version object 321 by performing coordinate conversion of the sphere display texture 342. Pattern changes. Specifically, by performing coordinate conversion of the sphere display texture 342, the sphere display texture 342 is moved a in the negative direction of the u axis from the original coordinate range and at the same time in the negative direction of the v axis. The pattern of the place moved to b is set in the projection area of the simplified version object 321.

In step S1506, the sphere display texture 342 is applied to the projection area of the simplified version object 321, and this application processing ends. Here, the details of the process of applying the sphere display texture 342 to the projection area of the simplified version object 321 will be described. The VDP 135 sets one of the dots forming the projection area of the simplified object 321 as the target dot. The VDP 135 first grasps one dot on the surface of the simplified version object 321 set as the target dot, and grasps one UV coordinate value of the sphere display texture 342 set for the dot. Then, the color information set in the UV coordinate value in the sphere display texture 342 is grasped, and the color information is set in the target dot of the projection area of the simplified object 321. The target dot is updated until color information is set for all the dots forming the projection area of the simplified object 321. As a result, the color information of the sphere display texture 342 is set in the projection area of the simplified version object.

The UV coordinate value of one pixel of the sphere display texture 342 is set to the dot on the surface of the simplified version object 321. Since the UV coordinate value set for each dot does not change, the color information corresponding to each dot is the color information set at a fixed position in the UV coordinate system where the sphere display texture 342 exists. When the coordinate conversion of the sphere display texture 342 is not performed (step S1503: NO), the color information corresponding to each dot is constant. On the other hand, when the coordinate conversion of the sphere display texture 342 is performed (step S1503: YES), the color information set at the fixed position in the UV coordinate system in which the sphere display texture 342 exists changes. The color information set for each dot forming the projection area of the simplified object 321 also changes.

At the update timing when the parameter of the simplified version object 321 or the parameter of the viewpoint PC 11 changes, the pattern displayed in the projection area of the simplified version object 321 changes, giving the impression that the sphere 341 is stereoscopically displayed. Can be given to anyone.

As described above, in place of the spherical object having a large number of vertices and having a smooth spherical structure, the simplified version object 321 having a smaller number of vertices and polygons than the spherical object is used to stereoscopically form the sphere 341. By performing such display, it is possible to reduce the amount of data stored in advance in the memory module 133 and reduce the processing load for displaying the sphere 341.

In the simplified version object 321, the first plane polygon 334 near the tip apex 333 has a gentle inclination angle, and the second plane polygon 335 far from the tip apex 333 has a steep inclination angle. In the configuration, when the sphere display texture 342 is applied to the projection area of the simplified version object 321, the pattern located on the first plane polygon 334 is displayed wide and the pattern located on the second plane polygon 335 is narrow. The three-dimensional display of the sphere 341 is possible.

At the start timing and all the update timings, the simplified version object 321 is set to the world coordinate system in such a manner that the central axis 336 of the simplified version object 321 and the screen area PC12 are orthogonal to each other, so that the simplified version object 321 is in front. Is projected onto the screen area PC12, and the projection area of the simplified version object 321 becomes substantially circular. Since the projection area of the simplified version object 321 is substantially circular at all timings, the sphere 341 can be displayed using the simplified version object 321 having a small data capacity.

At the update timing when the coordinates of the simplified version object 321 in the world coordinate system change, the update timing when the coordinates of the viewpoint PC11 change, and the update timing when the orientation of the viewpoint PC11 changes, the parameters of the simplified version object 321 are set to the viewpoint PC11. In addition to the change, the UV coordinates of the sphere display texture 342 are coordinate-converted according to the change of the parameter of the simplified object 321. As a result, the projection area of the simplified version object 321 at the update timing at which the coordinates of the simplified version object 321 in the world coordinate system change, the update timing at which the coordinates of the viewpoint PC11 change, and the update timing at which the orientation of the viewpoint PC11 changes. The corresponding range of the sphere display texture 342 applied to is changed, and the pattern of the sphere 341 displayed on the display surface G of the symbol display device 31 is changed. It is possible to give the player the impression that the sphere 341 is three-dimensionally displayed.

<Another form of ball display production>
In the above-mentioned configuration for performing the sphere display effect, the display CPU 131 refers to the coordinate conversion table of the sphere display texture 342 for the method of grasping the parameters for the display CPU 131 to convert the UV coordinates of the sphere display texture 342. Then, it is not limited to the method of grasping the parameter for converting the UV coordinates of the sphere display texture 342. For example, the parameter for converting the UV coordinates of the sphere display texture 342 may be grasped according to the rotation angle for setting the simplified version object 321 in the world coordinate system.

Specifically, the correspondence relationship between the rotation angle for setting the simplified version object 321 in the world coordinate system and the parameter for converting the UV coordinates of the sphere display texture 342 is set in the memory module 133. The table is stored. The display CPU 131 grasps the rotation angle among the parameters of the simplified object 321 this time, and refers to the correspondence table to grasp the parameter for UV coordinate conversion. The memory module 133 is compared with a configuration in which a coordinate conversion table in which parameters for UV coordinate conversion are set is stored for all the timings at which the relationship between the simplified object 321 and the viewpoint PC 11 in the world coordinate system changes. The amount of data stored in advance can be reduced.

Further, the display of the sphere 341 using the simplified version object 321 is not limited to the display of the sphere 341 that does not move. For example, a state in which a spherical object, such as a tennis ball, having a pattern on its surface is rotated on the spot in a stationary state may be displayed.

By performing coordinate conversion in which the position of the texture in the UV coordinates is moved in a predetermined direction by a predetermined amount, it is possible to display how the spherical object rotates on the spot. When a spherical object having a spherical structure is rotated in the world coordinate system, since it is possible to display a state in which a spherical object rotates by only converting the UV coordinates of the texture without changing the orientation of the simplified version object 321. Compared with the above, it is possible to suppress the data capacity prestored in the memory module 133 and reduce the processing load.

Further, in the configuration in which the parameter for performing coordinate conversion of the sphere display texture 342 is changed according to the rotation angle for setting the simplified version object 321 in the world coordinate system, the rotation angle of the simplified version object 321 changes. The configuration is not limited to changing the parameters for performing coordinate conversion of the sphere display texture 342 at all timings. For example, at a timing when the rotation angle of the simplified version object 321 is within a certain range, common parameters for performing coordinate conversion of the sphere display texture 342 are used, and the rotation angle of the simplified version object 321 is within a certain range. At the exit timing, different parameters for performing coordinate conversion of the sphere display texture 342 may be used.

Specifically, the same parameter for performing coordinate conversion is set for a plurality of continuous rotation angles. When the viewpoint PC11 continuously moves from the start point to the end point, coordinate conversion of the sphere display texture 342 is performed using the same parameters until the movement amount of the viewpoint PC11 exceeds a certain amount, and the simplified object 321 is used. Display the same pattern in the projected area of. Then, when the amount of movement of the viewpoint PC 11 exceeds a certain amount, the parameter for performing coordinate conversion of the sphere display texture 342 is changed, and the pattern displayed in the projection area of the simplified object 321 is changed. The processing load for performing the sphere display effect can be reduced as compared with the configuration in which the parameter for performing the coordinate conversion of the sphere display texture 342 changes every time the viewpoint PC 11 moves.

Further, the same number of sphere display textures 342 as the types of rotation angles for setting the simplified version objects 321 in the world coordinate system may be used. The case where there is a first angle and a second angle as rotation angles for setting the simplified version object 321 in the world coordinate system will be specifically described.

The memory module 133 stores the first angle texture, which is image data of the surface of the sphere 341 to be displayed, and the simplified version object 321 at the timing when the simplified version object 321 is set in the world coordinate system at the first angle. At the timing set in the world coordinate system at the second angle, the second angle texture, which is image data of the surface of the sphere 341 to be displayed, is stored. Further, the memory module 133 enables the display CPU 131 to set the texture for the first angle in the drawing list at the timing when the simplified version object 321 is set in the world coordinate system at the first angle. A texture selection table that allows the display CPU 131 to set the texture for the second angle in the drawing list at the timing when the plate object 321 is set in the world coordinate system at the second angle is stored.

The display CPU 131 reads the texture selection table at the start timing, and sets the texture according to the rotation angle of the simplified version object 321 at the timing in the drawing list at each timing. Since each texture is applied to the projection area of the simplified version object 321, in one way, each texture can be created in accordance with the mode applied to the projection area of the simplified version object 321. it can. Therefore, as compared with the configuration in which the content of the image applied to the projection area of the simplified version object 321 is changed by changing the application range in one sphere display texture 342, a more three-dimensional sphere is obtained. 341 can be displayed.

In addition, the method of making the content of the high-expectation production different from the content of the low-expectation production differs from the timing of switching the viewpoint PC11 in the high-expectation production and the timing of switching the viewpoint PC11 in the low-expectancy production. It is not limited to the method of doing. For example, the memory module 133 stores a sphere display texture 342 for high-expectation performance and a sphere display texture 342 for low-expectation performance, and the sphere display texture 342 according to the type of performance to be performed. May be used. Since the surface pattern of the sphere 341 displayed in the high expectation effect is different from the surface pattern of the sphere 341 displayed in the low expectation effect, the player has a high expectation of a big hit by confirming the pattern. You can know whether or not.

In each of the high-expectation effect and the low-expectation effect, in a configuration in which the common sphere display texture 342 is used, the sphere display texture 342 to be applied to the projection area of the simplified object 321 at each timing of each effect. By setting the range to be different, the content of the high-expectancy effect may be different from the content of the low-expectancy effect.

The timing at which the viewpoint PC 11 is switched is not limited to the timing preset in the parameter table of the simplified object 321 and the coordinate conversion table of the sphere display texture 342. For example, the viewpoint PC 11 may be switched when the player operates the performance operation device 48.

In this case, the memory module 133 stores the parameter table of the simplified object 321 and the coordinate conversion table of the sphere display texture 342 by the number of switchable viewpoint PCs 11. Then, at the update timing immediately after the player operates the rendering operation device 48, the new parameter table of the simplified version object 321 and the new coordinate conversion table of the sphere display texture 342 are read. By switching the viewpoint PC 11 according to the player's operation, it is possible to encourage the player to actively participate in the ball display effect.

Further, the target displayed by using the object whose structure is simplified is not limited to the sphere 341. For example, a spheroid obtained by rotating the ellipse with the major axis or the minor axis of the ellipse as the axis of rotation may be the display target. The front, side and rear views of the spheroid have the same elliptical contour. In addition, the plan view and the bottom view of the spheroid have the same circular outer shape.

When the simplified version object 321 is projected onto the screen area PC12 orthogonal to the central axis 336 of the simplified version object 321, the projection area becomes substantially circular. In this case, when the simplified version object 321 is enlarged or reduced in one direction in a plane orthogonal to the central axis 336 of the simplified version object 321, the deformed simplified version object 321 has a substantially elliptical projection area.

Regarding the deformation of the simplified version object 321, in detail, the simplified version object 321 is arranged in a certain virtual three-dimensional space, and the central axes 336 of the simplified version objects 321 are parallel to the Z axis. Introduce the Y and Z axes. Then, the simplified version object 321 is deformed by enlarging or reducing it in one direction of the XY plane. For example, the simplified version object 321 is deformed by enlarging or reducing it in the X-axis direction. By this transformation, the projection area of the simplified version object 321 can be transformed into a substantially elliptical shape. In this manner, when the projection area is projected on the screen area PC12, a three-dimensional object having a substantially elliptical projection area is used to stereoscopically display a front view, a side view, and a rear view of a spheroid. You can

If a front view, a side view, or a rear view of the spheroid is displayed from the positional relationship between the viewpoint PC11 and the spheroid in the world coordinate system, the deformed simplified object 321 is set in the world coordinate system. A configuration in which the undeformed simplified object 321 is set in the world coordinate system when a plan view or a bottom view of the spheroid is displayed due to the positional relationship between the viewpoint PC11 and the spheroid in the world coordinate system. By doing so, it is possible to stereoscopically display the spheroid while reducing the processing load.

Further, the target displayed by using the object whose structure is simplified may be an object whose surface is composed of a curved surface and a flat surface. Specifically, a sphere may be connected to the tip of an elongated polygonal column, and a street lamp having a pattern drawn on the surface of the sphere may be the display target. In this case, instead of the simplified version object 321, a street light object in which the simplified version object 321 and the polygonal column object are connected is used. When the street light object is projected onto the screen area PC12 from one direction, the projection area of a portion having the same structure as the simplified version object 321 becomes substantially circular.

By changing the rotation angle for setting the street light object in the world coordinate system according to the movement of the viewpoint PC 11, the projection area of the portion having the same structure as the simplified version object 321 can be kept substantially circular. .. Further, when the rotation angle for setting the street light object to the world coordinate system is changed, it is displayed by changing the range of the texture applied to the projection area of the portion having the same structure as the simplified object 321. It is possible to display a street light in which the pattern on the surface of the sphere changes according to the angle of the light. Instead of using one street light object, the simplified object 321 and the polygonal prism object may be individually arranged in the world coordinate system.

The effect image is not limited to the image of the sphere 341 alone. As an effect image, an image of another object may be displayed together with the image of the spherical object. For example, an image of the earth may be displayed as an image of a spherical object, and an image of a rocket may be displayed as an image of another object.

The VDP 135 separately creates drawing data for displaying an image of the earth and drawing data for displaying an image of a rocket as drawing data for presentation. Then, the drawing data for displaying the image of the earth is lined up at the farthest side, the drawing data for the pattern is lined up at the foremost side, and the drawing data for displaying the image of the rocket is between the two drawing data. By writing the three drawing data in the screen buffer 144 in a manner arranged in line, the drawing data for the effect and the design are created.

Further, the configuration for setting the viewpoint PC11 when creating rendering data for presentation is not limited to the configuration for individually setting the viewpoint PC11 for each object set in the world coordinate system. For example, a single viewpoint PC11 may be commonly set for all objects set in the world coordinate system.

Specifically, the simplified version object 321 set in the world coordinate system and the object for displaying the rocket are projected on the same screen area PC12 to create projection data for presentation. By applying the texture for displaying the earth to the projection area of the simplified version object 321 in the projection data for rendering, and applying the texture for displaying the rocket to the projection area of the object for displaying the rocket. , Create drawing data for performance.

Compared to the configuration in which the viewpoint PC 11 is set individually for each object set in the world coordinate system, the number of times the object is projected is reduced, and one frame is drawn in the frame areas 142a and 142b to be drawn. When writing data, the number of drawing data to be written as drawing data for effects and symbols is reduced, so that the processing load for executing the ball display effect can be reduced.

Next, a configuration for displaying an image with a blurred frame will be described. In the pachinko machine 10, a cloud display effect of displaying a plurality of clouds 362a in a blurred frame and an image of the character 371 in which auras 412 to 417 are displayed around the cloud display effect as an effect of displaying a blurred image of the frame. And an aura display effect for displaying.

<Structure for performing cloud display>
First, a configuration for performing cloud display effect will be described.

The cloud display effect is executed as part of the effect of notifying the expectation degree of the jackpot. In the high-expectation effect in which the expectation of a big hit is high, a large number of clouds 362a are displayed in a blurred frame. Further, in the low-expectation effect in which the expectation of a big hit is low, a small number of clouds 362a are displayed in a blurred frame. In the cloud display effect, by switching the viewpoint PC 11, the cloud 362a viewed from below and the cloud 362a viewed from above are displayed at different timings. The switching of the viewpoint PC 11 is performed at a predetermined timing in the cloud display effect.

In the cloud display effect, as the effect image, there are a timing at which only the image of the cloud 362a is displayed and a timing at which the image of the cloud 362a and the image of the airplane are displayed. At the timing when the image of the cloud 362a and the image of the airplane are displayed, the drawing data 368 for cloud for displaying the image of the cloud 362a (FIG. 31(a)) and the drawing for airplane for displaying the image of the airplane. Data and data are created separately. The process of creating the cloud drawing data 368 will be described below. The plane drawing data is created by applying the texture for displaying the plane to the projection data of the object for displaying the plane.

FIG. 31A shows cloud drawing data 368 created to display an image of a cloud group with a blurred frame on the display surface G of the symbol display device 31. In the cloud display effect, cloud drawing data 368, which is image data in which a plurality of clouds 362a are arranged in a blurred frame, is created. The cloud drawing data 368 includes a cloud display object 361 (FIG. 31(b)), a cloud display texture 362 (FIG. 31(d)), a clipping object 364 (FIG. 32(a)), and blurring range data. Created using.

FIG. 31B shows a cloud display object 361. The cloud display object 361 is a polyhedral object composed of a plurality of polygons. Therefore, when the cloud display object 361 is set in the world coordinate system and projected onto the screen area PC12, the outer shape of the projection data becomes a polygon. The shape of the polygon changes depending on the relative positional relationship between the cloud display object 361 and the viewpoint PC11.

The cloud display object 361 is a polyhedron having symmetry. Specifically, the cloud display object 361 has three rotation axes 361b to 361d orthogonal to each other in the three-dimensional space. The cloud display object 361 has a property that when the cloud display object 361 is rotated 180° about each of the rotation axes 361b to 361d, the cloud display object 361 before and after the rotation overlaps. The three rotary shafts 361b to 361d intersect at one point. A point where the three rotation axes 361b to 361d intersect is defined as a center point 361a.

A parameter table of the cloud display object 361 is stored in the memory module 133. A plurality of pointer information is set in the parameter table. The pointer information corresponds to the timing of changing the parameter of the cloud display object 361 in the world coordinate system or the timing of changing the parameter of the viewpoint PC 11 in the world coordinate system. Here, the parameters of the cloud display object 361 include coordinates, a rotation angle, and a scale, and the parameters of the viewpoint PC 11 include coordinates and a direction. A parameter for setting the cloud display object 361 in the world coordinate system is set in each of the pointer information. The VDP 135 grasps the parameter by referring to the drawing list output by the display CPU 131, and sets the cloud display object 361 in the world coordinate system based on the parameter. Here, among the parameters set in the parameter table of the cloud display object 361, the coordinates of the cloud display object 361 are the coordinates of the center point 361a of the cloud display object 361.

FIG. 31C shows projection data 352 of the cloud display object 361. The VDP 135 creates the projection data 352 of the cloud display object 361 by projecting the cloud display object 361 set in the world coordinate system onto the screen area PC12. Here, when the object is projected on the screen area PC12, the entire data in which the shape of the screen area PC12 is reflected is used as the projection data, and the object is actually projected on the screen area PC12 to determine the shape of the object. The reflected area is the projection area. Since the size of the screen region PC12 is the same as the size of the display surface G of the symbol display device 31, the size of the projection data created is also the same as the size of the display surface G of the symbol display device 31. The projection data 352 of the cloud display object 361 includes a cloud display projection area 352a onto which the cloud display object 361 is projected, and a cloud display peripheral area 352b other than the cloud display projection area 352a.

FIG. 31D shows a cloud display texture 362 corresponding to the cloud display object 361. The memory module 133 stores a cloud display texture 362 in which a large number of clouds 362a are lined up as a texture for high-expectation effect, and a small number of clouds 362a are lined up as a texture for low-expectation effect. The cloud display texture 362 that is displayed is stored. The display CPU 131 grasps the cloud display texture 362 corresponding to the current game time from the two types of cloud display textures 362 based on the data table and sets it in the drawing list. Hereinafter, a case where the cloud display texture 362 for high-expectation performance is used will be described. The cloud display texture 362 is set in a UV coordinate system different from the world coordinate system. The cloud display texture 362 is applied to the projection data of the cloud display object 361.

Specifically, the UV coordinates of the corresponding cloud display texture 362 are set to each dot on the surface of the cloud display object 361. Further, the projection of the cloud display object 361 onto the screen area PC12 is performed in such a manner that the dot information on the surface of the cloud display object 361 projected on each dot of the cloud display projection area 352a can be grasped.

The VDP 135 grasps the dot information on the surface of the cloud display object 361 corresponding to each dot of the cloud display projection area 352a, and grasps the coordinate value of the UV coordinate corresponding to the dot on the surface of the cloud display object 361. .. Then, the color information set to the coordinate value of the cloud display texture 362 existing in the UV coordinate system is set to each dot of the cloud display projection area 352a. As a result, the cloud display texture 362 is applied to the projection data 352 of the cloud display object 361.

FIG. 31E shows the cloud display two-dimensional data 363 created by applying the cloud display texture 362 to the projection data of the cloud display object 361. In the cloud display two-dimensional data 363, transparency information (α value of “0”) of complete transparency is set in a region corresponding to the cloud display peripheral region 352b. Since the cloud display projection area 352a is an area formed by projecting the cloud display object 361 that is a polyhedron, the boundary 369 between the cloud display projection area 352a and the cloud display peripheral area 352b is composed of a plurality of line segments. It is square. The cloud display two-dimensional data 363 is an image in which the clouds 362 a are arranged inside the boundary 369.

When the two-dimensional data for cloud display 363 is displayed as it is on the display surface G of the symbol display device 31, the cloud 362 a displayed inside the boundary 369 has a complicated shape, whereas the boundary 369. Has a simple shape, which gives the player a feeling of strangeness. Therefore, the VDP 135, after creating the cloud display two-dimensional data 363, stores the cloud display two-dimensional data 363 separately for processing. Specifically, the cloud display two-dimensional data 363 is separately stored in the cloud display effect buffer provided in the screen buffer 144.

Next, a method of creating the projection data 351 of the clipping object 364 necessary for processing the cloud display two-dimensional data 363 will be described. As shown in FIG. 32A, the memory module 133 stores a clipping object 364 having the same shape as the cloud displaying object 361 and slightly smaller than the cloud displaying object 361.

The clipping object 364 has a structure obtained by reducing the cloud display object 361 to 80% with the center point 361a of the cloud display object 361 as the center of reduction. The point used as the center of reduction is the center point 364 a of the clipping object 364. The clipping object 364 has three rotation axes 364b to 364d orthogonal to each other in the three-dimensional space. The clipping object 364 has a property that when the clipping object 364 is rotated 180° about each of the rotation axes 364b to 364d, the clipping object 364 before and after the rotation overlaps. The three rotary shafts 361b to 361d intersect at a center point 364a.

The VDP 135 sets the clipping object 364 in the world coordinate system based on the same parameters as the cloud display object 361. Specifically, the same coordinates as the coordinates of the central point 361a of the cloud display object 361 are used as the coordinates of the central point 364a of the clipping object 364, and the cloud display is performed as the rotation angle for setting the clipping object 364. The same rotation angle as that for setting the object 361 for use is used. Also, as a reduction ratio or enlargement ratio when the clipping object 364 is reduced or expanded and set in the world coordinate system, a reduction ratio or enlargement when the cloud display object 361 is reduced or expanded and set in the world coordinate system. Use magnification.

The VDP 135 projects the clipping object 364 onto the screen area PC12 to create projection data 351 of the clipping object 364. The projection data 351 includes a clipping projection area 351a on which the clipping object 364 is projected, and a peripheral area 351b other than the clipping projection area 351a. After creating the projection data 351 of the clipping object 364, the VDP 135 sets “0” as the α value of all the dots forming the clipping projection area 351a, and the α of all the dots forming the peripheral area 351b. Set "1" as the value.

FIG. 32B shows the projection data 351 of the clipping object 364. The screen area PC12 onto which the cloud display object 361 is projected and the screen area PC12 onto which the clipping object 364 is projected have the same shape and the same size. Therefore, the same number of dots are arranged in each of the projection data 352 of the cloud display object 361 and the projection data 351 of the clipping object 364. Specifically, the same number of dots are arranged in the horizontal direction of the two projection data 351, 352, and the same number of dots are also arranged in the vertical direction of the two projection data 351, 352. Here, the relationship between the cloud display projection area 352a in the projection data 352 of the cloud display object 361 and the clipping projection area 351a in the projection data 351 of the clipping object 364 will be described.

The shape of the projection area is the outline of the object at the angle at which the object is projected. At each timing, since the angle at which the clipping object 364 is projected is the same as the angle at which the cloud display object 361 is projected, the shape of the clipping projection area 351a, which is the projection area of the clipping object 364, is This is the same as the cloud display projection area 352a which is the projection area of the display object 361. Further, in the initial state, the clipping object 364 has a size obtained by reducing the cloud display object 361 at a magnification of 80%. Then, at each timing, when the clipping object 364 and the cloud display object 361 are enlarged or reduced and set in the world coordinate system, the enlargement magnification or reduction magnification is the same. Therefore, the size of the clipping projection area 351a is the size obtained by reducing the cloud display projection area 352a by a magnification of 80%.

In the world coordinate system, a perpendicular is drawn from the center point 361a of the cloud display object 361 to the screen area PC12, and the intersection of the perpendicular and the screen area PC12 is the center corresponding point 352c of the cloud display object 361 (FIG. 31(c)). And In the world coordinate system, a perpendicular line is drawn from the center point 364a of the clipping object 364 to the screen area PC12, and the intersection of the perpendicular line and the screen area PC12 is the center corresponding point 351c of the clipping object 364 (FIG. 32(b)). And

Since the coordinates of the center point 361a of the cloud display object 361 and the coordinates of the center point 364a of the clipping object 364 in the world coordinate system are the same, the position of the center corresponding point 352c of the cloud display object 361 in the screen area PC12. And the position of the center corresponding point 351c of the clipping object 364 is the same. The position of the center corresponding point 352c of the cloud display object 361 in the projection data 352 of the cloud display object 361 is the same as the position of the center corresponding point 351c of the cutout object 364 in the projection data 351 of the cutout object 364. is there.

Specifically, in the projection data 352 of the cloud display object 361, the positional relationship between the dot in the upper left corner and the center corresponding point 352c of the cloud display object 361 is as follows. This is the same as the positional relationship between the dots at the corners of and the center corresponding point 351c of the clipping object 364.

The angle when the cloud display object 361 is projected on the screen area PC12 is the same as the angle when the clipping object 364 is projected on the screen area PC12. According to the above relationship, the clipping projection region 351a in the projection data 351 of the clipping object 364 is the cloud display projection region 352a in the projection data 352 of the cloud display object 361, and the center corresponding point 352c of the cloud display object 361. Is the same as the area reduced to 80%.

Next, the clipping process performed by the VDP 135 will be described. In the cutout processing, in the cloud display two-dimensional data 363, a region having a corresponding relationship with the cutout projection region 351a is cut out. Here, cutting out a predetermined area in the two-dimensional data means that transparency information of complete transmission is set in the predetermined area in the two-dimensional data.

In the cutout processing of the cloud display effect, the two-dimensional data for cloud display 363 becomes the data on the cutout side. The data on the side to be clipped is the data to be clipped. Further, in the clipping processing of the cloud display effect, the projection data 351 of the clipping object 364 becomes the data on the clipping side. The data on the side to be cut out is used as data for cutting out. In the clipping process, the clipping target data and the clipping data are grasped. The clipping data is used for grasping the region to be clipped in the clipping target data.

First, the VDP 135 grasps the cloud display two-dimensional data 363 as the clipping target data and grasps the projection data 351 of the clipping object 364 as the clipping data. After that, for all the dots forming the projection data 351 of the clipping object 364 that is the clipping data, it is determined whether or not the α value set to the dot is “0”.

If the α value set to the target dot is “0”, the α value set to the dot corresponding to the dot in the cloud display two-dimensional data 363 to be cut out is set to “0”. Can be rewritten. When the α value set for the target dot is not “0”, rewriting is not performed, and therefore, in the cloud display two-dimensional data 363 that is the clipping target, it is set to the dot that has a corresponding relationship with the dot. The α value is maintained as it is.

In the projection data 351 of the clipping object 364, “0” is set as an α value for all the dots forming the clipping projection area 351a, and as an α value for all the dots forming the peripheral area 351b. Since "1" is set, only the area corresponding to the clipping projection area 351a in the two-dimensional data for cloud display 363 is completely transparent. The frame display two-dimensional data 353 is created by performing the clipping process on the cloud display two-dimensional data 363.

FIG. 32C is an explanatory diagram for explaining the frame display two-dimensional data 353. A frame area 353a exists in the frame display two-dimensional data 353. The frame area 353a is an outer edge portion of the cloud display projection area 352a that is left without being cut out in the cloud display two-dimensional data 363. In the two-dimensional frame display data 353, the outer region 353b existing outside the frame region 353a and the inner region 353c existing inside the frame region 353a are completely transparent.

Next, a method of creating the blurring frame display two-dimensional data 367 (FIG. 34E) for blurring the boundary 369 of the cloud display two-dimensional data 363 will be described. The blurring frame display two-dimensional data 367 is created by setting the blurring range 366 that is the target of the blurring process in the frame display two-dimensional data 353 and moving the color information and the transparency information of the blurring range 366. To be done. Here, the blurring process is performed by moving the color information set in a partial area of the two-dimensional data to another area, resulting in a partial deviation and blurring from the original two-dimensional data. This is a process of creating dimensional data.

First, a method for setting the blurring range 366 in the frame display two-dimensional data 353 will be described. A blur range table TB1 (FIG. 32E) for setting the blur range 366 is set in the memory module 133. FIG. 32D is an explanatory diagram for explaining the blurring range 366 set by using the coordinate data set in the blurring range table TB1. Further, FIG. 32(e) is a blur range table TB1.

As shown in FIG. 32(e), numbers 1 to 1000 are set as dot numbers in the blurring range table TB1. The number is the number of dots forming the blurring range 366. The coordinate data of the XY coordinate system is set to each number. As shown in FIG. 32D, the blurring range 366 has a blurring center 366a that is a central dot. The coordinates of the blurring center 366a are (x, y).

The coordinate data of the dot of each number is set in relation to the coordinates (x, y) of the blurring center 366a. Specifically, as shown in FIG. 32(e), the first dot is located at a position a(1) in the x-axis direction and b(1) in the y-axis direction from the blurring center 366a, and The numbered dot is located at a position shifted a(2) in the x-axis direction and b(2) in the y-axis direction from the blurring center 366a. The third dot is located at a position a(3) in the x-axis direction and b(3) in the y-axis direction from the blurring center 366a. The 1000th dot is located at a position a (1000) in the x-axis direction and b (1000) in the y-axis direction from the blurring center 366a. Here, each time the x coordinate increases by 1, the dot position moves by one dot in the x axis direction, and each time the y coordinate increases by 1, the dot position moves by one dot in the y axis direction. a(1) to a(1000) and b(1) to b(1000) are values that represent the deviation from the blurring center 366a. The positions of the dots included in the blurring range 366 are set in a relative relationship with the blurring center 366a. Therefore, when the coordinates of the blurring center 366a are determined in the frame display two-dimensional data 353, the coordinates of all the dots included in the blurring range 366 are determined. In the blurring process, a plurality of coordinates of the blurring center 366a are set, and a plurality of blurring ranges 366 are set in the frame display two-dimensional data 353.

FIG. 33A is an explanatory diagram for explaining the arrangement of dots that form the two-dimensional frame display data 353. As shown in FIG. 33( a ), the frame display two-dimensional data 353 is rectangular and has a large number of dots arranged in the x-axis direction (horizontal direction) and also has a large number in the y-axis direction (vertical direction). Dots are lined up. The coordinates of the dot existing in the upper left of the frame display two-dimensional data 353 are (1, 1), and the x coordinate is incremented by 1 every time one dot is shifted in the horizontal direction, and is y every time one dot is shifted in the vertical direction. The coordinate increases by 1.

In the blurring process, a vertical scanning process of searching for dots having an α value other than “0” while shifting the target dot in the vertical direction for a predetermined x coordinate, and a horizontal scan for a predetermined y coordinate. The horizontal scanning process is executed to shift the dots that are to be searched for a dot for which an α value other than “0” is set. Then, the coordinates of the dots determined by the vertical scanning process and the horizontal scanning process become the coordinates of the blurring center 336a. Here, scanning means determining whether or not the set α value is “0” for each of the dots that form the target row.

First, the first half of the vertical scanning process performed by the VDP 135 will be described with reference to FIG. The vertical scanning process has a first half part in which the α value set in the dots is examined from the top to the bottom, and a second half part in which the α value set in the dots is examined from the bottom to the top. ..

In the first half of the vertical scanning process, "500" is set as the initial value of the x coordinate of the target dot. As a result, in the frame display two-dimensional data 353, the dots arranged at the 500th position from the left end are to be scanned. The dots to be scanned are arranged in one vertical column, and the scanning is performed from the top to the bottom of the column.

The VDP 135 first determines whether or not the α value set in the uppermost dot is “0”, and when it is “0”, moves to the second dot. It is determined whether or not the α value set in the second dot is “0”, and if it is “0”, the process moves to the third dot. In this way, the dots in the row that is the target of scanning are sequentially examined from the top. Then, when a dot for which an α value other than “0” is set is found in the column that is the target of scanning this time, the coordinate of the dot is stored in the register 153 as the first coordinate of the blurring center 366a. Remember.

When a dot for which an α value other than “0” is set is found in the scan target column, the scan of that column is terminated there, and x for determining the scan target column is determined. Update by adding "500" to the coordinate value. Also, when all the dots in the scan target column have been checked, "500" is added to the x coordinate value for determining the scan target column and updated. Then, the row of dots that has been newly scanned is scanned again.

The scan is performed while moving the scan target column to the right by 500 dots until the number of scans reaches the first switching value. The first switching value is a value set at the design stage, and is set so that the number of scans becomes the first switching value when scanning is performed from the left end to the right end of the frame display two-dimensional data 353. .. In the first half of the vertical scanning process, a plurality of coordinates of the blurring center 366a are stored in a manner that corresponds one-to-one with the number of scans. The coordinates of the blurring center 366a thus stored are all located at the upper edge of the frame area 353a.

The latter half of the vertical scanning process performed after the first half of the vertical scanning process will be described with reference to FIG. In the latter half of the vertical scanning process, the initial value of the x coordinate that determines the scan target column is set to “750”, and scanning is performed again from the left end to the right end of the frame display two-dimensional data 353. In the latter half of the vertical scanning process, scanning is performed from bottom to top. That is, scanning is performed in order from the dot existing at the bottom of the scan target column. Since the initial value of the x coordinate that determines the scan target column is different from the first half of the vertical scan processing, the coordinates stored in the first half of the vertical scan processing and the coordinates stored in the second half of the vertical scan processing are in the x-axis direction. Deviated.

The scan is performed while shifting the scan target column to the right by 500 dots until the number of scans reaches the second switching value. The second switching value is a value set at the design stage, and the number of scans is set to the second switching value when scanning is performed from the left end to the right end of the frame display two-dimensional data 353. .. In the latter half of the vertical scanning process, a plurality of coordinates of the blurring center 366a are stored in a manner that corresponds one-to-one with the number of scans. The coordinates of the blurring center 366a thus stored are all located at the lower edge of the frame area 353a.

In the VDP 135, the vertical scan process is followed by the horizontal scan process. The horizontal scan process consists of the first half of checking the α value set for each dot from left to right, and the second half of checking the α value set for each dot from right to left. There is.

The first half of the horizontal scanning process will be described with reference to FIG. In the first half of the horizontal scanning process, the initial value of the y coordinate that determines the scan target column is set to “500”, and scanning is performed from the upper end to the lower end of the frame display two-dimensional data 353. In the first half of the horizontal scanning process, scanning is performed from left to right. That is, the scan is performed in order from the dot on the leftmost side of the scan target column.

The scan is performed until the number of scans reaches the third switching value while moving the scan target column downward by 500 dots. The third switching value is a value set at the design stage, and the number of scans is set to the third switching value when scanning is performed from the upper end to the lower end of the frame display two-dimensional data 353. .. In the first half of the horizontal scanning process, a plurality of coordinates of the blurring center 366a are stored in a manner that corresponds one-to-one with the number of scans. The coordinates of the blurring center 366a thus stored are all located on the left edge of the frame area 353a.

The latter half of the horizontal scanning process will be described with reference to FIG. In the latter half of the horizontal scanning process, the initial value of the y coordinate that determines the scan target column is set to “750”, and scanning is performed from the upper end to the lower end of the frame display two-dimensional data 353. In the latter half of the horizontal scanning process, scanning is performed from right to left. That is, scanning is performed in order from the dot on the rightmost side of the scan target column. Since the initial value of the y coordinate that determines the scan target column is different from the first half of the horizontal scan processing, the coordinates stored in the first half of the horizontal scan processing and the coordinates stored in the second half of the horizontal scan processing are in the y-axis direction. Deviated.

The scan is performed until the number of scans reaches the upper limit value while moving the scan target column downward by 500 dots. The upper limit value is a value set at the design stage, and is set so that the number of scans becomes the upper limit value when scanning is performed from the upper end to the lower end of the frame display two-dimensional data 353. In the latter half of the horizontal scanning process, a plurality of coordinates of the blurring center 366a are stored in a manner that corresponds one-to-one with the number of scans. The coordinates of the blurring center 366a thus stored are all located on the right edge of the frame area 353a.

Next, a method of moving the color information and the transparency information will be described. In the frame display two-dimensional data 353, a plurality of blurring ranges 366 are set based on the coordinates of the blurring center 366a recognized by the vertical scanning process and the horizontal scanning process. Further, the movement destination range 356 is set in the outer area 353b outside the frame area 353a in a one-to-one correspondence with each blurring range 366. Then, the processing of moving the color information and the transparency information set in the blur range 366 to the destination range 356 is executed.

34A to 34D are explanatory diagrams for explaining a method of moving the color information and the transparency information set in the blurring range 366 to the destination range. First, the case where the destination range 356 is set above the blurring range 366 will be described with reference to FIG. Since the coordinates of the plurality of blurring centers 366a recognized in the vertical scanning process and the horizontal scanning process are stored in a manner corresponding to the number of scans in a one-to-one manner, the coordinates stored in the first half of the vertical scanning process and the vertical scan It is possible to selectively grasp the coordinates stored in the latter half of the processing, the coordinates stored in the first half of the horizontal scanning processing, and the coordinates stored in the latter half of the horizontal scanning processing.

Specifically, by setting the range of the number of scans to "1" to "first switching value", the coordinates stored in the first half of the vertical scanning process are selectively grasped. The coordinates are located at the upper edge of the frame area 353a. When setting the blurring range 366 in the frame display two-dimensional data 353 based on the coordinates, the movement destination range 356 is set above the blurring range 366 so that the movement destination range 356 is located outside the frame area 353a. Can be set.

In the blurring range data stored in the memory module 133, since the coordinates of the dots included in the blurring range 366 are set in a relative relationship with the coordinates of the blurring center 366a, they are stored in the first half of the vertical scanning process. When the blurring range 366 is set based on the coordinates, the blurring range 366 is set around the upper edge of the frame area 353a.

The VDP 135 creates new coordinates by subtracting “200” from the y-coordinate value of the coordinates at the coordinates stored in the first half of the vertical scanning process. A range set by substituting the new coordinates as the coordinates of the blurring center 366a is set as a movement destination range 356. The destination range 356 has the same shape and size as the blurring range 366, and is located 200 dots above the blurring range 366. At the start timing and each update timing, the movement destination range 356 is set in the area between the upper side of the rectangular frame display two-dimensional data 353 and the upper edge of the frame area 353a. The destination range 356 does not extend beyond the upper side of the frame display two-dimensional data 353.

Each dot forming the blurring range 366 and each dot forming the movement destination range 356 have a one-to-one correspondence. Specifically, the first dot in the blurring range 366 and the first dot in the destination range 356 have a corresponding relationship, and the second dot in the blurring range 366 and the second dot in the destination range 356. And have a corresponding relationship. Further, the third dot in the blur range 366 and the third dot in the destination range 356 have a corresponding relationship. The 1000th dot in the blurring range 366 and the 1000th dot in the destination range 356 have a corresponding relationship.

The VDP 135 first grasps the color information and transparency information set for the first dot in the blurring range 366, and sets the grasped color information and transparency information for the first dot in the destination range. Then, the transparency information of complete transparency is set to the first dot in the blur range 366. As a result, the process of moving the color information and the transparency information set for the first dot in the blur range 366 to the first dot in the destination range 356 is completed.

Next, a process of moving the color information and the transparency information set in the second dot of the blurring range 366 to the second dot of the movement destination range 356 is performed. In this way, the process of moving the color information and the transparency information set to the dots of the blurring range 366 to the dots of the moving destination range 356 while increasing the number of the dots to be moved by "1". .. Then, by performing the process of moving the color information and the transparency information on the 1000th dot, the process of moving the color information and the transparency information set in the blur range 366 to the destination range 356 is completed. To do. By the processing, the color information and the transparency information near the upper edge of the frame area 353a are moved upward, and the upper side of the frame area 353a is blurred.

Next, a case where the destination range 356 is set below the blurring range 366 will be described with reference to FIG. By setting the range of the number of scans to “first switching value+1” to “second switching value”, the coordinates stored in the latter half of the vertical scanning process are selectively grasped. The coordinates are located at the lower edge of the frame area 353a. When the blurring range 366 is set in the frame display two-dimensional data 353 based on the coordinates, the movement destination range 356 is set below the blurring range 366 so that the movement destination range 356 is located outside the frame area 353a. Can be set.

When the blurring range 366 is set based on the coordinates stored in the latter half of the vertical scanning process, the blurring range 366 is set around the lower edge of the frame area 353a. The VDP 135 creates new coordinates by adding "200" to the value of the y coordinate of the coordinates stored in the latter half of the vertical scanning process. The range set by substituting the new coordinates as the coordinates of the blurring center 366a becomes the destination range 356. The destination range 356 has the same shape and size as the blurring range 366, and is located 200 dots below the blurring range 366. At the start timing and each update timing, the movement destination range 356 is set in a region between the lower side of the rectangular frame display two-dimensional data 353 and the lower edge of the frame region 353a. The destination range 356 does not extend beyond the lower side of the frame display two-dimensional data 353.

Each dot forming the blurring range 366 and each dot forming the movement destination range 356 have a one-to-one correspondence. The VDP 135 grasps the color information and the transparency information set in the target dot in the blurring range 366, and sets the color information and the transparency information in the corresponding dot in the destination range 356. Then, the transparency information of complete transparency is set to the target dot in the blurring range 366. For all the dots in the blurring range 366, the target dot is updated until the movement of the color information and the transparency information is completed. Due to the movement of the color information and the transparency information, the color information and the transparency information near the lower edge of the frame area 353a are moved downward, and the lower side of the frame area 353a is blurred.

Next, a case where the destination range 356 is set to the left of the blurring range 366 will be described with reference to FIG. By setting the range of the number of scans to “second switching value+1” to “third switching value”, the coordinates stored in the first half of the horizontal scanning process are selectively grasped. The coordinates are located on the left edge of the frame area 353a. When the blurring range 366 is set in the frame display two-dimensional data 353 based on the coordinates, the movement destination range 356 is set to the left of the blurring range 366 so that the movement destination range 356 is outside the frame area 353a. Can be set to.

When the blurring range 366 is set based on the coordinates stored in the first half of the horizontal scanning process, the blurring range 366 is set around the left edge of the frame area 353a. The VDP 135 subtracts "200" from the value of the x coordinate of the coordinate at the coordinate stored in the first half of the horizontal scanning process to create a new coordinate. The range set by substituting the new coordinates as the coordinates of the blurring center 366a becomes the destination range 356. The destination range 356 has the same shape and size as the blurring range 366, and is located 200 dots to the left of the blurring range 366. At the start timing and each update timing, the movement destination range 356 is set in a region between the left side of the rectangular frame display two-dimensional data 353 and the left side edge of the frame region 353a. The destination range 356 does not extend beyond the left side of the frame display two-dimensional data 353.

Each dot forming the blurring range 366 and each dot forming the movement destination range 356 have a one-to-one correspondence. The VDP 135 grasps the color information and the transparency information set in the target dot in the blurring range 366, and sets the color information and the transparency information in the corresponding dot in the destination range 356. Then, the transparency information of complete transparency is set to the target dot in the blurring range 366. For all the dots in the blurring range 366, the target dot is updated until the movement of the color information and the transparency information is completed. Due to the movement of the color information and the transparency information, the color information and the transparency information near the left edge of the frame area 353a are moved to the left, and the left side of the frame area 353a is blurred.

Next, a case where the destination range 356 is set to the right of the blurring range 366 will be described with reference to FIG. By setting the range of the number of scans to “third switching value+1” to “upper limit value”, the coordinates stored in the latter half of the horizontal scanning process are selectively grasped. The coordinates are located on the right edge of the frame area 353a. When the blurring range 366 is set in the frame display two-dimensional data 353 based on the coordinates, the movement destination range 356 is set to the right of the blurring range 366 so that the movement destination range 356 is located outside the frame area 353a. Can be set to.

When the blurring range 366 is set based on the coordinates stored in the latter half of the horizontal scanning process, the blurring range 366 is set around the right edge of the frame area 353a. The VDP 135 adds "200" to the value of the x coordinate of the coordinate stored in the latter half of the horizontal scanning process to create a new coordinate. The range set by substituting the new coordinates as the coordinates of the blurring center 366a becomes the destination range 356. The destination range 356 has the same shape and size as the blurring range 366, and is located 200 dots to the right of the blurring range 366. At the start timing and each update timing, the movement destination range 356 is set in the area between the right side of the rectangular frame display two-dimensional data 353 and the right edge of the frame area 353a. The destination range 356 does not extend beyond the right side of the frame display two-dimensional data 353.

Each dot forming the blurring range 366 and each dot forming the movement destination range 356 have a one-to-one correspondence. The VDP 135 grasps the color information and the transparency information set in the target dot in the blurring range 366, and sets the color information and the transparency information in the corresponding dot in the destination range 356. Then, the transparency information of complete transparency is set to the target dot in the blurring range 366. For all the dots in the blurring range 366, the target dot is updated until the movement of the color information and the transparency information is completed. By moving the color information and the transparency information, the color information and the transparency information near the right edge of the frame area 353a are moved to the right, and the right side of the frame area 353a is blurred.

FIG. 34E is an explanatory diagram for explaining the blurring frame display two-dimensional data 367 created by performing the blurring process on the frame display two-dimensional data 353. In the blurring frame display two-dimensional data 367, the outline of the blurring frame area 367a in which opaque color information is set has a complicated shape with irregularities. The transparency information of complete transparency is set in the outer area 367b on the outer side and the inner area 367c on the inner side of the blurring frame area 367a.

Next, a method of creating the cloud drawing data 368 (FIG. 31A) will be described. The cloud drawing data 368 is created by combining the separately stored cloud display two-dimensional data 363 (FIG. 31E) and blurring frame display two-dimensional data 367 (FIG. 34E). .. The cloud display two-dimensional data 363 and the blurring frame display two-dimensional data 367 are rectangles having the same shape and size and the same number of dots. That is, in the cloud display two-dimensional data 363 and the blurring frame display two-dimensional data 367, the same number of dots are arranged vertically, and the same number of dots are also arranged horizontally. Therefore, in the two-dimensional data for cloud display 363 and the two-dimensional data for blur frame display 367, the dots existing at the same position are associated with each other to form each dot forming the two-dimensional data for cloud display 363 and the blur frame display. The dots forming the two-dimensional data 367 for use are associated with each other one-to-one.

In the synthesis of two two-dimensional data, the color information set for each dot forming the basic data is changed according to the color information and the transparency information set for each dot forming the corresponding priority data. It is done by Based on the drawing list, the VDP 135 sets the cloud display two-dimensional data 363 (FIG. 31(e)) as basic data, and sets the blurring frame display two-dimensional data 367 (FIG. 34(e)) as priority data. Set. The blurring frame display two-dimensional data 367 that is the priority data includes an area in which the α value of “1” is set and an area in which the α value of “0” is set.

Specifically, a region included in the frame region 353a before the blurring process is performed, and a region where the blurring range 366 is not set in the blurring process and an outer region 353b before the blurring process is performed. An α value of “1” is set in each of the included regions, in which the destination range 356 is set in the blurring process. On the other hand, an area that was included in the frame area 353a before the blurring process, in which the blurring range 366 was set in the blurring process, an outer region 367b of the blurring frame display two-dimensional data 367, and an inner side. An α value of “0” is set in each of the areas 367c.

When the opaque color information is set for the dots of the blurring frame display two-dimensional data 367, the color information set for the corresponding dots of the cloud display two-dimensional data 363 is the blurring frame display two-dimensional data. The opaque color information set in the dots of the data 367 is changed. Further, when the completely transparent transparency information is set for the dots of the blurring frame display two-dimensional data 367, the color information set for the corresponding dots of the cloud display two-dimensional data 363 is not changed. The synthetic data obtained by this is cloud drawing data 368 (FIG. 31A) in which the frame area 353a is rewritten into the blurring frame area 367a in the two-dimensional data for cloud display 363. The cloud drawing data 368 is created by rewriting the frame area 353a surrounding the cloud 362a having a complicated shape to the blurring frame area 367a having a complicated outer shape. Then, based on the cloud drawing data 368, an image in which a plurality of clouds 362a are lined up in a blurry frame is displayed on the display surface G of the symbol display device 31, thereby reducing a sense of discomfort given to the player. can do.

The VDP 135 creates drawing data for effects and symbols in the drawing data creation process for effects and symbols in step S710 of the drawing process (FIG. 13). The update timing at which the drawing data for airplane, which is the drawing data for displaying the airplane passing behind the cloud 362a, and the drawing data for cloud 368 are created as the drawing data for rendering will be described below. It should be noted that each drawing data has the same outer shape, and the number of pixels forming each drawing data is also the same. Further, in the drawing data for an airplane, an α value other than “0” is set for a pixel for which color information for displaying an image of an airplane is set, and other pixels are set to “0”. The α value is set.

The VDP 135 arranges the drawing data for airplanes, the drawing data for clouds 368, and the drawing data for symbols that are individually created, and the drawing data for airplanes is arranged at the most back side, and the drawing data for symbol display is at the most front side. In line, the drawing data for clouds 368 is written between the two drawing data to write the three drawing data in the screen buffer 144, thereby creating drawing data for effects and symbols.

Further, the VDP 135 sets the background drawing data and the effect and design drawing data individually written in the screen buffer 144 in the drawing data combining process in step S711 of the drawing process (FIG. 13) to the background. The drawing data for one line is created on the back side, and the drawing data for the effect and the pattern is written on the front side for writing in the frame areas 142a and 142b to be drawn, thereby creating one frame of drawing data.

In the case of creating drawing data for effects and patterns and in the case of creating drawing data for one frame, if the pixel for which drawing is executed is set to the α value of complete transparency, the back side When the semi-transparent α value is set, the color information of the image is used as it is, and the color information of the image on the back side and the color information of the image on the front side are blended at a ratio based on the α value. When the opaque α value is set, the color information of the image on the back side is overwritten with the color information of the image on the back side. As a result, the effect image is displayed at a position on the front side of the background image and at the back side of the design image. As the effect image, an image in which a plurality of clouds 362a are arranged in front of the image of the airplane is displayed.

It should be noted that, at the update timing when the rendering data for rendering is only the rendering data for clouds 368 without displaying the airplane, the VDP 135 sets the rendering data for clouds 368 to the screen buffer 144 as rendering data on the far side. Along with the writing, the drawing data for the design is written as the drawing data on the front side to create the drawing data for the effect and the design.

Hereinafter, a specific processing configuration for creating the cloud drawing data 368 using the clipping object 364 will be described. FIG. 35 is a flowchart showing the calculation processing for cloud display effect executed by the display CPU 131. The calculation processing for cloud display effect is started when the data table corresponding to the game time in which the effect for displaying the cloud drawing data 368 is executed is set. The parameter table of the cloud display object 361 is stored in the memory module 133 in advance.

First, in step S1601, it is determined based on the currently set data table whether or not the cloud display effect is being executed. When the cloud display effect is not being executed (step S1601: NO), it is determined in step S1602 whether or not it is the start timing of the cloud display effect. If it is not the start timing (step S1602: NO), this operation processing is terminated as it is, and if it is the start timing (step S1602: YES), the process proceeds to step S1603.

In step S1603, the parameter table of the cloud display object 361 is read based on the currently set data table. In the parameter table, the parameters of the cloud display object 361 at the timing of changing the parameters of the cloud display object 361 in the world coordinate system and the timing of changing the parameters of the viewpoint PC 11 are set. Here, the parameters of the cloud display object 361 are coordinates, rotation angles, and scales, and the parameters of the viewpoint PC 11 are coordinates and orientations. The timing when the parameter of the cloud display object 361 is changed means that the cloud 362a viewed from a different angle is displayed on the display surface G of the symbol display device 31 when the cloud display object 361 moves or rotates. It's timing. Then, the timing when the parameters of the viewpoint PC 11 are changed means that the image displayed on the display surface G of the symbol display device 31 is an image when the cloud 362a is viewed from below to an image when the cloud 362a is viewed from above. It is the timing to switch to. In a succeeding step S1604, a process of grasping various data for cloud display effect is performed.

Here, the process of grasping various data for cloud display effect will be described with reference to the flowchart of FIG. FIG. 36 is a flowchart showing a process of grasping various data for cloud display effect executed by the display CPU 131. The cloud display object 361, the clipping object 364, the cloud display texture 362, and the blurring range data are stored in advance in the memory module 133.

First, in step S1701, the use instruction information of the cloud display object 361 is stored based on the currently set data table, and in step S1702, the already read parameter table of the cloud display object 361 is referred to. The parameters of the cloud display object 361 are grasped. In step S1703, the use instruction information of the clipping object 364 is stored based on the currently set data table, and in step S1704, the parameter table of the cloud display object 361 that has already been read is referred to for clipping. Understand the parameters of the object 364.

The parameter of the cloud display object 361 and the parameter of the clipping object 364 are both grasped by referring to the parameter table of the cloud display object 361. Therefore, the parameter for setting the cloud display object 361 in the world coordinate system and the parameter for setting the clipping object 364 in the world coordinate system are the same.

In step S1705, the cloud display texture 362 corresponding to the cloud display object 361 is grasped based on the currently set data table. When the currently set data table is a data table for high-expectation performance, the cloud display texture 362 for high-expectation performance is grasped. If the currently set data table is a low-expectancy rendering data table, the cloud display texture 362 for low-expectancy rendering is grasped. In step S1706, blurring range data for setting a range in which the frame region 353a of the frame display two-dimensional data 353 is blurred is grasped. Then, in step S1707, various instruction information is stored, and the present grasping process ends. Here, the various instruction information refers to cutout instruction information, blurring instruction information, and combination instruction information.

By setting the cutout instruction information in the drawing list, the cutout process (FIG. 40) of cutting out the area corresponding to the cutout projection area 351a in the two-dimensional data for cloud display 363 is executed. Further, by setting the blurring instruction information in the drawing list, blurring processing for blurring the frame area 353a of the frame display two-dimensional data 353 is executed. Here, the blurring process includes a vertical scan process (FIG. 41), a horizontal scan process (FIG. 42), a range setting process (FIG. 43), and a moving process (FIG. 44) of color information and the like. Then, by setting the synthesis instruction information in the drawing list, the processing of steps S1810 to S1813 in the cloud drawing data creation processing (FIG. 37) is executed.

Returning to the description of the calculation process for cloud display effect (FIG. 35 ), after executing the process of grasping various data for cloud display effect in step S1604, the start designation information is stored in step S1605 and this calculation process is executed. finish.

When the calculation processing for cloud display effect is executed as described above, the cloud display object 361, the clipping object 364, the cloud display texture 362, and the cloud display texture 362 are included in the drawing list created by the subsequent drawing list output processing. Use instruction information of blurring range data is set. Further, the parameters of the cloud display object 361 and the clipping object 364 are also set in the drawing list. Further, in the drawing list, clipping instruction information, blurring instruction information, combination instruction information, and cloud display effect start designation information are also set.

If the cloud display effect is being executed (step S1601: YES), in step S1606, it is time to change the relative relationship between the cloud display object 361 and the viewpoint PC11 in the world coordinate system. Or not. The determination is performed based on the parameter table of the cloud display object 361 that has already been read. When it is not time to change the relative relationship between the cloud display object 361 and the viewpoint PC11 in the world coordinate system (step S1606: NO), in step S1607, use instruction information of separate saved data is stored. The VDP 135 reads and uses the cloud drawing data 368 separately stored according to the use instruction information. In the following step S1608, the update designation information is stored and the present arithmetic processing is terminated.

When the calculation process for cloud display production is executed as described above, the drawing list created by the subsequent drawing list output process includes the usage instruction information of cloud drawing data 368 stored separately and the cloud display. Performance update designation information is set.

If it is time to change the relative relationship between the cloud display object 361 and the viewpoint PC 11 in the world coordinate system (step S1606: YES), a process of grasping various data for cloud display effect in step S1609 (FIG. 36) is executed, the update designation information is stored in step S1610, and the present arithmetic processing is terminated.

When the calculation processing for cloud display effect is executed as described above, the cloud display object 361, the clipping object 364, the cloud display texture 362, and the cloud display texture 362 are included in the drawing list created by the subsequent drawing list output processing. Use instruction information of blurring range data is set. Further, the parameters of the cloud display object 361 and the clipping object 364 are also set in the drawing list. Further, the drawing list also stores clipping instruction information, blurring instruction information, composition instruction information, and cloud display effect update designation information.

Next, the cloud drawing data creation processing executed by the VDP 135 will be described with reference to FIG. The cloud drawing data creation processing is executed by the effect setting processing in step S703 of the drawing processing (FIG. 13). Further, the cloud drawing data creation process is started when the cloud display effect start designation information or update designation information is set in the drawing list.

First, in step S1801, it is determined whether or not the use instruction information of the cloud drawing data 368 separately stored in the current drawing list is set. When the use instruction information of the cloud drawing data 368 separately stored in the drawing list is not set (step S1801: NO), the cloud display two-dimensional data creation process is executed in step S1802. Here, the process of creating the two-dimensional data for cloud display will be described with reference to the flowchart of FIG. FIG. 38 is a flowchart showing the cloud display two-dimensional data creation processing executed by the VDP 135.

First, in step S1901, the drawing list of this time is referred to, and the address where the cloud display object 361 is stored in the memory module 133 is grasped and read. In the following step S1902, the parameter of the cloud display object 361 is grasped by referring to the drawing list this time, and the cloud display object 361 is set in the world coordinate system in step S1903.

In step S1904, the cloud display object 361 is projected onto the screen area PC12 to create projection data 352 of the cloud display object 361. In step S1905, the drawing list of this time is referred to, and the address where the cloud display texture 362 is stored in the memory module 133 is grasped and read. Then, in step S1906, the cloud display texture 362 is applied to the projection data 352 of the cloud display object 361 to create the cloud display two-dimensional data 363, and in step S1907, the cloud display two-dimensional data 363 is separated. Save and end this creation process.

Returning to the description of the cloud drawing data creation processing (FIG. 37), the cloud display two-dimensional data creation processing is executed in step S1802, and then the clipping object projection processing is executed in step S1803. Here, the projection processing of the clipping object will be described with reference to the flowchart of FIG. FIG. 39 is a flowchart showing the clipping object projection processing executed by the VDP 135.

First, in step S2001, the clipping object 364 is grasped by referring to the drawing list of this time, and in step S2002, the parameters of the clipping object 364 are grasped based on the drawing list of this time. In a succeeding step S2003, the clipping object 364 is set in the world coordinate system based on the parameters grasped in the step S2002, and in the step S2004, the clipping object 364 is projected on the screen area PC12 so that the clipping object 364 can be displayed. The projection data 351 is created.

In step S2005, in the projection data 351 of the clipping object 364 created in step S2004, the α values of all the dots forming the clipping projection area 351a are set to “0”. In a succeeding step S2006, in the projection data 351 of the clipping object 364, the α values of all the dots forming the peripheral area 351b are set to “1”, and this projection processing is ended.

Returning to the description of the cloud drawing data creation processing (FIG. 37 ), after the projection processing of the clipping object is executed in step S1803, the clipping processing is executed in step S1804. Here, the clipping process will be described with reference to the flowchart in FIG. FIG. 40 is a flowchart showing the clipping processing executed by the VDP 135. The cutout process is executed when cutout instruction information is set in the drawing list.

First, in step S2101, the separately stored cloud display two-dimensional data 363 is set as cutout target data based on the current drawing list, and in step S2102, the cutout object 364 of the cutout object 364 is set based on the current drawing list. The projection data 351 is set as the clipping data. The cutout process is performed by changing the color information set for each dot of the cutout target data according to the color information and the transparency information set for each dot of the cutout data.

In step S2103, in the projection data 351 of the clipping object 364 that is the clipping data, the dot that is the target of the determination process regarding the transparency information is updated. Specifically, the first dot is set as the target dot at the start timing, and the dot positioned next to the previous target dot is set as the target dot at the update timing. In a succeeding step S2104, it is determined whether or not the α value set in the current target dot grasped in step S2103 is “0”. When “0” is set as the α value for the current target dot (step S2104: YES), complete transparency information is set for the dot corresponding to the current target dot in step S2105. Here, the corresponding dot is a dot of the cloud display two-dimensional data 363 which is the cutout target data.

After making a negative determination in step S2104 or after performing the process of step S2105, it is determined in step S2106 whether or not all the dots forming the projection data 351 of the clipping object 364 have become the target dots. .. If there is a dot that is not the target dot (step S2106: NO), the process returns to step S2103 to update the target dot. If there is no dot that is not the target dot (step S2106: YES), the main cutout process is terminated. By the clipping processing, the frame display two-dimensional data 353 (FIG. 32C) is created.

Returning to the description of the cloud drawing data creation processing (FIG. 37), after performing the clipping processing in step S1804, in step S1805, the vertical scanning processing is performed on the frame display two-dimensional data 353 created in step S1804. .. Here, the vertical scanning process will be described with reference to the flowchart in FIG. FIG. 41 is a flowchart showing the vertical scanning process executed by the VDP 135. The vertical scanning process is executed when the blurring instruction information is set in the drawing list.

First, in step S2201, it is determined whether or not the variable n is the first switching value. Here, the variable n is an integer of 0 or more, and “1” is added every time scanning of each column is completed. The variable n at the start timing is “0”. If the variable n is not the first switching value, the process advances to step S2202 to start scanning a new column. In step S2202, "1" is added to the variable n. The variable n indicates that this time is the nth scan.

In step S2203, the y coordinate value for determining the scan target dot is cleared to "0". As a result, a new scan is performed from the top of the target column. In step S2204, "500" is added to the x coordinate value for determining the scan target column. At the start timing, “500” is set as the initial value of the x coordinate value, and the target column for the first scan is determined. At the update timing, the scan target column is shifted to the right by 500 dots from the previous target column.

In step S2205, "1" is added to the y coordinate value for determining the scan target dot, and in step S2206, the dot one dot below the previous dot is recognized as the current target dot. In a succeeding step S2207, it is determined whether or not the α value set for the current target dot is “0”. If the α value is not “0” (step S2207: NO), it means that the current target dot exists at the upper edge of the frame area 353a. Therefore, in step S2208, the current target dot position information is obtained. Is stored in one-to-one correspondence with the variable n, which is the number of scans this time.

When the α value set for the current target dot is “0” (step S2207: YES), it means that the current target dot is one of the dots forming the outer area 353b. The position information of the target dot this time is not stored. In step S2209, it is determined whether the y coordinate value for determining the target dot is the upper limit value. If the current target dot is not located at the bottom of the scan target row (step S2209: NO), the process returns to step S2205 to update the y-coordinate value of the target dot and continue scanning downward.

If the current target dot is located at the bottom of the scan target row (step S2209: YES), it is stored in step S2210 that the dots forming the frame area 353a were not found in the nth scan. To do. When the process of step S2208 or step S2210 is performed, the process returns to step S2201 and it is determined again whether the variable n is the first switching value. If the variable n is not the first switching value (step S2201: NO), the process proceeds to step S2202 again. When the variable n is the first switching value (step S2201: YES), the process proceeds to step S2211, and the latter half of the vertical scanning process is performed.

In step S2211, “250” is set to the x coordinate value for determining the scan target column. In step S2212, it is determined whether or not the variable n is the second switching value, and if the variable n is not the second switching value, "1" is added to the variable n in step S2213. In step S2214, the y coordinate value for determining the current target dot is set to a value that is “1” larger than the upper limit value. Then, in step S2215, "500" is added to the x coordinate value for determining the scan target column. The first scan in the second half of the vertical scan process is a column having an x coordinate value of "750", and after that, it is shifted to the right by 500 dots. This means that the scanning from the bottom is performed on a column different from the first half of the vertical scanning process.

In step S2216, "1" is subtracted from the y coordinate value for determining the target dot, and in step S2217, the dot that is one dot above the previous target dot is recognized as the current target dot. After the target row of the scan is updated, the y coordinate value that determines the first target dot is the upper limit value, so the scan proceeds from the bottom of the target row to the top. In step S2218, it is determined whether or not the α value set for the current target dot is “0”. If the α value set for the current target dot is not “0” (step S2218: NO), it means that the current target dot is a dot existing at the lower edge of the frame area 353a. In step S2219, the position information of the dot is stored in one-to-one correspondence with the variable n. The variable n indicates the number of scans.

If the α value set for the current target dot is “0” (step S2218: YES), it means that the current target dot is one of the dots forming the outer area 353b. The position information of the dot is not stored and the process proceeds to step S2220. In step S2220, it is determined whether or not the y coordinate value of the target dot this time is "1".

If the y-coordinate value of the target dot is not "1" (step S2220: NO), the process returns to step S2216 to continue scanning for dots located above the current target dot. If the y-coordinate value of the target dot is “1” (step S2220: YES), it means that the dot is located at the top of the scan target row, and therefore in step S2221, the n-th time is determined. It is stored that there is no dot forming the frame area 353a in the scan target column.

After performing the process of step S2219 or step S2221, it is determined in step S2212 whether the variable n is the second switching value. If the variable n is not the second switching value (step S2212: NO), it means that there is a column to be scanned, and therefore the process proceeds to step S2213 again to scan the next column to be scanned. If the variable n is the second switching value (step S2212: YES), the y coordinate value for determining the target dot is cleared to "0" in step S2222, and the vertical scanning process is ended.

By the vertical scanning process, the position information of the dots existing on the upper edge of the frame region 353a and the position information of the dots existing on the lower edge of the frame region 353a are stored. The position information of the upper dot is associated with an integer of any one of "1" to "first switching value". Further, the position information of the lower dot is associated with an integer of any one of “first switching value+1” to “second switching value”.

Returning to the description of the cloud drawing data creation processing (FIG. 37), after performing the vertical scan processing in step S1805, in step S1806, the horizontal scan processing is performed on the frame display two-dimensional data 353 created in step S1804. To do. Here, the horizontal scanning process will be described with reference to the flowchart in FIG. FIG. 42 is a flowchart showing the horizontal scan process executed by the VDP 135. The horizontal scanning process is executed when blurring instruction information is set in the drawing list.

First, in step S2301, it is determined whether or not the variable n is the third switching value. In step S2302, "1" is added to the variable n. In step S2303, the x coordinate value for determining the scan target dot is cleared to "0". As a result, a new scan is performed from the leftmost of the target column. In step S2304, “500” is added to the y coordinate value for determining the scan target column. At the start timing, "500" is set as the initial value of the y-coordinate value, so that the target column of the first scan is determined. At the update timing, the scan target column is shifted 500 dots below the previous target column.

In step S2305, "1" is added to the x coordinate value for determining the scan target dot, and in step S2306, the dot one dot to the right of the previous dot is recognized as the current target dot. .. In a succeeding step S2307, it is determined whether or not the α value set in the current target dot is “0”. If the α value is not “0” (step S2307: NO), it means that the current target dot exists at the left edge of the frame area 353a. Therefore, in step S2308, the position information of the current target dot is set. Is stored in one-to-one correspondence with the variable n, which is the number of scans this time.

If the α value set for the current target dot is “0” (step S2307: YES), it means that the current target dot is one of the dots forming the outer area 353b. The position information of the target dot this time is not stored. In step S2309, it is determined whether the x coordinate value for determining the target dot is the upper limit value. If the target dot this time is not located at the rightmost position in the scan target column (step S2309: NO), the process returns to step S2305 to update the x coordinate value of the target dot, and continues scanning to the right.

If the current target dot is located at the rightmost position of the scan target column (step S2309: YES), it is stored in step S2310 that the dots forming the frame area 353a were not found in the nth scan. To do. When the process of step S2308 or step S2310 is performed, the process returns to step S2301, and it is determined again whether the variable n is the third switching value. If the variable n is not the third switching value (step S2301: NO), the process proceeds to step S2302 again. When the variable n is the third switching value (step S2301: YES), the process proceeds to step S2311, and the latter half of the vertical scanning process is performed.

In step S2311, "250" is set to the y coordinate value for determining the scan target column. In step S2312, it is determined whether or not the variable n is the upper limit value, and if the variable n is not the upper limit value, "1" is added to the variable n in step S2313. In step S2314, a value larger than the upper limit value by "1" is set as the x coordinate value for determining the current target dot. Then, in step S2315, “500” is added to the y coordinate value for determining the scan target column. The first scan in the latter half of the vertical scan process is a column having a y-coordinate value of "750", and thereafter is shifted to the right by 500 dots. This means that the scanning from the right is performed on a column different from the first half of the vertical scanning process.

In step S2316, "1" is subtracted from the x coordinate value for determining the target dot, and in step S2317, the dot one dot left of the previous target dot is grasped as the current target dot. After the target row of the scan is updated, the x coordinate value that determines the first target dot is the upper limit value, so the scan proceeds from the rightmost to the left of the target row. In step S2318, it is determined whether the α value set for the current target dot is “0”. If the α value set for the current target dot is not “0” (step S2318: NO), it means that the current target dot is a dot existing on the right edge of the frame area 353a. In step S2319, the dot position information is stored in one-to-one correspondence with the variable n. The variable n indicates the number of scans.

If the α value set for the current target dot is “0” (step S2318: YES), it means that the current target dot is one of the dots forming the outer area 353b. The position information of the dot is not stored and the process proceeds to step S2320. In step S2320, it is determined whether or not the x coordinate value of the target dot this time is "1".

If the x coordinate value of the target dot is not "1" (step S2320: NO), the process returns to step S2316, and the scan is continued for the dot located to the left of the current target dot. When the x coordinate value of the target dot is “1” (step S2320: YES), it means that the dot is located at the leftmost position in the scan target column, and therefore, in step S2321, the n-th time is determined. It is stored that there is no dot forming the frame area 353a in the scan target column.

After performing the processing of step S2319 or step S2321, in step S2312, it is determined whether or not the variable n is the upper limit value. If the variable n is not the upper limit value (step S2312: NO), it means that the column to be scanned remains, and therefore the process proceeds to step S2313 again to scan the next target column. If the variable n is the upper limit value (step S2312: YES), the initialization process is performed in step S2322, and the horizontal scan process is terminated. In the initialization process, the x coordinate value and the y coordinate value for determining the target dot are cleared to “0”. Also, the value of the variable n is cleared to "0".

By the horizontal scanning process, the position information of the dots existing on the left edge of the frame region 353a and the position information of the dots existing on the right edge of the frame region 353a are stored. The position information of the left dot is associated with an integer of any one of "second switching value + 1" to "third switching value". Further, the dot position information on the right side is associated with an integer of any one of “third switching value+1” to “upper limit value”.

Returning to the description of the cloud drawing data creation processing (FIG. 37), after performing the horizontal scan processing in step S1806, the current drawing list is referenced in step S1807, and the blurring range data is stored in the memory module 133. The address being read is grasped and read. In a succeeding step S1808, range setting processing for setting the blurring range 366 and the movement destination range 356 in the frame display two-dimensional data 353 is performed. Here, the range setting process will be described with reference to the flowchart of FIG. FIG. 43 is a flowchart showing the range setting process executed by the VDP 135. The range setting process is executed when the blurring instruction information is set in the drawing list.

First, in step S2401, the coordinate group stored in the first half of the vertical scanning process is grasped. The coordinate group includes coordinates of a plurality of dots existing on the upper edge of the frame area 353a. The coordinate group is grasped by grasping the coordinate whose associated scan count is an integer of any one of "1" to "first switching value". In step S2402, for each coordinate forming the coordinate group identified in step S2401, a plurality of blurring ranges 366 are set in the frame display two-dimensional data 353 using the coordinate as the coordinate of the blurring center 366a. As a result, a plurality of blurring ranges 366 are set around the plurality of dots located at the upper edge of the frame area 353a. The blurring range group formed by the plurality of blurring ranges 366 is referred to as a first blurring range group.

In step S2403, a process of subtracting "200" from the value of the y coordinate is performed for each coordinate forming the coordinate group grasped in step S2401. As a result, the range corresponding to the coordinate group is translated upward by 200 dots in the frame display two-dimensional data 353. In step S2404, for each coordinate forming the coordinate group calculated in step S2403, a plurality of blurring ranges 366 are set as the frame display two-dimensional data 353 with the coordinate as the coordinate of the blurring center 366a. Then, the blur range 366 is set as the destination range 356. As a result, a plurality of destination ranges 356 are set above the plurality of blurring ranges 366 set in step S2402. The destination range group composed of the plurality of destination ranges 356 is referred to as a first destination range group.

The movement destination range 356 forming the first movement destination range group is obtained by moving the blurring range 366 forming the first blurring range group upward by 200 dots in parallel. Therefore, the blur range 366 and the destination range 356 have the same number, size, and shape. Each blur range 366 and each destination range 356 have a one-to-one correspondence. The dots forming the corresponding two ranges 356 and 366 also have a one-to-one correspondence.

In step S2405, the coordinate group stored in the latter half of the vertical scanning process is grasped. The coordinate group is composed of the coordinates of a plurality of dots existing on the lower edge of the frame area 353a. The coordinate group is grasped by grasping a coordinate in which the number of associated scans is an integer of any one of “first switching value+1” to “second switching value”. In step S2406, for each coordinate forming the coordinate group grasped in step S2405, a plurality of blurring ranges 366 are set in the frame display two-dimensional data 353 using the coordinate as the coordinate of the blurring center 366a. As a result, a plurality of blurring ranges 366 are set around the plurality of dots located at the lower edge of the frame area 353a. The blurring range group formed by the plurality of blurring range 366 is referred to as a second blurring range group.

In step S2407, a process of adding "200" to the value of the y coordinate is performed for each coordinate forming the coordinate group grasped in step S2405. As a result, the range corresponding to the coordinate group is translated downward by 200 dots in the frame display two-dimensional data 353. In step S2408, for each coordinate forming the coordinate group calculated in step S2407, a plurality of blurring ranges 366 are set as the frame display two-dimensional data 353 with the coordinate as the coordinate of the blurring center 366a. Then, the blur range 366 is set as the destination range 356. As a result, a plurality of destination ranges 356 are set below the plurality of blurring ranges 366 set in step S2406. The destination range group configured by the plurality of destination ranges 356 is referred to as a second destination range group.

The movement destination range 356 forming the second movement destination range group is obtained by moving the blurring range 366 forming the second blurring range group downward by 200 dots in parallel. Therefore, the blur range 366 and the destination range 356 have the same number, size, and shape. Each blur range 366 and each destination range 356 have a one-to-one correspondence. The dots forming the corresponding two ranges 356 and 366 also have a one-to-one correspondence.

In step S2409, the coordinate group stored in the first half of the horizontal scanning process is grasped. The coordinate group includes coordinates of a plurality of dots existing on the left edge of the frame area 353a. The coordinate group is grasped by grasping the coordinate whose associated scan number is an integer of any one of "second switching value + 1" to "third switching value". In step S2410, for each coordinate forming the coordinate group recognized in step S2409, a plurality of blurring ranges 366 are set in the frame display two-dimensional data 353 using the coordinate as the coordinate of the blurring center 366a. As a result, a plurality of blurring ranges 366 are set around the plurality of dots located on the left edge of the frame area 353a. The blurring range group formed by the plurality of blurring range 366 is referred to as a third blurring range group.

In step S2411, a process of subtracting “200” from the value of the x coordinate is performed for each coordinate forming the coordinate group grasped in step S2409. As a result, the range corresponding to the coordinate group is translated leftward by 200 dots in the frame display two-dimensional data 353. In step S2412, for each coordinate forming the coordinate group calculated in step S2411, a plurality of blurring ranges 366 are set as the frame display two-dimensional data 353 with the coordinate as the coordinate of the blurring center 366a. Then, the blur range 366 is set as the destination range 356. As a result, a plurality of destination ranges 356 are set to the left of the plurality of blurring ranges 366 set in step S24010. The destination range group configured by the plurality of destination ranges 356 is referred to as a third destination range group.

The movement destination range 356 forming the third movement destination range group is obtained by moving the blurring range 366 forming the third blurring range group in parallel to the left by 200 dots. Therefore, the blur range 366 and the destination range 356 have the same number, size, and shape. Each blur range 366 and each destination range 356 have a one-to-one correspondence. The dots forming the corresponding two ranges 356 and 366 also have a one-to-one correspondence.

In step S2413, the coordinate group stored in the latter half of the horizontal scanning process is grasped. The coordinate group includes coordinates of a plurality of dots existing on the right edge of the frame area 353a. The coordinate group is grasped by grasping a coordinate whose associated scan count is an integer of any one of “third switching value+1” to “upper limit value”. In step S2414, for each coordinate forming the coordinate group recognized in step S2413, a plurality of blurring ranges 366 are set in the frame display two-dimensional data 353 using the coordinate as the coordinate of the blurring center 366a. As a result, a plurality of blurring ranges 366 are set around the plurality of dots located on the right edge of the frame area 353a. The blurring range group formed by the plurality of blurring range 366 is referred to as a fourth blurring range group.

In step S2415, a process of adding “200” to the value of the x coordinate of each coordinate forming the coordinate group grasped in step S2413 is performed. As a result, the range corresponding to the coordinate group is translated rightward by 200 dots in the frame display two-dimensional data 353. In step S2416, for each coordinate forming the coordinate group calculated in step S2415, a plurality of blurring ranges 366 are set as the frame display two-dimensional data 353 with the coordinate as the coordinate of the blurring center 366a. Then, the blurring range 366 is set as the movement destination range 356, and the range setting process ends. As a result, a plurality of destination ranges 356 are set to the right of the plurality of blurring ranges 366 set in step S2414. The destination range group composed of the plurality of destination ranges 356 is referred to as a fourth destination range group.

The movement destination range 356 forming the fourth movement destination range group is obtained by moving the blurring range 366 forming the fourth blurring range group rightward by 200 dots in parallel. Therefore, the blur range 366 and the destination range 356 have the same number, size, and shape. Each blur range 366 and each destination range 356 have a one-to-one correspondence. The dots forming the corresponding two ranges 356 and 366 also have a one-to-one correspondence.

Returning to the description of the cloud drawing data creation process (FIG. 37 ), after performing the range setting process in step S1808, in step S1809, in step S1808, the first blur range group to the fourth blur range group and the first blur range group. For the frame display two-dimensional data 353 for which the moving destination range group to the fourth moving destination range group have been set, a moving process of color information and the like is performed. Here, the moving process of the color information and the like will be described with reference to the flowchart of FIG. The color information and the like include color information and transparency information. FIG. 44 is a flowchart showing the moving process of the color information and the like executed by the VDP 135. The moving process of the color information and the like is executed when the blurring instruction information is set in the drawing list.

First, in step S2501, the blur range group to which the color information and the transparency information are to be moved is updated. Specifically, the first blurring range group is set when nothing is set as the target blurring range group, and when the first blurring range group is set as the target blurring range group, the first blurring range group is set. 2 Set a blur range group. When the second blurring range group is set as the target blurring range group, the third blurring range group is set, and when the third blurring range group is set as the target blurring range group. The fourth blur range group is set.

In step S2502, the blurring range 366 of the target for moving the color information and the transparency information is updated. The blurring range 366 is updated in such a manner that all the blurring ranges 366 forming the currently set blurring range group are sequentially targeted once. In step S2503, all the dots forming the currently set blurring range 366 are sequentially processed once as target dots.

In step S2504, the color information and the transparency information of the current target dot are stored, and in step S2505, the completely transparent transparency information is set in the current target dot. In step S2506, the dot corresponding to the current target dot is recognized. The corresponding dots are the dots forming the movement destination range 356 corresponding to the target blurring range 366. In the following step S2507, the color information and the transparency information stored in step S2504 are set to the dots grasped in step S2506.

In step S2508, it is determined whether or not the process of moving the color information and the transparency information has been executed for all the dots forming the blurring range 366 which is the current target. When there is a dot for which the process of moving the color information and the transparency information has not been performed (step S2508: NO), the process returns to step S2503 to update the target dot, and the color information and transparency of the new target dot are updated. Perform the process of moving information. When there is no dot for which the process of moving the color information and the transparency information has not been performed (step S2508: YES), the process proceeds to step S2509.

In step S2509, it is determined whether or not the process of moving the color information and the transparency information has been executed for all the blurring ranges 366 forming the current blurring range group. When there is a blurring range 366 for which the process of moving the color information and the transparency information has not been performed (step S2509: NO), the process returns to step S2502 to update the target blurring range 366, and a new blurring range 366. Processing for moving the color information and the transparency information of the. If there is no blurring range 366 for which the process of moving the color information and the transparency information is not performed (step S2509: YES), the process proceeds to step S2510.

In step S2510, it is determined whether or not the process of moving the color information and the transparency information has been executed for all the blurring range groups up to the fourth blurring range group. When there is a blurring range group for which the process of moving the color information and the transparency information has not been performed (step S2510: NO), the process returns to step S2501 to update the target blurring range group, and a new blurring range group. Processing for moving the color information and the transparency information of the. If there is no blur range group for which the process of moving the color information and the transparency information has not been performed (step S2510: YES), the process of moving the main color information and the transparency information ends.

The color information and the transparency information set in the first blurring range group are moved to the first destination range group located above the first blurring range group and set in the second blurring range group. The color information and the transparency information move to the second destination range group located below the second blur range group. Further, the color information and the transparency information set in the third blur range group are moved to the third destination range group located above the third blur range group and set in the fourth blur range group. The existing color information and transparency information are moved to the fourth destination range group located below the fourth blur range group. In any case, the color information and the transparency information set in a part of the frame area 353a are moved to the outer area 353b outside the frame area 353a, and the frame area 353a is blurred and the blurring frame display two-dimensional data is displayed. 367 is created.

Returning to the description of the cloud drawing data creation processing (FIG. 37 ), after performing the movement processing of the color information and the transparency information in step S1809, the processing of steps S1810 to S1812 is executed to display the cloud display data. The two-dimensional data 363 and the blurring frame display two-dimensional data 367 are combined to create cloud drawing data 368. The processing of steps S1810 to S1812 is performed based on the synthesis instruction information set in the drawing list.

In step S1810, the cloud display two-dimensional data 363 is set as the basic data for synthesis. In a succeeding step S1811, the blurring frame display two-dimensional data 367 is set as the combination priority data. Then, in step S1812, the cloud display two-dimensional data 363 and the blurring frame display two-dimensional data 367 are combined.

When the opaque color information is set for the dots of the blurring frame display two-dimensional data 367, the color information set for the corresponding dots of the cloud display two-dimensional data 363 is the blurring frame display two-dimensional data. The opaque color information set in the dots of the data 367 is changed. Further, when the completely transparent transparency information is set for the dots of the blurring frame display two-dimensional data 367, the color information set for the corresponding dots of the cloud display two-dimensional data 363 is not changed. By the composition, cloud drawing data 368 is created.

In step S1813, the cloud drawing data 368 created in step S1812 is saved separately, and the creation process ends. If the use instruction information of separately stored data is set in the drawing list this time (step S1801: YES), the separately stored cloud drawing data 368 is read out in step S1814, and this creation processing is performed. finish. That is, at the update timing at which the relative relationship between the cloud display object 361 and the viewpoint PC11 in the world coordinate system does not change, the cloud drawing data 368 stored separately is used without newly creating the cloud drawing data 368. To do. As a result, the processing load for performing the cloud display effect can be reduced compared to the case where the cloud drawing data 368 is created at all update timings.

As described above, the clipping object 364 is an object in which the cloud display object 361 is made smaller by reducing the cloud display object 361 around the center point 361a. The parameters for setting the clipping object 364 in the world coordinate system are the same as the parameters for setting the cloud display object 361 in the world coordinate system. Therefore, when the area corresponding to the clipping projection area 351a is cut out from the cloud display two-dimensional data 363, the frame display two-dimensional data 353 in which only the outer edge of the cloud display projection area 352a is displayed is created. You can When the relationship between the cloud display object 361 and the viewpoint PC11 in the world coordinate system changes, the shape and size of the cloud display projection area 352a change, but the shape and size of the clipping projection area 351a change in the same manner as the change. Since the size also changes, it is possible to create the frame display two-dimensional data 353 in which only the outer edge of the cloud display projection area 352a is always displayed. The amount of data stored in advance in the memory module 133 is reduced as compared with the configuration in which the different two-dimensional frame display data 353 is stored by the number of relationships between the cloud display object 361 and the viewpoint PC 11 in the world coordinate system. can do.

When the projection data 351 of the clipping object 364 is created, the α value of “0” is set in the clipping projection area 351a, and the α value of “1” is set in the peripheral area 351b. Further, the cloud display two-dimensional data 363 is set as the cutout target data, the projection data 351 of the cutout object 364 is set as the cutout data, and the cutout process is executed. The region of the clipping target data corresponding to the region in which the α value is set is cut out. Thereby, the frame display two-dimensional data 353 according to the relationship between the cloud display object 361 and the viewpoint PC 11 can be created in real time. Compared with the configuration in which the frame display two-dimensional data 353 is stored, the data capacity stored in advance in the memory module 133 can be reduced.

The cloud drawing data 368 created at the start timing and the update timing at which the relationship between the cloud display object 361 and the viewpoint PC 11 changes is saved separately, and at the update timing at which the relationship between the cloud display object 361 and the viewpoint PC 11 does not change. In the configuration described above, the cloud drawing data 368 that is separately stored is read and used without creating the cloud drawing data 368. Compared with the case of performing the process of creating the frame display two-dimensional data 353 at all update timings, the processing load for performing the cloud display effect can be reduced.

Using the blurring range data, the blurring ranges 366 are set in a plurality of locations in the frame area 353a, and the movement destination ranges 356 are set in a plurality of locations in the outer area 353b, and the color information and transparency set in the blurring range 366 are set. By moving the information to the movement destination range 356, the blurring frame display two-dimensional data 367 can be created. Then, by using the blurring frame display two-dimensional data 367, the outer edge portion of the cloud display projection area 352a having a linear and angular shape is changed to a complicated outer edge portion having unevenness, thereby creating a natural cloud. Display effect can be performed.

A vertical scan process and a horizontal scan process are performed on the frame display two-dimensional data 353 to determine the coordinates of the blurring center 366a. In the first half of the vertical scanning process, the dots are sequentially scanned downward from the dots at the upper end of the scan target row, and the coordinates of the dots located at the upper edge of the frame area 353a become the coordinates of the blurring center 366a. Further, in the latter half of the vertical scanning process, the dots are sequentially scanned upward from the bottom dot of the scan target row, and the coordinates of the dots located at the lower edge of the frame area 353a become the coordinates of the blurring center 366a. .. In the first half of the horizontal scanning process, scanning is performed in order from the leftmost dot of the scan target column toward the right, and the coordinates of the dot located at the left edge of the frame area 353a become the coordinates of the blurring center 366a. In the latter half of the horizontal scanning process, scanning is performed in order from the rightmost dot of the scan target column to the left, and the coordinates of the dot located at the right edge of the frame area 353a become the coordinates of the blurring center 366a. .. Therefore, the blurring range 366 can be set on the outer edge of the frame area 353a, and the outer edge of the frame area 353a can be blurred. Compared with the configuration in which the blurring range 366 is randomly determined, the blurring process of the frame area 353a can be executed efficiently.

The destination range 356 corresponding to the blurring range 366 set near the upper edge of the frame area 353a is set above the blurring range 366, and the blurring range 366 is set near the lower edge of the frame area 353a. The corresponding destination range 356 is set below the blurring range 366. The destination range 356 corresponding to the blurring range 366 set near the left edge of the frame region 353a is set to the left of the blurring range 366, and the blurring range set near the right edge of the frame region 353a. The destination range 356 corresponding to 366 is set to the right of the blurring range 366. Accordingly, it is possible to set all the movement destination ranges 356 in the outer area 353b, and selectively move the color information and the transparency information of the frame area 353a toward only the outer side. Unlike the configuration in which the destination range 356 is randomly determined, the cloud drawing data 368 can be created in a manner that does not change the contents of the color information and the transparency information set in the cloud display projection area 352a. ..

<Another form of cloud display production>
In the configuration for executing the cloud display effect described above, the process of creating the projection data 351 of the clipping object 364 has the same shape as the cloud displaying object 361, and is a size smaller than the cloud displaying object 361. The processing is not limited to using the object 364. For example, instead of the clipping object 364, the reduced data of the cloud display object 361 may be arranged in the world coordinate system.

Specifically, the display CPU 131 creates a normal parameter for setting the cloud display object 361 in the world coordinate system, and a cutout parameter in which only the scale information is set to be slightly smaller in the normal parameter. And set it in the drawing list.

The VDP 135 sets the cloud display object 361 in the world coordinate system based on the normal parameters and projects it on the screen region PC12 to create normal projection data 352 of the cloud display object 361. Further, the VDP 135 sets the cloud display object 361 in the world coordinate system based on the cutout parameter and projects it on the screen area PC12 to create projection data for cutout of the cloud display object 361. Since a smaller scale than the normal parameter is set for the cutout parameter, the cutout projection data is the same data as the cutout object 364 projection data 351.

Since the same data as the projection data 351 of the clipping object 364 can be created without using the clipping object 364, the data capacity of the object stored in advance in the memory module 133 can be reduced.

In addition, the processing for displaying the boundary 369 of the cloud display two-dimensional data 363 in an inconspicuous manner is performed by forming the blurring frame area 367a in the dots forming the periphery of the boundary 369 of the cloud display two-dimensional data 363. The process is not limited to the process of overwriting the color information and the transparency information set in the existing dots. For example, color information and transparency information intermediate between the sky color and the background color of the cloud display texture 362 are set in the cloud display projection area 352a. By cutting out the clipping projection area 351a from the cloud display projection area 352a, the frame display two-dimensional data 353 including the intermediate color frame area 353a can be created. By overwriting the color information and the transparency information set in the dots forming the intermediate color frame area 353a on the dots forming the periphery of the boundary 369 of the two-dimensional data 363 for cloud display, In the two-dimensional data 363, the boundary 369 between the region to which the cloud display texture 362 is applied and the background can be displayed in an inconspicuous manner.

Further, the process of creating the cloud drawing data 368 is not limited to the process involving the clipping process. For example, after the cloud display two-dimensional data 363 is created, the blurring process executed in steps S1805 to S1809 of the cloud drawing data creation processing (FIG. 37) is performed on the cloud display two-dimensional data. May be. By the blurring process, the boundary 369 of the cloud display two-dimensional data 363 can be blurred. Further, even if the blurring process is executed on the cloud display two-dimensional data 363, only the vicinity of the boundary 369 is subject to the blurring process, and the contents of the area inside the boundary are maintained. Therefore, the cloud drawing data 368 can be created while reducing the processing load.

The position of the center corresponding point 352c in the projection data 352 of the cloud display object 361 may not be the same as the position of the center corresponding point 351c in the projection data 351 of the clipping object 364. Furthermore, the size and outline of the projection data 352 of the cloud display object 361 do not have to be the same as the size and outline of the projection data 351 of the clipping object 364.

In short, the center corresponding point 352c of the projection data 352 of the cloud display object 361 and the center corresponding point 351c of the projection data 351 of the cutout object 364 are matched with each other from the cloud display projection area 352a. It suffices if the 351a can be cut out. For example, the cutout projection area 351a is configured in such a manner that the center corresponding point 352c of the projection data 352 of the cloud display object 361 and the center corresponding point 351c of the projection data 351 of the cutout object 364 have a one-to-one correspondence. A position correction table for making a one-to-one correspondence between each dot and the dots forming the cloud display projection area 352a is stored in the memory module 133 in advance. The cut-out projection area 351a can be cut out.

Further, the blurring process is not limited to the process of moving the color information and the transparency information set in the dots forming the blurring range 366 to the dots forming the movement destination range 356. For example, the color information and the transparency information to be set in the destination range 356 are stored in advance, and the color information and the transparency information are uniformly set in all the destination ranges 356 set in the outer area 353b. It may be configured. Color information for setting all the destination ranges 356 as compared with the configuration in which the color information and the transparency information set in the dots forming the corresponding blur range 366 are grasped and set in the destination range 356. By sharing the transparency information and the transparency information, it is possible to omit the process of grasping the color information and the transparency information set in each blurring range 366, and reduce the processing load of the blurring process.

Further, the number of cloud display objects 361 set in the world coordinate system is not limited to one. For example, a plurality of cloud display objects 361 may be set in the world coordinate system to display a state in which a plurality of clouds 362a are arranged side by side. To rotate a plurality of cloud display objects 361 set in the world coordinate system and display a group of a plurality of clouds 362a viewed from different angles, to shift the timing of rotating the plurality of cloud display objects 361. Thus, it is possible to increase the number of cloud groups 362a that can be displayed while suppressing an increase in processing load.

A case in which a group of three clouds 362a having different distances from the viewpoint PC 11 is displayed and the display angle of the group of the three clouds 362a is gradually changed while the processing load is suppressed is specifically described. To do.

The cloud from which the distance from the viewpoint PC11 is the shortest and which is displayed closest to the foreground on the display surface G of the symbol display device 31 is the first cloud group and the cloud for displaying the first cloud group. The drawing data 368 is the drawing data for the first cloud. In addition, a group of clouds 362a that has the longest distance from the viewpoint PC 11 and is displayed on the deepest side on the display surface G of the symbol display device 31 is a third cloud group, and is for displaying the third cloud group. The cloud drawing data 368 is set as the third cloud drawing data. Then, the distance from the viewpoint PC11 is the second shortest, and the cloud group displayed between the first cloud group and the third cloud group on the display surface G of the symbol display device 31 is the second cloud group, and The cloud drawing data 368 for displaying the second cloud group is set as the second cloud drawing data.

Each of the third cloud drawing data, the second cloud drawing data, the first cloud drawing data, and the pattern drawing data is individually written in the screen buffer 144. The VDP 135 creates drawing data for effects and symbols by writing four drawing data to the screen buffer 144. Specifically, the drawing data for the third cloud is arranged at the deepest side, the drawing data for the second cloud is secondly arranged at the back side, the drawing data for the first cloud is thirdly arranged at the back side, and the pattern The four drawing data are written in such a manner that the drawing data for use are arranged on the front side.

The VDP 135 newly sets the drawing data for the first cloud, the drawing data for the second cloud, and the drawing data for the third cloud at the update timing when the parameter of the cloud display object 361 that sets the world coordinate system changes. Created in and saved separately. At the update timing when the parameters of the cloud display object 361 set in the world coordinate system do not change, the separately saved drawing data is read and used. Therefore, the processing load at the update timing for newly creating the drawing data for displaying the cloud group is large, and the processing load at the update timing for using the separately stored drawing data is small.

When displaying an image of three cloud groups when viewed from a different angle from the image of the three cloud groups currently displayed on the display surface G of the symbol display device 31, the cloud display object 361 is displayed in the world coordinate system. If the processing for changing only the parameter of the viewpoint PC 11 is performed without changing the parameter for setting the, the drawing data for the first cloud, the drawing data for the second cloud, and the drawing data for the third cloud Will be created at the same time, and the processing load at the update timing will be larger than at other update timings. Also, when the parameters of the three cloud display objects 361 for displaying the three cloud groups are changed at one update timing without changing the parameters of the viewpoint PC 11, the three cloud drawing data 368 will be newly created at the same time. In these cases, it is necessary to have a configuration that can withstand a processing load with a large update timing for newly creating three cloud drawing data 368 at the same time.

On the other hand, by shifting the timings of changing the three rotation angles for setting the three cloud display objects 361 in the world coordinate system, it is possible to suppress an increase in processing load. First, at the first update timing, only the rotation angle of the cloud display object 361 for displaying the first cloud group located closest to the front side is changed, and only the first cloud drawing data is newly created. At the subsequent second update timing, only the rotation angle of the cloud display object 361 for displaying the second cloud group located second in front is changed, and only the second cloud drawing data is newly created. Then, at the third update timing, only the rotation angle of the cloud display object 361 for displaying the third cloud group located on the innermost side is changed, and only the third cloud drawing data is newly created.

By distributing the processing load for newly creating the three cloud drawing data 368 to three update timings, the amount of processing required at a specific update timing is extremely increased as compared with other update timings. The situation can be avoided. In this case, since the display angle of the cloud group changes in order from the front side to the back side, there is little discomfort given to the player by shifting the timing of changing the display angle.

Further, only the cloud drawing data 368 at the start timing may be stored in advance, or only the first cloud group may be displayed at the start timing to gradually increase the number of cloud groups to be displayed. By doing so, the number of newly created cloud drawing data 368 can be reduced at the start timing. The processing capacity required for the display control device 130 can be reduced by adopting a configuration in which there is no timing to newly create two or more cloud drawing data 368 at the start timing and all update timings.

<Structure for performing aura display production>
Next, a configuration for performing an aura display effect will be described. The character 371 displayed in the aura display effect includes a head 372, a right arm 373, a right hand 374, a body 375, a left leg 376, and a right leg 377. In the aura display effect, auras 412 to 417 are displayed on the outer edges of the respective parts 372 to 377 of the character 371. When the parts 372 to 377 forming the character 371 are displayed in an overlapping manner in the front-rear direction of the display surface G of the symbol display device 31, by displaying the auras 412 to 417 also in the overlapping portion, the character 371 is displayed. It is possible to uniformly display the auras 412 to 417 with respect to the respective parts 372 to 377.

The aura display effect is performed as an effect for notifying the expectation level of the jackpot. In the high-anticipation effect in which the expectation of a big hit is high, the time when the character 421 with an aura is displayed is set longer than the time when the character 371 without the auras 412 to 417 is displayed. On the other hand, in the low-anticipation effect where the jackpot expectation is low, the time when the character 371 without the auras 412 to 417 is displayed is set longer than the time when the character with the aura 421 is displayed. The content of the data table for high-expectation performance is different from the content of the data table for low-expectation performance. Switching between the character 421 with an aura and the character 371 without the auras 412 to 417 is performed based on the set data table.

In the aura display effect, the timing at which the image of the character 371 or the image of the character with aura 421 is independently displayed as an image for effect, the image of the character 371 or the image of the character with aura 421, the character 371 or the character with an aura. There is a timing when an image for displaying the points owned by the 421 is displayed together. Character drawing data 371a (FIG. 45(a)) for displaying the character 371, aura character drawing data 421a (FIG. 45(b)) for displaying the aura character 421, and points are displayed. Each of the drawing data for points for is created individually. Note that the drawing data for points is created by applying the texture for displaying points to the projection data of the object for displaying points. Hereinafter, the character drawing data 371a and the aura-added character drawing data 421a will be described.

In the aura display effect, the drawing data 421a for characters with an aura is created, so that the character 371 with the auras 412 to 417 is displayed on the display surface G of the symbol display device 31. First, the drawing data 421a for characters with an aura will be described. 45A shows the character drawing data 371a in which the auras 412 to 417 are not displayed, and FIG. 45B shows the character drawing data 421a with auras in which the auras 412 to 417 are displayed. The VDP 135 creates the character drawing data 371a or the aura-added character drawing data 421a as the effect drawing data. As shown in FIG. 45A, the character drawing data 371a is data for displaying the right side surface of the character 371.

The memory module 133 stores six character objects for displaying the respective parts 372 to 377 of the character 371, and six partial textures corresponding to the six character objects. Here, the character object includes a head object 372a (FIG. 46A) for displaying the head 372 of the character 371, a right arm part object for displaying the right arm part 373, and a right hand part 374. Right hand object for displaying, torso object for displaying torso 375, left leg object for displaying left leg 376, and right leg for displaying right leg 377 A generic term for objects.

Further, the partial texture refers to a head texture corresponding to the head object 372a, a right arm texture corresponding to the right arm object, a right hand texture corresponding to the right hand object, and a torso object. It is a general term for the corresponding body texture, the left leg texture corresponding to the left leg object, and the right leg texture corresponding to the right leg object.

The textures for the six parts are set in a UV coordinate system different from the world coordinate system. Corresponding UV coordinate values are set for each dot on the surface of the character object. Further, the projection of the character object onto the screen area PC12 is performed in such a manner that the dot information on the surface of the character object projected on each dot of the projection data can be grasped.

The VDP 135 grasps the dot information on the surface of the character object corresponding to each dot of the projection data, and grasps the coordinate value of the UV coordinate system corresponding to the dot on the surface of the character object. Then, the color information set in the coordinate value of the partial texture set in the UV coordinate system is set in each dot of the projection data. As a result, the partial texture is applied to the projection data of the character object. In the aura display effect, since the size of the screen area PC12 onto which the object is projected is the same as the size of the display surface G of the symbol display device 31, the size of the projection data created by projection is also the symbol display device 31. The size is the same as the size of the display surface G.

As shown in FIG. 45( b ), the drawing data for character with aura 421 a is composed of respective parts 372 to 377 forming the character 371 and auras 412 to 417 of the respective parts 372 to 377. Specifically, the aura 412 of the head 372 is displayed on the outer edge of the head 372 of the character 371, the aura 413 of the right arm 373 is displayed on the outer edge of the right arm 373, and the aura 412 of the right hand 374 is displayed. The aura 414 of the right hand portion 374 is displayed on the outer edge. Further, the aura 415 of the body 375 is displayed on the outer edge of the body 375 of the character 371, the aura 416 of the left leg 376 is displayed on the outer edge of the left leg 376, and the aura 416 of the right leg 377 is displayed. The aura 417 of the right leg 377 is displayed on the outer edge.

In the drawing data for character with aura 421a, the aura 413 of the right arm 373 is displayed on the outer edge of the right arm 373 displayed in a manner overlapping with the body 375 of the character 371, and also overlaps with the body 375 of the character 371. The aura 414 of the right-hand part 374 is displayed on the outer edge of the right-hand part 374 displayed in the mode. Further, the torso 375 of the character 371 is displayed in such a manner as to partially overlap the left leg 376, and the aura 415 of the torso 375 is also displayed for the overlapping portion. Similarly, the right leg 377 of the character 371 is displayed in such a manner as to partially overlap the left leg 376, and the aura 417 of the right leg 377 is also displayed for the overlapping portion.

When the auras 412 to 417 are displayed only on the outer frame of the character 371, when a part of the character 371 is displayed in a manner overlapping with other parts, the auras 412 to 417 corresponding to the overlapped parts are displayed. It disappears. For example, the aura 413 of the right arm portion 373 of the character 371 is displayed when the character 371 faces front, but is not displayed when the character 371 faces sideways. As described above, the presence or absence of the display of the auras 412 to 417 changes depending on the direction of the character 371, so that the aura display effect gives an unnatural impression to the player. On the other hand, when a part of the character 371 is displayed in such a manner as to overlap with another part, the auras 412 to 417 are displayed in the overlapping part for the outer edge of the part located closer to the viewpoint PC11. A natural aura display production can be performed.

The aura-added character drawing data 421a includes aura-added part two-dimensional data 412a to 417a (FIGS. 47(a) to (f)) corresponding to the respective parts 372 to 377 forming the character 371 in the screen buffer 144. It is created by writing in the effect buffer of the display effect. Here, the two-dimensional data 412 a to 417 a for aura-attached parts relates to the two-dimensional data 412 a for a head with aura regarding the head 372, the two-dimensional data 413 a for a right arm with aura regarding the right arm 373, and the right-hand part 374. Two-dimensional data 414a for a right hand part with aura, two-dimensional data 415a for a torso with an aura regarding the torso 375, two-dimensional data 416a for a left leg with an aura for the left leg 376, and an aura for the right leg 377. It is a generic term for the right leg two-dimensional data 417a.

Hereinafter, a method of creating the two-dimensional data 412a to 417a for aura-attached portions will be described using the head 372 as a specific example. FIG. 46A is an explanatory diagram for explaining the head object 372a, and FIG. 46B is a diagram for explaining head projection data 372b that is the projection data of the head object 372a. FIG. Further, FIG. 46(c) is an explanatory diagram for explaining the head aura object 382a, and FIG. 46(d) is an aura head projection data 382b which is projection data of the head aura object 382a. It is an explanatory view for explaining. The head aura object 382a is stored in advance in the memory module 133.

First, a process of creating the head projection data 372b and the aura head projection data 382b will be described. The head object 372a has a center point 372e inside thereof. The head aura object 382a is an object having the same structure as the structure obtained by enlarging the head object 372a at a magnification of 125% around the center point 372e of the head object 372a. Therefore, the head aura object 382a has the same shape as the head object 372a. Further, the head aura object 382a has a center point 382e similarly to the head object 372a. The head aura object 382a is slightly larger than the head object 372a.

The memory module 133 stores a character parameter table for setting the character object in the world coordinate system. In the character parameter table, a plurality of pointer information corresponding to the update timing when the parameter of the character object in the world coordinate system is changed and the update timing when the parameter of the viewpoint PC 11 is changed are set. A parameter for setting the character object in the world coordinate system is set in each of the pointer information. Here, the parameter of the character object includes the coordinate, the rotation angle, and the scale of the character object, and the parameter of the viewpoint PC 11 includes the coordinate and the direction.

The coordinates of the character object are the coordinates of the center point of the character object. In addition, the character object may be enlarged or reduced from the initial size and set in the world coordinate system. The scale, which is one of the parameters of the character object, is the magnification from the initial state. When the character object is enlarged from the initial state and set in the world coordinate system, the scale becomes a value larger than 100%, and when the character object is reduced from the initial state and set in the world coordinate system. Has a value smaller than 100 percent. Further, when the character object has the same size as the initial state and is set in the world coordinate system, the scale value is 100%.

The display CPU 131 refers to the character parameter table and sets the parameter of the character object at each timing in the drawing list. As shown in FIG. 46A, the VDP 135 has a mode in which the center point 372e of the head object 372a is located at the coordinate based on the parameter including the coordinate of the head object 372a set in the drawing list. The head object 372a is set to world coordinates with.

The display CPU 131 sets the same parameter as the parameter of the head object 372a in the drawing list as the parameter of the head aura object 382a. Specifically, the same coordinates as the coordinates of the center point 372e of the head object 372a are set as the coordinates of the center point 382e of the head aura object 382a. The same value as the rotation angle and scale of the head object 372a is set as the rotation angle and scale of the head aura object 382a.

In the initial state, the head aura object 382a is slightly larger than the head object 372a. Then, the magnification for setting the head object 372a in the world coordinate system and the magnification for setting the head aura object 382a in the world coordinate system are always the same. Therefore, at the start timing and each update timing, the head aura object 382a is set in the world coordinate system in a mode slightly larger than the head object 372a set in the world coordinate system at the timing. As shown in FIG. 46C, the VDP 135 positions the center point 382e of the head aura object 382a at the coordinate based on the parameter including the coordinate of the head object 372a set in the drawing list. In this manner, the head aura object 382a is set in the world coordinate system.

Since the head object 372a and the head aura object 382a are set based on the same parameters, the coordinates and rotation angles of the center points 372e and 382e of the two objects 372a and 382a in the world coordinate system are the same. is there. Further, the magnification of the enlargement or reduction performed when setting the two objects 372a and 382a in the world coordinate system is the same. Therefore, in the world coordinate system, the head aura object 382a is always one size larger than the head object 372a.

As shown in FIGS. 46B and 46D, rectangular projection data 372b and 382b are created by projecting the head object 372a or the head aura object 382a onto the screen area PC12. In the aura display effect, the shape and size of projection data obtained by projecting an object on the screen area PC12 are the same as the shape and size of the projected screen area PC12. The shape and size of the two-dimensional data created using the projection data are the same as the shape and size of the projection data. Specifically, the projection data and the two-dimensional data are rectangular data having a size corresponding to the display surface G of the symbol display device 31. The same number of dots are arranged in the horizontal direction of the projection data and the two-dimensional data created by the aura display effect, and the same number of dots are also arranged in the vertical direction of the projection data and the two-dimensional data.

In the rectangular projection data obtained by projecting the object on the screen area PC12, the area formed by the dots actually projected by the object is defined as the projection area. The shape of the projection area is the outline of the object at the angle at which the object is projected. At each timing, the angle at which the head aura object 382a is projected is always the same as the angle at which the head object 372a is projected. Therefore, the aura head projection which is the projection area of the head aura object 382a is projected. The shape of the area 382c is the same as the head projection area 372c which is the projection area of the head object 372a. The size of the aura head projection area 382c is slightly larger than the size of the head projection area 372c.

In the head projection data 372b, a region other than the head projection region 372c is set as a peripheral region 372d, and in the aura head projection data 382b, a region other than the aura head projection region 382c is set as a peripheral region 382d. ..

In the world coordinate system, a perpendicular is drawn from the center point 372e of the head object 372a to the screen area PC12, and the intersection of the perpendicular and the screen area PC12 is the center corresponding point 372f of the head object 372a (FIG. 46(b)). And Also, in the world coordinate system, a perpendicular is drawn from the center point 382e of the head aura object 382a to the screen area PC12, and the intersection of the perpendicular and the screen area PC12 is the center corresponding point 382f of the head aura object 382a (FIG. 46). (D)).

Since the coordinates of the center point 372e of the head object 372a in the world coordinate system and the coordinates of the center point 382e of the head aura object 382a are the same, the center corresponding point 372f of the head object 372a in the screen area PC12. And the position of the center corresponding point 382f of the head aura object 382a are the same. The position of the center corresponding point 372f of the head object 372a in the head projection data 372b is the same as the position of the center corresponding point 382f of the head aura object 382a in the aura head projection data 382b.

Specifically, the positional relationship between the dot in the upper left corner of the head projection data 372b and the center corresponding point 372f of the head object 372a is in the upper left corner of the aura head projection data 382b. The positional relationship between the dot and the center corresponding point 382f of the head aura object 382a is the same.

The angle when the head object 372a is projected on the screen area PC12 is the same as the angle when the head aura object 382a is projected on the screen area PC12. According to the above relationship, the aura head projection area 382c of the head aura object 382a has the head projection area 372c in the head projection data 372b with the center corresponding point 372f of the head object 372a as the center. This is the same as the area expanded to 125%.

When the head projection data 372b is created, the VDP 135 stores the head projection data 372b separately. Specifically, the head projection data 372b is separately stored in the aura display effect buffer provided in the screen buffer 144. After that, the VDP 135 sets the α value of “0” to all the dots forming the head projection area 372c in the head projection data 372b, and sets “1” to all the dots forming the peripheral area 372d. The α value of is set to create head projection data for clipping.

Further, when the VDP head projection data 382b is created, the VDP 135 sets the color information and the transparency information for aura display to all the dots forming the aura head projection area 382c, and also the peripheral area 382d. The α value of “0” is set to all the dots forming The color information and the transparency information for displaying the aura are stored in the memory module 133 in advance. Specifically, semitransparent red color is stored as the color information and the transparency information for the aura display. Regarding the transparency information, more specifically, “0.3” is stored as the α value.

Next, a process of cutting out an area corresponding to the head projection area 372c from the aura head projection data 382b and creating the head aura two-dimensional data 392a (FIG. 46(e)) will be described. Here, in the two-dimensional data, cutting out a predetermined area means setting transparency information of complete transmission in the predetermined area.

The VDP 135 sets the aura head projection data 382b as the clipping target data, sets the clipping head projection data as the clipping data, and performs the clipping processing (FIG. 40). In the cutout process, it is first determined whether or not the α value set for each dot forming the cutout head projection data that is the cutout data is “0”.

When the α value set to the dot of the cutout head projection data is “0”, complete transparency information is set to the corresponding dot of the cutout target data of the aura head projection data 382b. To be done. When the α value set in the dot of the cutout head projection data is not “0”, the color information set in the corresponding dot of the aura head projection data 382b that is the cutout target data and Transparency information is maintained. In the head projection data 372b, since the α value of “0” is set in the head projection area 372c, the area corresponding to the head projection area 372c in the aura head projection data 382b. Is cut out and two-dimensional data 392a for head aura is created.

FIG. 46(e) is an explanatory diagram for explaining the two-dimensional data 392a for the head aura. In the cutout process, in the aura head projection data 382b, only the outer edge portion of the aura head projection area 382c remains without being cut out, and becomes a ring-shaped head aura area 392. In the head aura area 392, red semitransparent color information and transparency information are set. In the head aura two-dimensional data 392a, the inside of the head aura area 392 is an inside area 392b in which the transparency information of complete transmission is set. The outside of the head aura area 392 is an outside area 392c in which the transparency information of complete transmission is set.

Next, a process of creating the blurring two-dimensional data 412b for the head aura (FIG. 46F) will be described. In the aura display effect, the head aura two-dimensional data 392a is subjected to blurring processing in order to display how the aura displayed around the character 371 fluctuates, and head aura two-dimensional data 412b is created. To be done. The blurring process includes a vertical scanning process (FIG. 41), a horizontal scanning process (FIG. 42), a range setting process (FIG. 43), and a moving process (FIG. 44) of color information and the like.

First, a vertical scan process and a horizontal scan process are performed on the two-dimensional data 392a for the head aura. In the vertical scanning process, the dots arranged in one vertical line are scanned, and in the horizontal scanning process, the dots arranged in one horizontal line are scanned.

Here, in the scan, the target dot is determined from the dots arranged in the row of the scan target dot, and it is determined whether or not the α value set to the dot is “0”. Done. The target dots are updated sequentially. Dot updating is continued until a dot having an α value other than “0” appears. When a dot for which an α value other than “0” is set appears, the position information of the dot is stored and the target column is updated.

In the first half of the vertical scanning process, the head aura two-dimensional data 392a is scanned from above to below. In the latter half of the vertical scanning process, the head aura two-dimensional data 392a is scanned from below to above. Here, the vertical scanning process performed in the aura display effect is performed at 500 dot intervals while shifting the target column in the positive direction of the x axis, similarly to the vertical scanning process (FIG. 41) performed in the cloud display effect. Be seen. The coordinates of a plurality of dots located at the upper edge of the head aura area 392 are stored at 500 dot intervals in the first half of the vertical scan processing, and the coordinates of the lower part of the head aura area 392 in the second half of the vertical scan processing are stored. The coordinates of a plurality of dots located at the edge are stored at intervals of 500 dots.

In the first half of the horizontal scanning process, the head aura two-dimensional data 392a is scanned from left to right. In the latter half of the horizontal scanning process, the head aura two-dimensional data 392a is scanned from right to left. Here, the horizontal scanning process performed in the aura display effect is performed at 500 dot intervals while shifting the target column in the positive direction of the y-axis, similarly to the horizontal scanning process (FIG. 42) performed in the cloud display effect. Be seen. The coordinates of a plurality of dots located at the left edge of the head aura area 392 are stored at 500 dot intervals in the first half of the horizontal scan processing, and the right edge of the head aura area 392 is stored in the second half of the horizontal scan processing. Coordinates of a plurality of dots positioned at are stored at intervals of 500 dots.

Next, the range setting process performed on the head aura two-dimensional data 392a will be described. The memory module 133 stores a blurring range table TB1 (FIG. 32(e)) for setting a blurring range 423 (FIG. 46(e)) that is a range for performing blurring processing. The center of the blur range 423 is defined as the blur center 423a. In the blurring range table TB1, the position information of the dots included in the blurring range 423 is set in relation to the coordinates (x, y) of the blurring center 423a, so if the predetermined coordinates are set as the position information of the central dot. The blur range 423 is set around the dot located at the predetermined coordinates.

In the range setting process, the destination range 422 is set as the range to which the color information and the transparency information set in the blur range 423 are moved. The movement destination range 422 is set as a coordinate different from the coordinate of the blurring center 423a for setting the blurring range 423 as the coordinate of the central dot, so that a range different from the blurring range 423 is set, and the range is moved. The destination range 422 is set.

Specifically, the VDP 135 first sets a plurality of coordinates stored in the first half of the vertical scanning process as the coordinates of the blurring center 423a, and thereby sets a plurality of blurring ranges along the upper outer edge of the head aura region 392. 423 is set. The plurality of blurring ranges 423 form a first blurring range group.

Next, the VDP 135 subtracts “200” from the y coordinate value of each coordinate stored in the first half of the vertical scanning process to calculate a new coordinate located above the original coordinate. Then, the new coordinates are set as the coordinates of the central dot, and the movement destination range 422 is set in the head aura two-dimensional data 392a. The movement destination range 422 is set above the blurring range 423 by the same number as the blurring range 423 in a one-to-one correspondence with the blurring range 423. The plurality of destination ranges 422 form a first destination range group.

Next, the VDP 135 sets a plurality of coordinates stored in the latter half of the vertical scanning process as the coordinates of the blurring center 423a, thereby creating a plurality of blurring ranges 423 along the lower outer edge of the head aura region 392. Set. The plurality of blurring ranges 423 form a second blurring range group.

Next, the VDP 135 adds “200” to the y coordinate value of each coordinate stored in the latter half of the vertical scanning process to calculate a new coordinate located below the original coordinate. Then, the new coordinates are set as the coordinates of the central dot, and the movement destination range 422 is set in the head aura two-dimensional data 392a. The movement destination range 422 is set below the blurring range 423 by the same number as the blurring range 423 in a one-to-one correspondence with the blurring range 423. The plurality of destination ranges 422 form a second destination range group.

Next, the VDP 135 sets a plurality of coordinates stored in the first half of the horizontal scanning process as the coordinates of the blurring center 423a, thereby setting a plurality of blurring ranges 423 along the left outer edge of the head aura region 392. To do. The plurality of blurring ranges 423 form a third blurring range group.

Next, the VDP 135 subtracts “200” from the x coordinate value of each coordinate stored in the first half of the horizontal scanning process to calculate a new coordinate located to the left of the original coordinate. Then, the new coordinates are set as the coordinates of the central dot, and the movement destination range 422 is set in the head aura two-dimensional data 392a. The movement destination range 422 is set to the left of the blurring range 423 by the same number as the blurring range 423 in a mode that corresponds to the blurring range 423 on a one-to-one basis. The plurality of destination ranges 422 form a third destination range group.

Next, the VDP 135 sets a plurality of coordinates stored in the latter half of the horizontal scanning process as the coordinates of the blurring center 423a, thereby setting a plurality of blurring ranges 423 along the outer edge on the right side of the head aura region 392. To do. The plurality of blurring ranges 423 form a fourth blurring range group.

Next, the VDP 135 adds "200" to the x coordinate value of each coordinate stored in the latter half of the horizontal scanning process to calculate a new coordinate located to the right of the original coordinate. Then, the new coordinates are set as the coordinates of the central dot, and the movement destination range 422 is set in the head aura two-dimensional data 392a. The destination range 422 is set to the right of the blur range 423 by the same number as the blur range 423 in a mode that corresponds to the blur range 423 on a one-to-one basis. The plurality of destination ranges 422 form a fourth destination range group.

By setting the first blur range group to the fourth blur range group and setting the first destination range group to the fourth blur range group, a plurality of blur ranges 423 are set along the outer edge of the head aura region 392. In addition, a destination range 422 that corresponds to each blurring range 423 on a one-to-one basis is set outside each blurring range 423. The destination range 422 is located in the outer area 392c.

Next, the movement processing of the color information and the like performed on the head aura two-dimensional data 392a will be described. In the moving process of the color information or the like, the color information or the like set in the dots forming each blur range 423 is moved to the dots forming the destination range 422 corresponding to the blur range 423. The color information and the like include color information and transparency information.

Specifically, the VDP 135 stores the color information and the transparency information set in the dots forming the blurring range 423, and sets the color information and the transparency information in the dots forming the corresponding destination range 422. To do. Then, the transparency information of complete transparency is set to the dots forming the blurring range 423. As a result, the color information and the transparency information of a partial area of the outer edge of the head aura area 392 move to the outer area 392c, and the head aura blur two-dimensional data 412b is created.

FIG. 46F is an explanatory diagram for explaining the blurring two-dimensional data 412b for the head aura. The aura 412 of the head 372 in which the outer edge of the head aura region 392 is blurred is present in the head aura blur two-dimensional data 412b. The aura 412 of the head 372 has a ring shape, and color information and transparency information of red semitransparent are set. Inside the aura 412 of the head 372, there is an inner region 412c that is completely transparent, and outside the aura 412 of the head 372, there is an outer region 412d that is completely transparent.

Next, a process of creating the aura-added head two-dimensional data 412a (FIG. 47A) will be described. The aura-added head two-dimensional data 412a is an image in which the aura 412 of the head 372 is added to the image of the head 372 of the character 371. The aura-added head two-dimensional data 412a is composed of head head two-dimensional data created by applying the head texture to the head projection data 372b and head aura blur two-dimensional data 412b. It is created by First, the VDP 135 reads the separately stored head projection data 372b, applies the head texture to the head projection area 372c, and sets the α value of “0” in the peripheral area 372d. , 2D data for the head is created.

Specifically, the UV coordinates of the corresponding head texture are set for each dot on the surface of the head object 372a. Further, the projection of the head object 372a onto the screen area PC12 is performed in such a manner that the dot information on the surface of the head object 372a projected on each dot of the head projection area 372c can be grasped.

The VDP 135 grasps the dot information on the surface of the head object 372a corresponding to each dot of the head projection area 372c, and grasps the coordinate value of the UV coordinate corresponding to the dot on the surface of the head object 372a. .. Then, the color information set in the coordinate values of the head texture existing in the UV coordinate system is set in each dot of the head projection area 372c. As a result, the head texture is applied to the head projection data 372b.

The VDP 135 creates the aura-added head two-dimensional data 412a by synthesizing the head two-dimensional data and the head aura blurring two-dimensional data 412b. Specifically, the VDP 135 sets the head two-dimensional data as the basic data, sets the head aura blur two-dimensional data 412b as the priority data, and executes the combining process. In the synthesizing process, the color information set in each dot forming the two-dimensional head data, which is the basic data, is set in each dot forming the two-dimensional head blur data 412b, which is the corresponding priority data. This is performed by changing the color information and the transparency information according to the information.

Here, the head aura blur two-dimensional data 412b includes an aura 412 of the head 372, an inner region 412c, and an outer region 412d. In the aura 412 of the head 372, the dots included in the area in which the blur range 423 is set have an α value of “0” and the dots included in the area in which the blur range 423 is not set. Is set to an α value that is greater than “0” and less than “1”. Further, the dots included in the inner area 412c and the outer area 412d are set to an α value of “0”.

When the α value set to the dot of the head aura blur two-dimensional data 412b is “0”, the color information set to the corresponding head two-dimensional data dot is maintained. If the α value set for the dot of the head aura blur two-dimensional data 412b is greater than “0” and less than “1”, the α value is used to calculate the head aura blur two-dimensional data. The color information set in the dots of the data 412b and the color information set in the dots of the corresponding head two-dimensional data are blended, and the obtained color information is stored in the corresponding head two-dimensional data. Set to dots.

In the aura 412 of the head 372, red semi-transparent color information and transparency information are set in an area where the blur range 423 is not set, and the α value is “0.3”. In this case, the sum of the value obtained by multiplying the red color information by “0.3” and the value obtained by multiplying the color information set in the dots of the two-dimensional head data by “0.7” is It is set to the dot of the two-dimensional data for the copy.

FIG. 47A is an explanatory diagram for explaining the aura-added head two-dimensional data 412a created by the combining process. The head 372 of the character 371 is displayed in the aura-added head-use two-dimensional data 412a. Image data of the texture for the head is set in the head 372. An aura 412 of the head 372 is set on the outer edge of the head 372. In the aura-attached head two-dimensional data 412a, the head 372 and the peripheral region 412e other than the aura 412 of the head 372 are completely transparent.

The process of creating the aura-added head two-dimensional data 412a has been described above using the head 372 of the character 371 as a specific example. In the aura display effect, two-dimensional data 412a to 417a for parts with auras are created not only for the head 372 but also for each part 372-377 of the character 371.

FIG. 47B is an explanatory diagram for explaining the two-dimensional data 413a for the right arm portion with the aura. The right arm portion 373 of the character 371 is displayed in the two-dimensional data for right arm portion 413a with aura. Image data of a texture for the right arm portion is set in the right arm portion 373. The aura 413 of the right arm portion 373 is set on the outer edge of the right arm portion 373. In the two-dimensional data 413a for the right arm part with aura, the right arm part 373 or the peripheral region 413b other than the aura 413 of the right arm part 373 is completely transparent.

FIG. 47(c) is an explanatory diagram for explaining the two-dimensional data 414a for the right hand part with aura. The right hand portion 374 of the character 371 is displayed in the aura-attached right hand portion two-dimensional data 414a. Image data of a texture for the right hand portion is set in the right hand portion 374. The aura 414 of the right hand portion 374 is set on the outer edge of the right hand portion 374. In the aura-attached two-dimensional data 414a for the right hand portion, the right hand portion 374 or the peripheral region 414b other than the aura 414 of the right hand portion 374 is completely transparent.

FIG. 47D is an explanatory diagram for explaining the two-dimensional data 415a for the body part with aura. The body part 375 of the character 371 is displayed in the aura-added body part two-dimensional data 415a. Image data of the body texture is set in the body 375. An aura 415 of the body 375 is set on the outer edge of the body 375. In the two-dimensional data for body part 415 a with aura, the body part 375 or the peripheral region 415 b of the body part 375 other than the aura 415 is completely transparent.

FIG. 47E is an explanatory diagram for explaining the two-dimensional data 416a for the left leg with an aura. The left leg 376 of the character 371 is displayed in the two-dimensional data 416a for the left leg with an aura. Image data of the texture for the left leg is set in the left leg 376. The aura 416 of the left leg 376 is set on the outer edge of the left leg 376. In the two-dimensional data 416a for the left leg with aura, the left leg 376 or the peripheral region 416b other than the aura 416 of the left leg 376 is completely transparent.

FIG. 47F is an explanatory diagram for explaining the two-dimensional data 417a for the right leg with an aura. The right leg 377 of the character 371 is displayed in the two-dimensional data 417a for the right leg with an aura. The right leg 377 is set with image data of the texture for the right leg. The aura 417 of the right leg 377 is set on the outer edge of the right leg 377. In the two-dimensional data 417a for the right leg with aura, the right leg 377 or the peripheral region 417b other than the aura 417 of the right leg 377 is completely transparent.

As shown in FIGS. 47(a) to (f), the six aura-attached part two-dimensional data 412a to 417a are the same size as the size of the display surface G of the symbol display device 31, and are for the six aura-attached parts. The same number of dots are arranged in the horizontal direction of the two-dimensional data 412a to 417a, and the same number of dots are also arranged in the vertical direction of the two-dimensional data 412a to 417a for six aura-attached portions.

Next, a process of creating the drawing data for character 421a with an aura will be described. The VDP 135 creates the aura-added character drawing data 421a by writing the six aura-added part two-dimensional data 412a to 417a that have been created individually in the aura display effect effect buffer in the screen buffer 144. ..

In the memory module 133, with respect to the start timing and the update timing at which the drawing data 421a for the character with an aura is created, the order of writing the two-dimensional data 412a to 417a for the six aura-containing parts in the effect buffer is set. The writing table is stored. The display CPU 131 reads the writing table at the start timing. Further, the display CPU 131, at the start timing and the update timing at which the drawing data 421a for the character with aura is created, buffers the two pieces of two-dimensional data 412a to 417a for aura with the six auras based on the writing table. Understand the order of writing to and set it in the drawing list. The VDP 135 grasps the order of writing by referring to the drawing list, and writes the six pieces of two-dimensional data 412a to 417a for parts with auras in the ordering buffer in the order.

Specifically, the VDP 135 first writes the aura-attached left leg two-dimensional data 416a as the innermost two-dimensional data. Thereafter, the two-dimensional data is written in the order of aura-added head two-dimensional data 412a→aura-added torso two-dimensional data 415a→aura-attached right arm two-dimensional data 413a→aura attached right-hand part two-dimensional data 414a. Then, the aura-added right leg two-dimensional data 417a is written as the frontmost two-dimensional data to create aura-added character drawing data 421a.

At this time, when the α value of complete transparency is set for the pixel for which drawing is performed, the image on the back side is used as it is, and when the α value of semi-transparency is set, the α value is changed. The color information of the image on the back side and the color information of the image on the front side are blended at the standard ratio, and when the opaque α value is set, the color information of the image on the back side is compared. Overwrites the color information of the image on the front side.

As a result, the auras 412 to 417 are displayed around the respective parts 372 to 377 of the character 371. By using the drawing data for character with aura 421a, the auras 413 and 414 can be displayed around the right arm 373 and the right hand 374 overlapping the body 375. Also, the aura 417 can be displayed around the right leg 377 that overlaps the left leg 376. Since the auras 412 to 417 are not displayed above the parts 372 to 377 of the character 371 existing in front of the auras 412 to 417, a natural aura reflecting the context of the respective parts 372 to 377 constituting the character 371 is reflected. 412 to 417 can be displayed.

The VDP 135 creates drawing data for effects and symbols in the drawing data creation process for effects and symbols in step S710 of the drawing process (FIG. 13). The update timing at which the drawing data 421a for characters with aura and the drawing data for points are created as the drawing data for effect will be described below. It should be noted that each drawing data has the same outer shape, and the number of pixels forming each drawing data is also the same. Further, in the point drawing data, an α value other than “0” is set for a pixel for which color information for displaying a point is set, and an α value of “0” is set for other pixels. Is set.

The VDP 135 draws the aura-added character drawing data 421a, the point-drawing data, and the drawing display drawing data, which are individually created, and arranges the aura-added character drawing data 421a on the deepest side, and draws the drawing display data. Is arranged on the most front side, and the drawing data for points is arranged between the two drawing data, thereby writing the three drawing data in the screen buffer 144 to create drawing data for the effect and the design.

Further, the VDP 135 sets the background drawing data and the effect and design drawing data individually written in the screen buffer 144 in the drawing data combining process in step S711 of the drawing process (FIG. 13) to the background. The drawing data for one line is created on the back side, and the drawing data for the effect and the pattern is written on the front side for writing in the frame areas 142a and 142b to be drawn, thereby creating one frame of drawing data. It should be noted that each drawing data has the same outer shape, and the number of pixels forming each drawing data is also the same.

In the case of creating drawing data for effects and patterns and in the case of creating drawing data for one frame, if the pixel for which drawing is executed is set to the α value of complete transparency, the back side When the semi-transparent α value is set, the color information of the image is used as it is, and the color information of the image on the back side and the color information of the image on the front side are blended at a ratio based on the α value. When the opaque α value is set, the color information of the image on the back side is overwritten with the color information of the image on the back side. As a result, the effect image is displayed at a position on the front side of the background image and at the back side of the design image. As the effect image, an aura character 421 and an image for displaying points are displayed.

It should be noted that at the update timing when only the drawing data for aura character drawing data 421a for the rendering drawing data is not displayed without displaying the points, the VDP 135 causes the drawing buffer data for aura character 421a to the back side of the screen buffer 144. The drawing data for the design and the drawing are created by writing the drawing data for the design as the drawing data for the front side.

Hereinafter, a specific processing configuration for displaying the auras 412 to 417 on the outer edge of the character 371 will be described. FIG. 48 is a flowchart showing the arithmetic processing for aura display effect executed by the display CPU 131. The calculation process for the aura display effect is activated when the data table corresponding to the game times in which the aura display effect is executed is set.

First, in step S2601, it is determined based on the currently set data table whether or not the aura display effect is being executed. If the aura display effect is not being executed (step S2601: NO), it is determined in step S2602 whether or not it is the start timing of the aura display effect. If it is not the start timing (step S2602: NO), this operation processing is terminated as it is, and if it is the start timing (step S2602: YES), the process proceeds to step S2603.

In step S2603, the character parameter table is read based on the currently set data table, and in step S2604, the writing table is read based on the currently set data table. In a succeeding step S2605, a grasping process of various data for aura display effect is performed. Here, the grasping process of various data for aura display effect will be described with reference to the flowchart of FIG. 49. FIG. 49 is a flowchart showing a process of grasping various data for aura display effect, which is executed by the display CPU 131.

First, in step S2701, the use instruction information of the character object for displaying each part 372 to 377 of the character 371 is stored based on the currently set data table, and in step S2702, the already read character is stored. The parameter of the character object is grasped by referring to the parameter table for character.

In step S2703, the use instruction information of the partial aura object is stored based on the currently set data table, and in step S2704, the parameter of the partial aura object is grasped.

In step S2705, based on the currently set data table, the color information and transparency information of red translucent are grasped as the color information and transparency information for the aura display, and in step S2706, the instruction to use the partial texture is issued. Store information. In the following step S2707, the use instruction information of the blurring range table TB1 is stored based on the currently set data table, and in step S2708, the six aura-added parts are stored based on the writing table that has already been read. The order in which the two-dimensional data 412a to 417a for writing is written in the effect buffer is grasped. Then, in step S2709, various instruction information is stored, and the present grasping process ends. Here, the various instruction information includes cutout instruction information for instructing the VDP 135 to perform the clipping processing and blurring instruction information for instructing the VDP 135 to perform the blurring processing.

Returning to the explanation of the aura display effect calculation process (FIG. 48), after executing the process of grasping various data for the aura display effect in step S2605, the start designation information is stored in step S2606, and this calculation process is performed. To finish.

When the calculation process for the aura display effect is executed as described above, the drawing list created in the subsequent drawing list output process includes a character object, a partial aura object, a partial texture, and a blur range table TB1. And the start designation information is set. In the drawing list, a parameter for setting the character object in the world coordinate system, a parameter for setting the partial aura object in the world coordinate system, and six aura-added partial two-dimensional data 412a. The order of writing ~417a in the effect buffer is set. Further, color information and transparency information for aura display are also set in the drawing list.

If the aura display effect is being executed (step S2601: YES), it is determined in step S2607 whether or not it is the timing of changing the parameter of the character object or the parameter of the viewpoint PC 11. The determination is performed based on the already read character parameter table. If it is not the change timing of the parameter of the character object or the parameter of the viewpoint PC 11 (step S2607: NO), in step S2608, the use instruction information of the separately-stored aura-added character drawing data 421a is stored. In step S2609, the update designation information is stored and the present arithmetic processing ends. At the timing when the parameter of the character object or the parameter of the viewpoint PC 11 is not changed, the processing load is reduced by using the character drawing data 371a already created and separately saved or the character-added character drawing data 421a. be able to.

When the calculation process for the aura display effect is executed as described above, the drawing list created by the subsequent drawing list output process has the character drawing data 371a or the aura-added character drawing data stored separately in the drawing list. The use instruction information of 421a is set and the update designation information is set.

If it is time to change the parameter of the character object or the parameter of the viewpoint PC 11 (step S2607: YES), the auras 412 to 417 are displayed in step S2610 by referring to the currently set data table. It is determined whether it is the update timing to perform. If it is the update timing for displaying the auras 412 to 417 (step S2610: YES), a grasping process (FIG. 49) of various data for aura display effect is executed in step S2611, and the update is designated in step S2612. The information is stored and the present arithmetic processing ends.

When the calculation process for the aura display effect is executed as described above, the drawing list created in the subsequent drawing list output process includes a character object, a partial aura object, a partial texture, and a blur range table TB1. And the update designation information is set. In the drawing list, a parameter for setting the character object in the world coordinate system, a parameter for setting the partial aura object in the world coordinate system, and six aura-added partial two-dimensional data 412a. The order of writing ~417a in the effect buffer is set. Further, color information and transparency information for aura display are also set in the drawing list.

If it is not the update timing for displaying the auras 412 to 417 (step S2610: NO), the character data grasping process is performed in step S2613. In the grasping process, based on the currently set data table, the use instruction information of the character object for displaying each part 372 to 377 of the character 371 is stored, and the already read character parameter table is stored. Understand the parameters of the character object by referring to. In addition, the use instruction information of the partial texture is stored based on the currently set data table.

After performing the process of grasping the character data in step S2613, the character use instruction information for causing the VDP 135 to create the character drawing data 371a is stored in step S2614, and the update designation information is stored in step S2615. This operation processing is ended.

When the calculation process for the aura display effect is executed as described above, the use instruction information of the character object is set in the drawing list created in the subsequent drawing list output process, and the update designation information is also set. Is set. Further, in the drawing list, parameters for setting the character object in the world coordinate system and character use instruction information are also set.

Next, the process of creating drawing data for a character with an aura executed by the VDP 135 will be described with reference to FIG. The process of creating the drawing data for the character with an aura is executed by the effect setting process in step S703 of the drawing process (FIG. 13). Further, the process of creating the drawing data for the character with an aura is started when the start designation information or the update designation information of the aura display effect is set in the drawing list.

First, in step S2801, the drawing list of this time is referred to, and it is determined whether or not the use instruction information of the separately-stored drawing data for character with aura 421a is set. When the use instruction information of the separately-stored drawing data for character with aura 421a is not set (step S2801: NO), the drawing list of this time is referred to in step S2802, and the character use instruction information is set. It is determined whether or not it has been done. If the character use instruction information is set (step S2802: YES), a character drawing data creation process is executed in step S2803.

In the process of creating the character drawing data, the drawing module of this time is referenced to grasp the addresses where the six character objects for displaying the respective parts 372 to 377 of the character 371 are stored in the memory module 133. read out. Also, with reference to the drawing list this time, the six parameters for setting the six character objects in the world coordinate system are grasped. Then, the six character objects are set in the world coordinate system based on the grasped parameters.

Then, the six parameters set in the world coordinate system are projected on the screen area PC12 to create projection data of the character object. Further, with reference to the drawing list this time, the memory module 133 grasps and reads the addresses at which the six partial textures, which are image data of the surfaces of the respective parts 372 to 377 of the character 371, are stored. Then, the character drawing data 371a is created by applying the six partial textures to the projection area of the character object.

Specifically, the projection of the six character objects set in the world coordinate system onto the screen area PC12 is performed in a manner that the dot information on the surface of the character object projected on each dot of the projection data can be grasped. .. The VDP 135 grasps the dot information on the surface of the character object corresponding to each dot in the projection data of the character object, and grasps the coordinate value of the UV coordinate system corresponding to the dot on the surface of the character object. Then, the color information set in the coordinate value of the partial texture set in the UV coordinate system is set in each dot of the projection data. As a result, the partial texture is applied to the projection data of the character object.

When the character use instruction information is not set in the drawing list this time (step S2802: NO), in step S2804, the aura-added head two-dimensional data creation process is executed. Here, the process of creating the two-dimensional data for the head with an aura will be described.

The VDP 135 first executes a process of creating head projection data for clipping. In the process of creating the head projection data for clipping, the head object 372a is set in the world coordinate system and projected on the screen area PC12 to create the head projection data 372b, and the created head projection data. Save 372b separately. After that, the α value of “0” is set to all the dots forming the head projection area 372c of the head projection data 372b, and all the dots forming the peripheral area 372d of the head projection data 372b are set. The α value of “1” is set to create head projection data for clipping.

Next, a process of creating head projection data for aura is executed. In the process of creating the aura head projection data, the head aura object 382a is set in the world coordinate system and projected on the screen area PC12 to create the aura head projection data 382b. After that, color information and transparency information for aura display are set to all the dots forming the aura head projection area 382c of the aura head projection data 382b, and the peripheral area 382d of the aura head projection data 382b is set. The α value of “0” is set to all the dots forming

Next, the VDP 135 sets the aura head projection data as the clipping target data, sets the clipping head projection data as the clipping data, and executes the clipping processing (FIG. 40). In the cutout process, an area corresponding to the cutout head projection area is cut out from the aura head projection data, and the head aura two-dimensional data 392a is created.

Next, a vertical scan process (FIG. 41) is executed on the created head aura two-dimensional data 392a. In the first half of the vertical scanning process, position information of a plurality of dots existing on the upper edge of the head aura region 392 is stored, and in the latter half of the vertical scanning process, the lower side of the head aura region 392 is stored. Position information of a plurality of dots existing on the edge of is stored.

Subsequently, the horizontal scan process (FIG. 42) is executed on the same head aura two-dimensional data 392a. In the first half of the horizontal scanning process, positional information of a plurality of dots existing on the left edge of the head aura region 392 is stored, and in the latter half of the horizontal scanning process, the right side of the head aura region 392 is stored. Position information of a plurality of dots existing on the edge is stored.

Next, the blurring range table TB1 is read from the memory module 133, and the range setting process (FIG. 43) is executed on the head aura two-dimensional data 392a based on the blurring range table TB1. In the range setting process, a plurality of blurring ranges 423 are set on the outer edge of the head aura region 392, and a plurality of destination ranges 422 corresponding to the blurring range 423 are set in the outer region 392c.

Specifically, the first blur range group is set near the upper edge of the head aura area 392, and the first destination range group is set above the first blur range group. Further, the second blur range group is set near the lower edge of the head aura region 392, and the second destination range group is set below the second blur range group. Furthermore, a third blur range group is set near the left edge of the head aura region 392, and a third destination range group is set to the left of the third blur range group. Then, the fourth blur range group is set near the right edge of the head aura area 392, and the fourth destination range group is set to the right of the fourth blur range group.

Next, the moving process (FIG. 44) of the color information etc. is executed. In the moving process, after the color information and the transparency information set for each dot in the blur range 423 is set in the corresponding dot in the destination range 422, the transparency information for the complete transparency in each dot in the blur range 423 is set. Is set. As a result, the head aura area 392 of the head aura two-dimensional data 392a is blurred, and the head aura gradation two-dimensional data 412b is created.

Next, the separately stored head projection data 372b is read out, and UV mapping for applying the head texture to the head projection area 372c is performed. Then, an α value of “0” is set in the peripheral area of the head projection data 372b to create head two-dimensional data.

Next, the head two-dimensional data is set to the basic data, the head aura blur two-dimensional data 412b is set to the priority data, and the head two-dimensional data and the priority data set to the basic data are set. The synthesis process for synthesizing the head aura blurring two-dimensional data 412b that has been performed is executed, and this creation process ends.

The combining process is performed in a mode in which the color information and the transparency information set in the corresponding dot of the basic data are changed according to the color information and the transparency information set in each dot of the priority data. When the α value set to the dot of the priority data is “1”, the color information and the transparency information set to the dot are set to the corresponding dot of the basic data. Further, when the α value set to the dot of the priority data is “0”, the color information and the transparency information set to the corresponding dot of the basic data are maintained.

When the α value set for the priority data dot is greater than “0” and less than “1”, the color information set for the priority data dot is associated with the basic data using the α value. The color information set for the corresponding dot is blended, and the obtained color information is set for the corresponding dot of the basic data. By combining the two-dimensional data for head and the blur two-dimensional data for head aura 412b, the two-dimensional data for head with aura 412a is created.

Returning to the description of the process for creating the drawing data for the character with an aura (FIG. 50), after performing the process for creating the two-dimensional data for the head with an aura in step S2804, the remaining five auras in steps S2805 to S2809. The process of creating the two-dimensional data 412a to 417a for attached parts is executed. In step S2805, a process for creating the aura-equipped right arm part two-dimensional data 413a is performed, and in step S2806, a process for creating the aura-equipped right hand part two-dimensional data 414a is performed.

In step S2807, a process for creating the aura-added torso two-dimensional data 415a is performed, and in step S2808, a process for creating the aura-added left leg two-dimensional data 416a is performed. In step S2809, a process for creating the two-dimensional data 417a for the right leg with aura is performed, and in step S2810, the two-dimensional data 412a to 417a for the six auras are referred to by referring to the drawing list this time. The order of writing in the effect buffer of the aura display effect in the screen buffer 144 is grasped. Then, in step S2811, the drawing data 421a for character with aura is created by writing the two-dimensional data 412a to 417a for the part with aura in the buffer for effect of the aura display effect in the screen buffer 144.

In the process of creating the drawing data for the character with an aura, the two-dimensional data 412a to 417a for the aura-attached parts regarding the parts 372 to 377 far from the viewpoint PC11 are set on the back side, and the parts close to the viewpoint PC11 are located. Six two-dimensional data 412a to 417a for an aura portion are written in a mode in which the two-dimensional data 412a to 417a for an aura portion for 372 to 377 are set on the front side. At this time, when the completely transparent α value is set for the pixel for which drawing is performed, the color information of the image on the back side is used as it is, and when the semi-transparent α value is set, The color information of the image on the back side and the color information of the image on the front side are blended in a ratio based on the α value, and when the opaque α value is set, the color information of the image on the back side is blended. In contrast, the color information of the image on the front side is overwritten. As a result, it is possible to display natural auras 412 to 417 in which the front-rear relationship of the respective parts 372 to 377 forming the character 371 is reflected.

After executing the processing of step S2803 or step S2811, in step S2812, the created drawing data is separately stored, and the present creation processing ends. Specifically, when the character drawing data 371a is created in step S2803, the character drawing data 371a is separately stored in the effect buffer for the aura display effect in the screen buffer 144. When the drawing data 421a for characters with aura is created in step S2811, the drawing data 421a for characters with aura is separately stored in the buffer for effect of the aura display effect in the screen buffer 144.

If the use instruction information of the separately stored data is set in the drawing list this time (step S2801), it is separately stored in the buffer for the effect of the aura display effect in the screen buffer 144 in step S2813. The drawing data for character 371a or the drawing data for character with aura 421a is read, and the present creation processing is ended.

At the update timing when the parameter of the character object is not changed and at the update timing when the parameter of the viewpoint PC 11 is not changed, the processing for creating the drawing data 421a for the character with aura is not performed, The configuration is such that the separately-stored aura-character drawing data 421a is read out, so that the aura display effect can be displayed compared to the case where the process of creating the aura-character drawing data 421a is executed at all update timings. The processing load to be executed can be reduced.

As described above, in the aura head projection data 382b, the area corresponding to the clipping head projection area is cut out to create the head aura two-dimensional data 392a. At the update timing when the parameter of the head object 372a in the world coordinate system changes and the update timing when the parameter of the viewpoint PC 11 changes,
The position of the clipping head projection area in the clipping head projection data changes, but the position of the aura head projection area in the aura head projection data 382b also changes, and therefore, for all auras. It is possible to create the two-dimensional data 392a for the head aura, which includes only the outer edge of the head projection area 382c. Data of the two-dimensional data stored in the memory module 133 as compared with the case where the two-dimensional data 392a for the head aura is stored in advance in association with all the relationships between the head object 372a and the viewpoint PC11 in the world coordinate system. The capacity can be reduced.

The head two-dimensional data 412a is created by setting the head two-dimensional data as the basic data, and setting the head aura blurring two-dimensional data 412b as the priority data and performing the combining process. Since the head two-dimensional data and the head aura blur two-dimensional data 412b are individually created, the color information and the transparency information of the auras 412 to 417 are separated from the color information and the transparency information of the character 371, It can be set in an independent manner.

The two-dimensional data 412a to 417a for partials with aura corresponding to the parts 372 to 377 located far from the viewpoint PC11 are arranged on the back side and correspond to the parts 372 to 377 located near to the viewpoint PC11. By writing the two-dimensional data 412a to 417a for parts with auras in the buffer for effect of the aura display effect in the screen buffer 144 in a mode in which the two-dimensional data 412a to 417a for parts with auras are arranged on the front side. , Drawing data 421a for character with aura is created. As a result, it is possible to perform a display that reflects the context of the overlapping portion. Further, the auras 412 to 417 can also be displayed on the outer edge portions of the frontmost portions 372 to 377 of the overlapping portions. Compared with a mode in which the auras 412 to 417 are not displayed in the overlapping portion, a more consistent aura display effect can be performed, so that the player's interest can be appropriately increased.

When the drawing data 421a for the character with an aura is separately saved and the update timing is such that the parameter of the character object is not changed and the parameter of the viewpoint PC 11 is the update timing, the separately saved character for the character with aura 421a is used. By using the drawing data 421a, it is possible to suppress the processing load for performing the aura display effect, as compared with the configuration in which the drawing data 421a for character with aura is created at all update timings.

By separately storing the head projection data 372b, the clipping head projection data and the head two-dimensional data can be created from one projection data. The number of times the head object 372a is projected onto the screen area PC12 as compared with the case where the projection for creating the cutout head projection data and the projection for creating the head two-dimensional data are individually performed. Can be reduced and the processing load can be reduced.

By performing the blurring process on the head aura two-dimensional data 392a to create the head aura blurring two-dimensional data 412b, the head aura area 392 having a simple shape can be changed to a complicated shape. The fluctuation of the aura 412 of the part 372 can be displayed. Since the blurring process can be selectively executed only on the head aura region 392, a combination of the image of the clear head 372 and the image of the blurred aura 412 can be displayed.

<Another form of aura display production>
In the configuration for executing the aura display effect described above, the auras 412 to 417 displayed around the character 371 are not limited to the auras 412 to 417 that have been subjected to the blurring process. For example, the aura is set around the head 372 of the character 371 by setting the two-dimensional data for the head as the basic data, setting the two-dimensional data for the head aura 392a as the priority data, and executing the combining process. It may be displayed. In this case, a simple aura is displayed around the head 372 of the character 371. Also, by changing the transparency information of the head aura area 392 from semi-transparent to opaque, it is possible to display a contour line having a width around the head 372 of the character 371.

Further, the processing for creating the aura-added head two-dimensional data 412a is not limited to the aura-added head two-dimensional data creation processing including the cutout processing. For example, blurring processing is performed on the aura head projection area 382c of the aura head projection data 382b to create two-dimensional data in which the outer edge of the aura head projection area 382c is blurred. The created two-dimensional data is set as the basic data to be cut out, and the two-dimensional head data is set as the priority data to execute the combining process. Accordingly, it is possible to create the aura-attached head two-dimensional data 412a in which the aura 412 is displayed around the head 372. Since the process is shorter than the process of creating the aura-added head two-dimensional data including the clipping process, it is possible to reduce the processing load for creating the aura-added head two-dimensional data 412a.

The method of creating the head aura two-dimensional data 392a is not limited to the method of creating the head projection data 372b and the aura head projection data 382b individually. For example, in the world coordinate system, the head object 372a is set on the front side and the head aura object 382a is set on the back side with the viewpoint PC11 as a reference, and the head object 372a and the head aura object are set. 382a and 382a may be simultaneously projected on the screen area PC12.

In the projection data obtained by the projection, color information and transparency information for aura display are included in all dots that are included in the aura head projection area 382c and that are not included in the head projection area 372c. Set. In addition, the transparency information of complete transparency is set for all the dots forming the head projection area 372c. Since the head aura two-dimensional data 392a can be created by a short process that does not perform the clipping process, the processing load for creating the head aura two-dimensional data 392a can be reduced.

The timing of executing the blurring process is not limited to the timing before the process of combining the head two-dimensional data and the head aura blur two-dimensional data 412b. For example, by setting the two-dimensional data for the head as the basic data, setting the two-dimensional data for the head aura 392a as the priority data, and executing the combining process, the head to which the texture for the head is applied is set. It is also possible to create two-dimensional data in which the aura 412 that has not been subjected to the blurring process is present around the copy projection area 372c. By performing blurring processing on the two-dimensional data, the two-dimensional data 412a for the head with aura can be created. In the blurring process, since the blurring center 423a is located on the outer edge of the aura 412 on which the blurring process is not executed, the blurring is performed without changing the contents of the head projection area 372c to which the head texture is applied. It is possible to selectively blur and display only the aura 412 that has not been processed.

Further, the timing of creating the six pieces of aura-added two-dimensional data 412a to 417a is not limited to the update timing at which the parameter of the character object is changed and the update timing at which the parameter of the viewpoint PC 11 is changed. For example, at the update timing when the six aura-added part two-dimensional data 412a to 417a are separately stored and the parameters of some of the six character objects are changed, some aura-added part two-dimensional data are stored. The configuration may be such that only 412a to 417a are created.

Aura-added part two-dimensional data 412a to 417a is created for the character object whose parameter is changed, and separately stored aura-added part two-dimensional data 412a to 417a is read for the character object whose parameter is not changed. To be used. This makes it possible to reduce the processing load for performing the aura display effect, as compared with the case of creating all the two-dimensional data 412a to 417a for aura-attached parts.

Further, the size of the six aura-attached two-dimensional data 412a to 417a is not limited to the same size as the size of the display surface G in the symbol display device 31. For example, the size of the six aura-attached two-dimensional data 412a to 417a may be smaller than the size of the display surface G of the symbol display device 31.

Specifically, when the six aura-added part two-dimensional data 412a to 417a are sequentially written to create the aura-added character drawing data 421a, the size of the writing destination area is the display surface G of the symbol display device 31. It has the same size as. In the writing table, the order for writing the two-dimensional data 412a to 417a for aura-attached portions is set, and the position information for writing the two-dimensional data 412a to 417a for each aura-attached portion is set. It has a structure.

Specifically, one dot serving as a reference is set in each of the two-dimensional data 412a to 417a for aura-attached portions. Specifically, one dot located at the center of each aura-added part two-dimensional data 412a to 417a is a reference dot. In addition, the writing destination area exists in the XY coordinate system. Then, in the writing table, the coordinates of the reference dots of the two-dimensional data 412a to 417a for each aura in the writing destination area are set.

The display CPU 131 sets the coordinates of the reference dots of the two-dimensional data 412a to 417a for each part with aura and the writing order in the drawing list. The VDP 135 refers to the drawing list and writes the two-dimensional data 412a to 417a for each aura-attached portion in the write destination area based on the writing order and the coordinates of the reference dots. Thereby, the drawing data 421a for an aura-equipped character having the same size as the display surface G of the symbol display device 31 is utilized by using the aura-attached part two-dimensional data 412a to 417a of a size smaller than the display surface G of the symbol display device 31. Can be created. Compared with the case of using the two-dimensional data 412a to 417a for aura with the same size as the display surface G of the symbol display device 31, the amount of data to be handled can be suppressed and the processing load can be reduced.

The size of the drawing data for the aura display effect, which is not the same as the display surface G of the symbol display device 31, is other than the drawing data for the character with aura 421a. For example, by writing the aura-attached part two-dimensional data 412a to 417a and the drawing data other than the aura-attached character drawing data 421a in an area having the same size as the display surface G of the symbol display device 31, the drawing data for effect is created. May be created.

A configuration in which the writing order and the position information for writing are set in the writing table for each of the two-dimensional data for aura-added parts 412a to 417a and the drawing data other than the drawing data for an aura-added character 421a. To do. By reducing the size of the drawing data for rendering other than the drawing data for character with aura 421a, the amount of data to be handled can be suppressed and the processing load can be reduced.

<Second Embodiment>
FIG. 51 is a block diagram showing the electrical configuration of the display control device 630 in this embodiment. In the present embodiment, the main control device 50 is provided as in the first embodiment. In addition, a voice light emission control device 60 is provided, which drives and controls the various light emission units 35, 36, 44 and the speaker unit 45 based on a command transmitted from the main control device 50 and receives an operation signal from the operation device 48 for performance. In addition, a display control device 630 for controlling the symbol display device 31 based on a command transmitted from the sound emission control device 60 is provided.

In this embodiment, the hardware configuration of the display control device 630 is different from that of the display control device 130 in the first embodiment. The hardware configuration of the display control device 630 will be described below.

As shown in FIG. 51, the display control device 630 includes a display control board 636 on which a display CPU 631, a work RAM 632, a memory module 633, a VRAM 634, and a video display processor (VDP) 635 are mounted. ..

The display CPU 631 has a function as a main control unit in the display control device 630, and reads (fetches), interprets (decodes), and executes a control program or the like. More specifically, the display CPU 631 is connected to an input port 637 mounted on the display control board 636 via a bus, and various commands transmitted from the sound emission control device 60 are input to the display CPU 631 via the input port 637. To be done. Note that the reception of a command from the sound emission control device 60 in the display CPU 631 is not limited to the configuration of directly receiving the command from the sound emission control device 60, and also includes the configuration of receiving the command relayed to the relay board. Be done.

The display CPU 631 is connected to the work RAM 632, the memory module 633, and the VRAM 634 via the bus, and based on the command received from the voice emission control device 60, various data stored in the memory module 633 is stored in the work RAM 632 or the VRAM 634. Send a transfer instruction. Further, the display CPU 631 is connected to the VDP 635 via the bus, and based on the command received from the voice emission control device 60, issues a drawing instruction to cause the symbol display device 31 to output an image signal. The memory module 633, the work RAM 632, and the VRAM 634 will be described below.

The memory module 633 stores in advance control data (control information) including a control program and fixed value data, and sprite data such as symbols and characters displayed on the symbol display device 31, background data, and moving images. It is a storage unit that stores in advance various image data (image information) including image data and the like. The memory module 633 includes a non-volatile semiconductor memory that does not require external power supply for storing data, and in particular, a NAND flash memory is used as the semiconductor memory. Incidentally, although the storage capacity is 4 Gbits, such a storage capacity is arbitrary as long as the control in the display control device 630 is satisfactorily executed. Further, the memory module 633 is used as a non-writing and read-only memory (ROM) when the pachinko machine 10 is used.

Here, each sprite data includes at least a combination of bitmap format data that defines the outer shape or 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. There is. The background data is stored and held as JPEG format data in which still image data is compressed.

The work RAM 632 is a storage unit for temporarily storing the control data read from the memory module 633 and transferred, and also temporarily storing flags and the like. The work RAM 632 has a volatile semiconductor memory that requires external power supply for storage and, in detail, a DRAM is used as the semiconductor memory. However, the RAM is not limited to DRAM, and other RAM such as SRAM may be used. Note that the storage capacity is 1 Gbit, but the storage capacity is arbitrary as long as the control in the display control device 630 is well executed. The work RAM 632 is used for both reading and writing when the pachinko machine 10 is used.

Based on the data transfer instruction from the display CPU 631 to the memory module 633, the control data is transferred from the memory module 633 to the work RAM 632. In this case, the control data is transferred in advance before the execution timing of the process in the display CPU 631 corresponding to the control data. Then, the display CPU 631 reads the control data transferred to the work RAM 632 into an internal memory area (register group) as necessary, and executes various processes.

The VRAM 634 is a storage means for temporarily storing various data necessary for outputting an image to the symbol display device 31. The VRAM 634 includes a volatile semiconductor memory that requires external power supply to retain the memory, and in detail, an SDRAM is used as the semiconductor memory. However, the RAM 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 such a storage capacity is arbitrary as long as the control in the display control device 630 is well executed. The VRAM 634 is used for both reading and writing when using the pachinko machine 10.

The VRAM 634 includes a development buffer 641. Image data is transferred from the memory module 633 to the development buffer 641 based on a data transfer instruction from the display CPU 631 to the memory module 633. In this case, the image data is transferred in advance before the execution timing of the process in the VDP 635 using the image data. Further, the VRAM 634 is provided with a frame buffer 642 in which drawing data is created by the VDP 635.

The VDP 635 is an image generation device that draws on the symbol display device 31, using the data stored and held in the expansion buffer 641 based on a drawing instruction from the display CPU 631, specifically by processing. It is a kind of drawing circuit that operates the image processing device 31b incorporated to drive and control the liquid crystal display unit 31a in the symbol display device 31. Since the VDP 635 is integrated into an IC chip, it is also called a "drawing chip", and the substance thereof should be called a microcomputer chip containing a drawing-specific firmware.

Specifically, the VDP 635 includes a control unit 651, a register 652, a moving picture decoder 653, and a display circuit 655. Further, these circuits are connected to each other via a bus, and are also connected to the I/F 656 for the display CPU 631 and the I/F 657 for the VRAM 634.

In the VDP 635, the drawing list as drawing instruction information transmitted from the display CPU 631 is stored in the register 652. By storing the drawing list in the register 652, the control unit 651 activates a program according to the drawing list and executes a predetermined process. It should be noted that the control unit 651 may have a configuration in which all of the control programs for operating are provided by the drawing list. The control unit 651 may be configured to execute a predetermined process. Further, the control program may be read from the memory module 633 in advance.

As the above processing, the control unit 651 creates drawing data for one frame in the frame buffer 642 using (or by processing) the image data expanded in the expansion buffer 641 of the VRAM 634. The drawing data for one frame is the data necessary to display the image at one update timing in the configuration in which the image on the display surface G of the symbol display device 31 is updated at a predetermined update timing. Say that.

Here, the frame buffer 642 is provided with a plurality of frame areas 642a and 642b. Specifically, a first frame area 642a and a second frame area 642b are provided. Each of these frame areas 642a and 642b is set to a capacity capable of storing drawing data for one frame. Specifically, each of the frame areas 642a and 642b includes a large number of unit areas (unit setting areas) corresponding to dots (pixels) of the liquid crystal display unit 31a (that is, the display surface G) at a predetermined magnification. ing. Each unit area has a storage capacity capable of storing data for specifying which color is displayed. More specifically, the full color system is adopted, and it is possible to set 256 colors for each of R (red), G (green), and B (blue) in each dot. Correspondingly, 1 byte (8 bits) is assigned to each RGB color in each unit area. That is, each unit area has a storage capacity of at least 3 bytes.

The storage capacity is not limited to the full-color method. For example, in a configuration in which only 256 colors can be displayed in each dot, the storage capacity required to store color information in each unit area may be 1 byte.

Since the frame buffer 642 is provided with the first frame area 642a and the second frame area 642b, in the situation where drawing on the symbol display device 31 is executed using drawing data created in one frame area. , Drawing data to be used in the future is created for other frame areas. That is, the double buffer system is adopted as the frame buffer 642.

The display circuit 655 generates an image signal corresponding to each dot of the liquid crystal display unit 31a based on the drawing data created in the first frame area 642a or the second frame area 642b, and the image signal is displayed in the display circuit 655. It is output to the symbol display device 31 via the connected output port 638. Further, the display circuit 655 also outputs a synchronizing signal such as a horizontal synchronizing signal or a vertical synchronizing signal. The display circuit 655 is provided with a scaler 658 and an image signal output portion 659 in order to generate and output the image signal.

<V interrupt processing>
Next, the V interrupt processing will be described with reference to the flowchart of FIG. The V interrupt process is repeatedly activated in a predetermined cycle, specifically, a 20 msec cycle.

When outputting the image signal for one frame to the symbol display device 31, the VDP 635 starts outputting the image signal from the dot in the upper left corner portion of the display surface G, and on the horizontal line including the dot at one end. The image signal is sequentially output to the aligned dots, and the image signal is sequentially output to the dots from left to right for each horizontal line. Then, the image signal is finally output to the dots in the lower right corner portion of the display surface G. In this case, the VDP 635 outputs a V interrupt signal to the display CPU 631 at the timing of outputting the image signal for the last dot, and causes the display CPU 631 to recognize that the update of the image of one frame is completed. The output cycle of this V interrupt signal is 20 msec. In this respect, the V interrupt processing can be regarded as being activated in synchronization with the reception of the V interrupt signal. However, even if the V interrupt signal is not received, if 20 msec has elapsed since the previous V interrupt process was started, the V interrupt process is newly started.

In the V interrupt process, first, in step S2901, a command analysis process is executed. Specifically, the content of the command stored in the command buffer of the work RAM 632 is analyzed. In a succeeding step S2902, pointer updating processing is executed. In the pointer update processing, the pointer information set in the data table is updated so as to advance by one frame. As a result, the display CPU 631 can grasp the processing required to display the image for one frame corresponding to the update timing of this time. In subsequent step S2903, task processing is executed. In the task process, in order to display the image for one frame corresponding to the update timing of this time, the parameters necessary for instructing the VDP 635 to draw are calculated. Details of the task processing will be described later.

In step S2904, a drawing list output process is executed and this V interrupt process is ended. In the drawing list output process, a drawing list for displaying an image for one frame corresponding to the update timing of this processing time is created, and the created drawing list is transmitted to the VDP 635. In this case, in the drawing list, the image grasped in the immediately preceding task process is the drawing target, and the parameter information updated in the task process is also set. The VDP 635 creates drawing data in the frame areas 642a and 642b of the VRAM 634 according to this drawing list.

Next, in the present embodiment, the contents of the drawing list transmitted from the display CPU 631 to the VDP 635 will be described. 53A to 53C are explanatory diagrams for explaining the contents of the drawing list.

Header information is set in the drawing list. In the header information, target buffer information, which is information indicating which one of the first frame area 642a and the second frame area 642b is to be created, is set for the image of one frame related to the drawing list. There is. Further, in the header information, the presence or absence of decoding designation and the information of the address to which the moving image data to be decoded is transferred are set. Further, various designation information is set in the header information.

In the drawing list, in addition to the header information described above, a plurality of types of image data used to display an image for one frame are set, and further, the drawing order information of each image data and the image data of each image data are set. Parameter information and are set. More specifically, the drawing order information is set so as to be serially-numbered numerical information, and the information of the image data to be used in a one-to-one correspondence with each numerical information is set. Also, parameter information is set in a one-to-one correspondence with the information of each image data.

The drawing order is set so that an individual image to be displayed is positioned on the back side of the display surface G in the image for one frame and is to be drawn first. The individual image is one still image defined by still image data such as background data, or one sprite defined by sprite data such as design sprite data. In the drawing list of FIG. 53A, 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. Therefore, the background data is first written to the frame areas 642a and 642b to be drawn, 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, the individual images are displayed in the order of background image→effect image→design.

Plural kinds of parameters are set in the parameter information P(1), P(2), P(3),.... Regarding the parameter P(1) of the background data, specifically, as shown in FIG. 53(b), information on the address of the area to which the background data is transferred in the VRAM 634 and the two-dimensional plane when the background data is written Frame information 642a, 642b with respect to the coordinate information indicating the position, 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 of a scale indicating the magnification when writing to the background, information of a uniform α value indicating the overall transparency information (or transparency information) when writing the background data, and whether α data is applied or not Information and are set. The types of the above parameters are the same for the sprite data A as shown in FIG.

Here, the coordinate information is not set individually for all the pixels that make up 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 the reference pixel for which the coordinate information is designated. The VDP 635 can recognize that the information of the designated coordinate is one pixel at the center of the image data, and when arranging the image data, the one pixel at the center is on the designated coordinate. .. As a result, it is possible to suppress the information capacity of the coordinate information to be designated for one image data in the display CPU 631. Further, since it is not necessary for the display CPU 631 and the VDP 635 to be able to recognize the coordinates of all the pixels of the image data, the program can be simplified.

Incidentally, the reference pixel is not limited to the central one pixel, and may be a pixel having a corner angle such as an upper left corner or an upper right corner. Since the sprite data and the still image data are basically defined as rectangular shapes, the display CPU 631 and the VDP 635 can easily recognize the reference pixel by using the corner pixel as the reference pixel.

The uniform α value is transparency information applied to all dots of one image data, and is numerical information derived as a calculation result in the display CPU 631. The uniform α value is uniformly applied to all pixels of the image data. On the other hand, the α data is transparency information applied to each pixel of background data and sprite data, and is stored in the NAND flash memory in advance as image data. The α data can have different transparency information for each pixel within the range of the same background data or the same sprite data. This α data has a larger data capacity than the program data for setting a uniform α value.

In the situation where the uniform α value and α data are set as described above, the transparency of the background data and the sprite data may be uniformly controlled for all pixels instead of being finely controlled in pixel units. It is possible to reduce the required data capacity by being able to deal with uniform α values, and it is also possible to finely control the transparency in pixel units by applying α data.

Drawing processing in the VDP 635 will be described with reference to the flowchart in FIG.

First, in step S3001, it is determined whether or not the creation of the drawing data instructed by the already received drawing list has been completed. If the drawing data has been created, it is determined in step S3002 whether a new drawing list has been received from the display CPU 631. If a new drawing list has been received, in step S3003 a corresponding process at the time of reception is executed.

In the response processing at the time of reception, it is grasped from which information of the target buffer included in the drawing list which frame area 642a, 642b is to be created for one frame corresponding to the drawing list received this time, and the grasp is made. The specified frame area is set as the drawing data creation target. Further, the presence/absence of the decode designation is grasped, and when the decode designation is present, the address to which the moving picture data to be decoded is transferred is grasped, and the moving picture decoder is operated so as to decode the moving picture data. ..

In a succeeding step S3004, a writing process is executed. In the writing 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. When the grasped image data is sprite data, the color palette data is applied to each dot of the bitmap image. Then, based on the grasped parameters, the image data of the current drawing target is written in the frame areas 642a and 642b set as the creation target.

On the other hand, if it is determined in step S3001 that the drawing data instructed by the already received drawing list is being created, the drawing list counter is updated in step S3005. As a result, the drawing target is switched to the image data in the next drawing order. Then, the process of step S3004 is executed for the switched image data. That is, the drawing data of one frame specified by one drawing list is created by executing the drawing process multiple times.

It is not limited to the configuration in which only one image data is processed in one drawing process, and a plurality of image data may be processed in one drawing process. It 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 adopted.

When a negative determination is made in step S3002, or after the processing of step S3004 is executed, it is determined in step S3006 whether the image signal output for one frame has been completed in the display circuit 655. If it is not completed, the main drawing process is ended as it is, and if it is completed, a V interrupt signal is output to the display CPU 631 in step S3007, and then the main drawing process is ended.

The drawing data for one frame is created so as to be completed within the range of 20 msec cycle. Further, an image signal is output from the display circuit 655 to the symbol display device 31 based on the created drawing data, but since the double buffer method is adopted as already described, the output of the image signal is the output. This is performed in parallel with the creation of the drawing data for one frame after that frame. The display circuit 655 has a selector circuit that alternately switches the frame regions 642a and 642b to be referred to each time the output of the image signal for one frame is completed, and the control unit 651 is switched by the selector circuit. In the above, the frame areas 642a and 642b which are the drawing targets of the drawing data are regulated so as not to be the output targets for outputting the image signal.

Next, the task processing executed in the display CPU 631 will be described.

The task process is executed in order to grasp the information necessary for creating the drawing list. The task processing will be described below with reference to the flowchart of FIG. First, in step S3101, it is determined whether or not there is an individual image to be controlled. The individual image to be controlled is shown in the currently set data table. When the individual image of the control start target exists (step S3101: YES), the control start process of steps S3102 to S3104 is executed. In the control start process, first, in step S3102, the work RAM 632 is searched for an empty buffer area for performing various calculations in controlling the individual image, and the individual image recognized as the control start target is paired. A free buffer area is secured so that 1 corresponds.

In the following step S3103, initialization processing is executed for all the empty buffer areas secured in step S3102. In the following step S3104, a control start parameter corresponding to the individual image is set in the empty buffer area initialized in step S3103. The parameters for starting the control include the position, rotation angle, and size of the target individual image on the virtual two-dimensional plane. When there are a plurality of individual images that are grasped as the control start target, the control start parameter is set individually for each free buffer area corresponding to each individual image.

After making a negative determination in step S3101 or setting parameters in step S3104, the control update processing of steps S3105 to S3108 is executed. In the control update processing, first, in step S3105, background calculation processing is executed. In the background calculation processing, the control update target of this time is grasped from the background still image that constitutes the background image and the background sprite. Further, with respect to the grasped control update target, various parameters necessary for creating a drawing list such as coordinates on the virtual two-dimensional plane, rotation angle, scale, uniform α value and α data designation are calculated and derived. Then, the various parameters thus derived are written in an area secured in the work RAM 632 in association with each individual image, thereby updating the control information.

In a succeeding step S3106, effect calculation processing is executed. In the effect calculation process, the control update target of this time is grasped from the effect sprites that form the image of the effect to be displayed in various effects such as reach display, notice display, and jackpot effect. Further, the various parameters described above are derived with respect to the grasped control update target. Then, the various parameters thus derived are written in an area secured in the work RAM 632 in association with each individual image, thereby updating the control information.

In a succeeding step S3107, symbol calculation processing is executed. In the symbol calculation process, the control update target of this time is grasped among the symbols to be displayed in a variable manner in each game. Further, the various parameters described above are derived with respect to the grasped control update target. Then, the various parameters thus derived are written in an area secured in the work RAM 632 in association with each individual image, thereby updating the control information.

By the way, in each processing of steps S3105 to S3107, animation data set to change various parameters of the individual image according to a specific pattern each time the image update timing is reached is used. This animation data is determined according to the type of individual image. The animation data is stored in the NAND flash memory in advance and is transferred to the work RAM 632 in advance by the time when it needs to be read by the display CPU 631.

After that, in step S3108, after the drawing instruction target grasping process is executed, this task process is ended. In the process of recognizing the drawing instruction target, among the individual images that are the control update targets by the processes of steps S3105 to S3107, the individual images included in the image for one frame related to the drawing data creation instruction this time are displayed. Perform the process of grasping.

As described above, for the individual image that is the control start target, “search for free buffer area” in step S3102, “initialize reserved buffer area” in step S3103, and “set parameter for starting control” in step S3104. And any one of the “variable parameter update procedure” of steps S3105 to S3107 is executed, while for the individual image only for the control update, one of “various parameter updates” of steps S3105 to S3107 is executed. Only the renewal procedure is executed. Therefore, the processing load of the individual image that is the control start target is larger than that of the individual image that is the control update target only. Note that the processing of step S3104 may not be executed, and the processing for replacing the individual image for which control is started may be executed in any of steps S3105 to S3107.

<Outline display production>
Next, the outline display effect will be described with reference to FIG. In the outline display effect, a human-shaped character 491 is displayed on the display surface G of the symbol display device 31. FIG. 56A is an explanatory diagram for explaining a display mode when the whole body of the character 491 to be displayed exists in the atmosphere region 501, and FIG. 56B is a whole body of the character 491 in the water region 502. FIG. 5 is an explanatory diagram for explaining a display mode in the case of being present in. Further, FIG. 56C is an explanatory diagram for explaining a display mode when the character 491 exists across the air region 501 and the water region 502.

The outline display effect is an effect in which an outline 492 or a blurred outline 493 (FIG. 59(e)) is displayed on the outer edge of the character 491. Here, the blur outline 493 is an outline displayed in a blurred manner. In the outline display effect, the degree of expectation of a jackpot is notified to the player according to the type of outline 492 or blur outline 493 displayed.

Specifically, a red blur outline 493 is displayed on the outer edge of the character 491 in the finalization notice effect that informs the player that the result of the current game is the big hit result. In addition, in the high expectation effect that informs the player that the result of this game time is likely to be a jackpot result, a red outline 492 is displayed on the outer edge of the character 491. A black outline 492 is displayed on the outer edge of the character 491 in the low expectation effect that informs the player that the result of the current game is unlikely to be a jackpot result. The red blur outline 493 and the red outline 492 are displayed with 1.5 times the thickness of the black outline 492.

As shown in FIG. 56(a), in the high-expectation effect or low-expectation effect, if the whole body of the character 491 exists in the atmosphere region 501, an outline 492 is displayed for the whole body of the character 491. Further, as shown in FIG. 56( b ), in the high-expectation effect or the low-expectation effect, when the whole body of the character 491 exists in the water region 502, the outline 492 is not displayed for the character 491. Then, as shown in FIG. 56( c ), when the character 491 exists across the air region 501 and the water region 502, the outline 492 is displayed only in the portion existing in the air region 501. In the character 491, the outline 492 is not displayed in the portion existing in the water area 502.

FIG. 57A shows character sprite data 451 which is sprite data for displaying the character 491. The memory module 133 stores a plurality of types of character sprite data 451 for displaying characters 491 in various poses. The display CPU 631 refers to the currently set data table and grasps one character sprite data 451 corresponding to the character 491 displayed at this timing from among the plurality of types of character sprite data 451. The use instruction information of the character sprite data 451 is set in the drawing list.

At the start timing and each update timing, one character sprite data 451 corresponding to each timing is grasped from a plurality of types of character sprite data 451 so as to be displayed on the display surface G of the symbol display device 31. The pose of the character 491 gradually changes, and a series of movements of the character 491 can be displayed.

Since the character sprite data 451 includes only an image area displayed on the display surface G of the symbol display device 31 as an individual image, the outer shape of the character sprite data 451 is the same as the outer shape of the display target character 491. is there. The character sprite data 451 does not include the outline display area 454 for displaying the outline 492. The memory module 633 of the pachinko machine 10 does not store sprite data for displaying the outline 492.

The outline 492 can be displayed by writing the outline display area 454 in the frame areas 642a and 642b. Here, the sizes of the frame areas 642a and 642b are the same as the size of the display surface G of the symbol display device 31. Therefore, the size of the drawing data created by setting the color information and the transparency information in the frame areas 642a and 642b is the same as the size of the display surface G of the symbol display device 31. FIG. 57B is an explanatory diagram for explaining the outline display area 454. As shown in FIG. 57B, the outline of the outline display area 454 is similar to the outline of the character sprite data 451. In addition, the outline of the outline display area 454 is formed by rounding the edge portion of the outline of the character sprite data 451. The outline display area 454 is written by arranging the character sprite data 451 in the frame areas 642a and 642b a plurality of times.

The frame areas 642a and 642b in which the outline display area 454 is written include a large number of unit areas, and an area for storing color information is set in each unit area. First, the unit area 461 of the frame areas 642a and 642b will be described with reference to FIG. FIG. 57C is an explanatory diagram for explaining the color information storage areas 471 to 473 set in each unit area 461 of the frame areas 642a and 642b. As shown in FIG. 57( c ), in each unit area 461, color information storage areas 471 to 473 each consisting of 1 byte are set in a one-to-one correspondence with each color of RGB, and each of the RGB areas is set. It is possible to set 256 colors.

As the value of the numerical value information stored in each of the color information storage areas 471 to 473 is smaller, the darker color in RGB is finally displayed, and in the case of the minimum value, black is displayed. Further, as the value of the numerical information is larger, the color of the lighter degree in RGB is finally displayed, and in the case of the maximum value, white is displayed.

Next, each pixel 462 of the character sprite data 451 will be described with reference to FIG. FIG. 57D is an explanatory diagram for explaining the color information and the transparency information (α value) set in each pixel 462 of the character sprite data 451. As shown in FIG. 57D, color information including numerical information is set to each pixel 462 of the character sprite data 451 by using a palette table or the like. The color information is set as information within the range of 1 byte for each color of RGB.

In addition to the above color information, transparency information is set for each pixel 462. As the transparency information, numerical information of any one of "0 to 100" in decimal is set. The transparency information of “0 to 100” corresponds to the α value of “0 to 1” and is treated as a value less than 1 in the calculation using the α value. Specifically, when “0” is set as the α value, the pixel 462 is completely transparent, and when “1” is set as the α value, the pixel 462 is opaque. If a value greater than “0” and less than “1” is set as the α value, the pixel 462 becomes semi-transparent.

When arranging the character sprite data 451 in the frame areas 642a and 642b, the color information corresponding to the color information and the transparency information of each pixel 462 forming the character sprite data 451 is a unit of the frame areas 642a and 642b. Written in area 461. Specifically, when the α value set in the target pixel 462 of the character sprite data 451 is “1”, the target pixel 462 of the target pixel 462 is set to the corresponding unit area 461 of the frame regions 642a and 642b. The color information is overwritten as it is.

On the other hand, the α value set in the target pixel 462 of the character sprite data 451 is less than “1”, and color information has already been set in the unit area 461 of the frame regions 642 a and 642 b corresponding to the target pixel 462. If the color information is set in the target pixel 462 of the character sprite data 451, and the color information set in the corresponding unit area 461 of the frame areas 642a and 642b, the character sprite data is set. A predetermined calculation using the α value set in the target pixel 462 of 451 is executed, and the calculation result is written in the unit area 461.

Next, a process for setting the single-color character sprite data 451 in the frame regions 642a and 642b a plurality of times so that the VDP 635 writes the outline display region 454 in the frame regions 642a and 642b will be described. Here, the single-color character sprite data 451 is created by rewriting the color information and the transparency information set in all the pixels 462 forming the character sprite data 451 read from the memory module 633. It Specifically, in the confirmation notification effect and the high-expectation effect, red color information and opaque transparency information are set in all pixels of the character sprite data 451. Further, in the low-anticipation notification effect, black color information and opaque transparency information are set for all pixels of the character sprite data 451.

As shown in FIG. 57A, the reference pixel 453 exists in the body of the character sprite data 451. The reference pixel 453 is one of the pixels 462 forming the character sprite data 451. The VDP 635 grasps the coordinates for setting the character sprite data 451 in the frame areas 642a and 642b by referring to the drawing list. Then, the character sprite data 451 is arranged in the frame areas 642a and 642b such that the reference pixel 453 is located at the coordinates set in the drawing list.

The coordinates for arranging the normal character sprite data 451 in which the color information and the transparency information are not rewritten in the frame areas 642a and 642b are set as the normal coordinates. Further, the coordinates for arranging the single-color character sprite data 451 in which the color information and the transparency information are rewritten in the frame areas 642a and 642b are set as special coordinates. The display CPU 631 sets one normal coordinate and four different special coordinates in the drawing list.

FIG. 58A is an explanatory diagram for explaining the positional relationship between the normal coordinates and the special coordinates in the frame areas 642a and 642b. As shown in FIG. 58A, the unit area 458a located at the first special coordinate, which is one of the four different special coordinates, is located in the negative y-axis direction than the unit area 458 located at the normal coordinate. Exists. Specifically, between the unit area 458a located at the first special coordinate and the unit area 458 located at the normal coordinate, there are 50 unit areas 461 when the low-expectancy rendering is performed, and the high expectation There are 75 unit areas 461 when the degree effect or the final notification effect is performed. Further, the unit area 458b located at the second special coordinate, which is one of the four different special coordinates, is present in the positive y-axis direction than the unit area 458 located at the normal coordinate. Specifically, between the unit area 458b located at the second special coordinate and the unit area 458 located at the normal coordinate, there are 50 unit areas 461 when the low-expectancy rendering is performed, and the high-expectation area 461 is present. There are 75 unit areas 461 when the degree effect or the final notification effect is performed.

The unit area 458c located at the third special coordinate, which is one of the four different special coordinates, exists in the negative direction of the x-axis than the unit area 458 located at the normal coordinate. Specifically, between the unit area 458c located at the third special coordinate and the unit area 458 located at the normal coordinate, there are 50 unit areas 461 when the low-anticipation effect is performed, and the high expectation. There are 75 unit areas 461 when the degree effect or the final notification effect is performed. Further, the unit area 458d located at the fourth special coordinate, which is one of the four different special coordinates, exists in the positive direction of the x-axis than the unit area 458 located at the normal coordinate. Specifically, between the unit area 458d located at the fourth special coordinate and the unit area 458 located at the normal coordinate, there are 50 unit areas 461 when the low-expectation effect is performed, and the high-expectation area 461 is present. There are 75 unit areas 461 when the degree effect or the final notification effect is performed.

The unit areas 458a to 458d located at the four special coordinates are vertically and horizontally displaced from the unit area 458 located at the normal coordinates. In the low-expectation effect, the distance from the normal coordinates to the four special coordinates is a distance in which 50 unit areas 461 are arranged, and the distance is about 10% of the width of the character sprite data 451 in the initial state. .. In the high-expectation effect or the confirmation notification effect, the distance from the normal coordinates to the four special coordinates is 1.5 times that in the low-expectation effect. Based on the four special coordinates, the single-color character sprite data 451 is arranged in the frame regions 642a and 642b in a state of being slightly shifted vertically and horizontally.

In the character sprite data 451, a region corresponding to the head of the character 491 is a head region 452 (FIG. 57(a)). Further, when the VDP 635 arranges the single-color character sprite data 451 based on the first special coordinates, the area in which the head area 452 is arranged is the first head area 452a, and the VDP 635 is the second special area. When the single-color character sprite data 451 is arranged based on the coordinates, a region where the head region 452 is arranged is referred to as a second head region 452b. When the VDP 635 arranges the single-color character sprite data 451 based on the third special coordinates, the area in which the head area 452 is arranged is the third head area 452c, and the VDP 635 is the fourth special area. An area in which the head area 452 is arranged when the single-color character sprite data 451 is arranged based on the coordinates is referred to as a fourth head area 452d.

The number of the character sprite data 451 stored in the memory module 633 is one, and the process of arranging the single-color character sprite data 451 four times is performed by reading the same character sprite data 451 four times. Done.

FIG. 58B is an explanatory diagram for explaining the positional relationship between the first head region 452a to the fourth head region 452d in the frame regions 642a and 642b. As shown in FIG. 58(b), the first head region 452a to the fourth head region 452d are displaced vertically and horizontally. Further, the first head region 452a to the fourth head region 452d have an overlapping region.

The VDP 635 sets the color information of a single color in order from the unit area 461 included in the first head area 452a. Since the non-transparent transparency information is set in all the pixels 462 forming the single-color character sprite data 451, the same color information as in the other areas is overwritten in the unit area 461 of the overlapping area. .. Therefore, the same color information is set in all the unit areas 461 included in the first head area 452a to the fourth head area 452d. By setting the same color information in the first head region 452a to the fourth head region 452d, the boundary lines of the respective regions 452a to 452d are displayed as one region without being displayed. The area is defined as a head outline display area 457.

FIG. 58C is an explanatory diagram for explaining the outline display area 457 of the head. The outline display area 457 of the head has an outer shape similar to the outer shape of the head area 452 of the character sprite data 451. Further, when the normal character sprite data 451 is arranged in the frame areas 642a and 642b at the same magnification as the single color character sprite data 451, the outline display area 457 of the head is the normal character sprite data. It is slightly larger than the head region 452 at 451.

As shown in FIG. 58A, the normal coordinates are coordinates located at the center of four special coordinates that are vertically and horizontally displaced. Therefore, in the frame areas 642a and 642b, after setting color information of a single color in all unit areas 461 included in the outline display area 457 of the head, the VDP 635 sets the normal character sprite data 451 based on the normal coordinates. When arranged, the head region 452 of the normal character sprite data 451 is located at the center of the outline display region of the head.

Non-transparent transparency information is set to the pixel 462 of the character sprite data 451. Therefore, in addition to the unit area 461 included in the outline display area 457 of the head, the unit area 461 included in the area in which the head area 452 of the normal character sprite data 451 is arranged includes The color information of the sprite data 451 is overwritten as it is.

FIG. 58D is an explanatory diagram for explaining the protruding area 455 of the head displayed outside the head area 452 when the head area 452 is overwritten on the outline display area 457 of the head. Is. Since the outline display area 457 of the head is slightly larger than the head area 452, a part of the outline display area 457 of the head remains without being overwritten and becomes the protruding area 455 of the head. Since the head region 452 is arranged at the center of the head outline display region 457, the head protrusion region 455 surrounds the outer edge of the head region 452.

Although the relationship between the outline display area 457 of the head and the head area 452 has been described above using the head of the character 491 as a specific example, the same relationship holds for the other parts of the character 491. For each part of the character 491, the outline display area of each part has an outer shape similar to the outer shape of each part area of the character sprite data 451. Further, when the normal character sprite data 451 is arranged in the frame areas 642a and 642b at the same magnification as the single color character sprite data 451, the outline display area of each part is each part of the character sprite data 451. One size larger than the area. Since the same color information is set in all the unit areas 461 included in the outline display area of each part of the character 491, no boundary line is displayed in the area where the outline display areas of each part overlap. Therefore, as shown in FIG. 57B, the outline display areas of the respective parts are connected to form one outline display area 454.

FIG. 58E is an explanatory diagram for explaining a protruding area 455 that is displayed outside the character sprite data 451 when the normal character sprite data 451 is overwritten in the outline display area 454. When the normal character sprite data 451 is overwritten on the outline display area 454, a part of the outline display area 454 that remains without being overwritten becomes the protruding area 455. The protruding area 455 borders each area of the character 491, and an outline 492 is displayed.

As shown in FIG. 58(e), since the outline display area 454 protrudes from the character sprite data 451 in the same width vertically and horizontally, the projection area 455 is formed in four directions without being limited to a specific direction. .. Further, the protruding area 455 is not limited to a specific part of the character 491, and is formed in the same manner around all the parts of the character 491. Therefore, the protruding area 455 surrounds the outer edge of the character sprite data 451 without interruption, and is displayed in a manner recognized by the player as the outline 492 of the character 491.

An outline display area 454 is created by shifting the single-color character sprite data 451 vertically and horizontally, and the normal character sprite data 451 is overwritten in the outline display area 454, so that an outline 492 surrounds the character 491. The method of displaying is described above. The difference between the outline 492 displayed by this method and the outline displayed by another method will be described.

As another method for displaying the outline around the character 491, a method of enlarging the character sprite data 451 to create the outline display area 456 can be considered. The method will be described with reference to FIG. The VDP 635 first reads the character sprite data 451 from the memory module 633, sets single color information and non-transparent transparency information in all the pixels 462 forming the data, and sets the reference pixel 453 at the center. The data is expanded as. Then, the enlarged data is arranged in the frame regions 642a and 642b in a manner such that the reference pixel 453 of the enlarged data is located at the normal coordinates to create the outline display region 456.

In this case, the outline display area 456 has the same outer shape as the character sprite data 451 and is slightly larger than the character sprite data 451. Next, the VDP 635 arranges the normal character sprite data 451 in the frame areas 642a and 642b in such a manner that the reference pixel 453 is located at the normal coordinates. Since the non-transparent transparency information is set for the pixels 462 forming the normal character sprite data 451, the pixels 462 are included in the outline display area 456, and in the area where the normal character sprite data 451 is arranged. In the included unit area 461, the color information of the normal character sprite data 451 is directly overwritten.

Since the outline display area 456 is slightly larger than the character sprite data 451, a part of the outline display area 456 overflows from the character sprite data 451. Around the body located at the center of the character sprite data 451, the outline display area 456 protrudes in all directions in the same manner, so that a natural outline is displayed. However, an unnatural outline is displayed around the part existing at a position deviated from the center of the character sprite data 451.

Specifically, in the head located above the center of the character sprite data 451, the outline display area 456 extends in an upwardly widened manner, so that a thick outline is displayed only above the head. The outline is not displayed below the head. In the leg portion located below the center of the character sprite data 451, the outline display area 456 protrudes in a downward wide area, so that a thick outline is displayed only on the lower side of the leg portion, and the leg portion is displayed. No outline is displayed above. In the left arm portion located to the left of the center of the character sprite data 451, the outline display area 456 extends in the leftward direction. Therefore, a thick outline is displayed only on the left side of the left arm portion, and the left arm portion is displayed. The outline is not displayed below. In the right arm portion located to the right of the center of the character sprite data 451, the outline display area 456 extends in the rightward direction. Therefore, a thick outline is displayed only on the right side of the right arm portion, and the right arm portion is displayed. No outline is displayed on the left side of.

As described above, the method of creating the outline display area 454 by shifting the single-color character sprite data 451 vertically and horizontally is possible because it is possible to display the uniform outline 492 in all the parts constituting the character 491. Is more effective than the method.

Next, a method of displaying the blurring outline 459 in the finalization notification effect will be described with reference to FIGS. 59(a) to 59(e). FIG. 59A shows a blurred outline display area 474 created by performing a blurring process on the outline display area 454. The blurring process for creating the blurred outline display region 474 is a process of reducing the outline display region 454 and then expanding it again to the original size.

Here, the blurring process will be described by using the image of the straight line 481 included in the character sprite data 451 as a specific example. FIG. 59B is an explanatory diagram for explaining the straight line 481 before the blurring process. As shown in FIG. 59B, the straight line 481 before the blurring process is a square area 484 in which eight unit areas 461 are arranged in the x-axis direction and eight unit areas 461 are arranged in the y-axis direction. It is displayed by setting the color information in a part of the unit areas 461 that compose it. The straight line 481 before blurring has four unit areas 461 in which color information is set in the x-axis direction and one unit area 461 in which color information is set in the y-axis direction. The rectangular unit structure is displayed by being set in such a manner that each time it shifts by 1 in the positive direction of the y-axis, it shifts by 1 in the negative direction of the x-axis.

FIG. 59C is an explanatory diagram for explaining a straight line 482 after reduction which is created by reducing the straight line 481 before blurring by 50% in the x-axis direction and by reducing it by 50% in the y-axis direction. is there. As shown in FIG. 59C, the straight line 482 after reduction forms a square area 485 in which four unit areas 461 are arranged in the x-axis direction and four unit areas 461 are arranged in the y-axis direction. It is displayed by setting the color information in some of the unit areas 461. The straight line 482 after reduction has a rectangular unit structure in which two unit areas 461 are arranged in the x-axis direction and one unit area 461 is arranged in the y-axis direction, and the rectangular unit structure is displaced by 1 in the positive direction of the y-axis. It is displayed by being set in such a manner that it is shifted by 1 in the negative direction of the x-axis for each time.

FIG. 59D is a blur straight line 483 created by expanding the reduced straight line 482 once again to the original size. As shown in FIG. 59D, the blur straight line 483 forms a square area 486 in which eight unit areas 461 are arranged in the x-axis direction and eight unit areas 461 are arranged in the y-axis direction. It is displayed by setting color information in the unit area 461 of the set. The blur line 483 has four unit areas 461 arranged in the x-axis direction, and a rectangular unit structure in which two unit areas 461 are arranged in the y-axis direction is displaced by 2 in the positive direction of the y-axis. It is displayed by being set in a manner shifted by two in the negative direction of the x-axis.

The blurring process causes the lines to be displayed roughly. After the outline display area 454 is drawn in the frame areas 642a and 642b, blurring processing is performed on the frame areas 642a and 642b to roughen the outline of the outline display area 454 and blur the outline. An outline display area 474 is created. Before and after the blurring process, the position of the blurring outline display region 474 in the frame regions 642a and 642b does not change. Therefore, when the VDP 635 arranges the normal character sprite data 451 in the frame areas 642a and 642b based on the normal coordinates after the blurring processing, most of the unit areas 461 included in the blurring outline display area 474 have The color information of the character sprite data 451 is overwritten.

The blurred outline display area 474 is slightly larger than the character sprite data 451. The character sprite data 451 is arranged in the center of the blur outline display area 474. For this reason, a part of the blurred outline display area 474 is projected from the character sprite data 451, and a blurred projection area 475 is formed. The blurring out area 475 evenly extends out in all directions of the character sprite data 451. Further, the outline of the blurring-out area 475 is blurred. Therefore, the outline of the character 491 displayed by the blurring-out area 475 becomes the blurring outline 493.

In the configuration in which the data for displaying the outline 492 and the data for displaying the character 491 are separately handled, the blurring process is performed only on the data for displaying the outline 492, so that the outline 492 is not blurred. You can blur only.

Next, as shown in FIGS. 56A to 56C, a process for displaying the water area 502 will be described. FIG. 59F is an explanatory diagram for explaining the water image data 503 stored in the memory module 633. The water image data 503 has an outer shape in which one side of a rectangle is replaced with a gentle wavy line, and blue color information and semi-transmissive transparency information are set in all the pixels 462 of the water image data 503. ing.

The R value set for all pixels 462 of the water image data 503 is twice the R value for displaying the water region 502, and the G value set for all pixels 462 of the water image data 503. The value is twice the G value for displaying the water region 502. Further, the B value set in all the pixels 462 of the water image data 503 is twice the B value for displaying the water region 502, and is set in all the pixels 462 of the water image data 503. The α value is “0.5”. Therefore, by using the α value of “0.5” set in each pixel 462 of the water image data 503, the color information set in each pixel 462 of the water image data 503 and the black color information are set. When blended with each other, color information for displaying the water region 502 is obtained.

One reference pixel 503a is set in the water image data 503. The VDP 635 arranges the water image data 503 in the frame areas 642a and 642b based on the parameters set in the drawing list. Here, the parameters of the water image data 503 include the coordinates of the reference pixel 503 a, the rotation angle of the water image data 503, and the magnification of the water image data 503.

First, the high-expectation effect or low-expectation effect in which the blurring process is not performed will be described. The VDP 635 arranges the single-color character sprite data 451 four times to draw the outline display area 454 in the frame areas 642a and 642b, and then based on the use instruction information of the water image data 503 set in the drawing list. Then, the water image data 503 is read from the memory module 633.

The VDP 635 changes the color information set in all the pixels 462 of the water image data 503 into black color information, and changes the transparency information set in all the pixels 462 into opaque transparency information. , Black water image data 503 is created. Specifically, the R value, the G value, and the B value set in all the pixels 462 of the water image data 503 are changed to “0”, and the α value is changed to “1”. Then, the black water image data 503 is arranged in the frame areas 642a and 642b. Since opaque transparency information is set for all pixels 462 of the black water image data 503, black color information is overwritten on all unit areas 461 included in the water region 502.

When the entire outline display area 454 is drawn in the atmosphere area 501 (FIG. 56A), the color information set in all the unit areas 461 included in the outline display area 454 is maintained. It On the other hand, when the entire outline display area 454 is drawn in the water area 502 (FIG. 56B), the color information set in all the unit areas 461 included in the outline display area 454 is displayed. The color information is changed to black, and the outline display area 454 is no longer displayed. When a part of the outline display area 454 is drawn in the water area 502 (FIG. 56(c)), the unit area 461 included in the outline display area 454 has a unit included in the water area 502. The color information set in the area 461 is changed to black color information. As a result, the portion of the outline display area 454 existing in the water area 502 is not displayed, and only the portion of the outline display area 454 existing in the atmosphere area 501 remains.

The VDP 635 arranges the black water image data 503 in the frame areas 642a and 642b, and then arranges the normal character sprite data 451 in the frame areas 642a and 642b. When the normal character sprite data 451 is arranged in the atmosphere area 501, since the outline display area 454 is drawn behind it, an outline 492 is displayed around the character 491. The outline 492 is displayed on the entire character 491. On the other hand, when the normal character sprite data 451 is arranged in the water area 502, the outline 492 is not displayed because the outline display area 454 is not drawn behind it. Further, when the normal character sprite data 451 is arranged so as to straddle the atmosphere area 501 and the water area 502, a part of the outline display area 454 is drawn in the atmosphere area 501. The outline 492 is displayed only in the portion existing in the atmosphere region 501.

After arranging the normal character sprite data 451 in the frame areas 642a and 642b, the VDP 635 reads the water image data 503 again, and changes the normal water image data 503 into the frame area without changing the color information and the transparency information. It is arranged at 642a and 642b. Here, the parameter when arranging the black water image data 503 and the parameter when arranging the normal water image data 503 are the same.

For all the pixels 462 of the normal water image data 503, an R value that is twice the R value for displaying the water region 502, a G value that is twice the G value for displaying the water region 502, and water. Since the B value that is twice the B value for displaying the area 502 and the α value of “0.5” are set, the unit area 461 included in the water area 502 is currently in the unit area 461. The color information obtained by blending the color information set to No. 1 and the color information of the water image data 503 based on the α value of “0.5” set to the normal water image data 503 is set. To be done. When the color information set in the current unit area 461 is black color information, color information for displaying the water region 502 is set in the unit area 461.

The high-expectation effect or low-expectation effect in which the blurring process is not performed has been described above. In the confirmation notification effect in which the blurring process is performed, the blurring process is performed after the outline display region 454 is drawn in the frame regions 642a and 642b and before the black water image data 503 is arranged in the frame regions 642a and 642b. .. In this case, a blurred outline 493 is displayed on the portion of the character 491 that exists in the atmosphere area 501.

Hereinafter, a specific processing configuration for displaying the outline 492 or the blurred outline 493 will be described. FIG. 60 is a flowchart showing the arithmetic processing for outline display effect executed by the display CPU 631. The outline display effect calculation process is executed by the effect calculation process of step S3106 in the task process (FIG. 57). In addition, the calculation process for the outline display effect is started when the information about the outline display effect is set in the currently set data table.

First, in step S3201, the character sprite data 451 is grasped based on the currently set data table, and in step S3202, the parameters of the character sprite data 451 are calculated and derived, and the derived parameter information is used as a work. The control information is updated by writing in an area secured in the RAM 632 in correspondence with the character sprite data 451.

In step S3203, based on the currently set data table, it is determined whether or not the effect this time is the final notification effect. When the effect this time is the final notification effect (step S3203: YES), in step S3204, the color information of red is grasped as the color information set in the outline display area 454, and in step S3205, it is blurred. The processing designation information is stored. When the blurring process designation information is set in the drawing list, the VDP 635 executes the blurring process for blurring the outline display area 454.

In step S3206, the parameters derived in step S3202 are used to calculate and derive four parameters for arranging the single-color character sprite data 451 four times in the frame regions 642a and 642b. In the finalization notification effect, parameters for displaying the thick blur outline 493 are derived, and information of the derived parameters is written in an area secured in the work RAM 632 in association with the single-color character sprite data 451 for control. Update information. The four parameters of the single-color character sprite data 451 include four special coordinates, and the distance from the normal coordinates to the four special coordinates is the distance in which 75 unit areas 461 are arranged.

If the effect this time is not the finalized notification effect (step S3203: NO), it is determined in step S3207 whether or not the effect this time is a high-expectation effect, based on the currently set data table. .. When the effect this time is a high-expectation effect (step S3207: YES), in step S3208, the color information of red is grasped as the color information set in the outline display area 454.

In step S3209, the parameters derived in step S3202 are used to calculate and derive four parameters for arranging the single-color character sprite data 451 four times in the frame regions 642a and 642b. In the high-expectation production, a parameter for displaying the thick outline 492 is derived, and information of the derived parameter is written in the area secured in the work RAM 632 in association with the single-color character sprite data 451 for control. Update information. The four parameters of the single-color character sprite data 451 include four special coordinates, and the distance from the normal coordinates to the four special coordinates is the distance in which 75 unit areas 461 are arranged.

If the effect this time is not the high-expectation effect (step S3207: NO), it means that the effect this time is the low-expectation effect. Therefore, in step S3210, the color information set in the outline display area 454 is set. As to grasp the black color information.

In step S3211, the parameters derived in step S3202 are used to calculate and derive four parameters for arranging the single-color character sprite data 451 four times in the frame areas 642a and 642b. In the low-expectation rendering, parameters for displaying the thin outline 492 are derived, and the information of the derived parameters is written in the area secured in the work RAM 632 in correspondence with the single-color character sprite data 451 for control. Update information. The four parameters of the single-color character sprite data 451 include four special coordinates, and the distance from the normal coordinates to the four special coordinates is the distance in which 50 unit areas 461 are arranged.

After the process of step S3206, the process of step S3209, or the process of step S3211, in step S3212, the water image data 503 for displaying the water region 502 is grasped based on the currently set data table, and step S3213. Then, the black color information and the opaque transparency information are grasped as the color information and the transparency information for creating the black water image data 503. In a succeeding step S3214, parameters of the water image data 503 are calculated and derived, and information of the derived parameters is written in an area secured in the work RAM 632 in correspondence with the water image data 503 to update the control information. Then, this arithmetic processing is ended.

When the calculation processing for the outline display effect is executed as described above, in the subsequent drawing list output processing, a drawing list in which both the character sprite data 451 and the water image data 503 are set as drawing targets is created. .. Further, in the drawing list, color information of the outline display area 454, presence/absence of blurring process designation information, parameter information of the character sprite data 451, parameter information of the single color character sprite data 451, and water image data 503. The parameter information and the parameter information of the black water image data 503 are included. Then, the created drawing list is transmitted to the VDP 635.

Next, the drawing processing for outline display effect executed in the VDP 635 will be described with reference to the flowchart in FIG. The drawing process for the outline display effect is executed as a part of the writing process executed in step S3004 of the drawing process (FIG. 54).

First, in step S3301, an outline display area drawing process for drawing the outline display area 454 or the blurred outline display area 474 is executed. Here, the drawing process of the outline display area will be described with reference to the flowchart of FIG. FIG. 62 is a flowchart showing the drawing processing of the outline display area executed by the VDP 635.

First, in step S3401, "1" is added to the variable n. Here, the variable n is a variable that can take an integer from “0” to “4”. The variable n indicates the number of times the single-color character sprite data 451 is drawn to draw the outline display area 454 or the blurred outline display area 474. In step S3402, the color information set in the outline display area 454 or the blurred outline display area 474 is grasped based on the drawing list. In the following step S3403, the character sprite data 451 is read based on the drawing list. In step S3404, the color information acquired in step S3402 is set in all pixels 462 of the character sprite data 451 to create single-color character sprite data 451, and in step S3405, the single color is created based on the drawing list. The n-th parameter of the character sprite data 451 is grasped.

Four different parameters necessary for drawing the outline display area 454 or the blurred outline display area 474 are set in the drawing list. As the number of times the single-color character sprite data 451 is drawn changes, the parameters for the drawing also change. Specifically, in the first drawing, coordinates deviating from the normal coordinates of the character sprite data 451 in the negative direction of the x-axis are used, and in the second drawing, the positive direction of the x-axis is used. Coordinates that are offset to are used. Further, in the third drawing, the coordinates deviated in the negative direction of the y-axis from the coordinates of the normal character sprite data 451 are used, and in the fourth drawing, the coordinates deviated in the positive direction of the y-axis. Existing coordinates are used.

In step S3406, the nth outline drawing process is executed using the nth parameter of the single-color character sprite data 451 grasped in step S3405. In the outline drawing process, the single-color character sprite data 451 is drawn in the frame areas 642a and 642b set as the creation target. Since opaque transparency information is set for all the pixels 462 of the single-color character sprite data 451, red color information or black color is set in the drawing target unit area 461 depending on the effect to be executed. Information is overwritten.

In step S3407, it is determined whether the variable n is “4”. When the variable n is a number equal to or less than “3” (step S3407: NO), the process returns to step S3401 again. On the other hand, if the variable n is "4" (step S3407: YES), the variable n is cleared to "0" in step S3408, and the blurring process designation information is set in the drawing list this time in step S3409. It is determined whether or not there is. If the blurring designation information is not set (step S3409: NO), the main drawing process is ended as it is. On the other hand, when the blurring designation information is set (step S3409: YES), the process proceeds to step S3410.

In step S3410, the outline display area 454 or the blurred outline display area 474 drawn in the frame areas 642a and 642b to be created is reduced, and in the following step S3411, the outline display area reduced in step S3410 is displayed. Enlargement processing for returning the area 454 or the blurred outline display area 474 to the original size is performed again, and the main drawing processing ends. By the blurring process executed in steps S3410 and S3411, the outer edge of the outline display area 454 or the blur outline display area 474 becomes rough, and the line forming the outline of the outline display area 454 or the blur outline display area 474 is formed. Is blurred.

Returning to the description of the outline display effect drawing process (FIG. 61 ), after performing the outline display area drawing process in step S3301, the water image data 503 is grasped based on the current drawing list in step S3302. In step S3303, black opaque color information and transparency information are grasped to create black water image data 503. Then, in step S3304, black color information and opaque transparency information are set in all pixels 462 of the water image data 503 to create black water image data 503.

In a succeeding step S3305, the parameters of the water image data 503 are grasped with reference to the drawing list, and the black water image data 503 is arranged in the frame regions 642a and 642b to be created in step S3306. Since the non-transmissive transparency information is set in all the pixels 462 of the black water image data 503, the black color information is overwritten in the drawing target unit area 461. As a result, in the outline display area 454 or the blurred outline display area 474 drawn in the frame areas 642a and 642b to be created, the area included in the atmosphere area 501 remains and the area included in the water area 502 becomes black. Is filled.

In step S3307, the character sprite data 451 is grasped based on the current drawing list, and in step S3308, the parameter of the character sprite data 451 is grasped based on the current drawing list. Then, in step S3309, the character sprite data 451 is drawn in the frame areas 642a and 642b to be created. Since the non-transparent transparency information is set for all the pixels 462 of the character sprite data 451, the color information of the character sprite data 451 is overwritten on the drawing target unit area 461 in the creation target frame areas 642a and 642b. To be done. As a result, the character sprite data 451 is overwritten on the outline display area 454 or the blurred outline display area 474 drawn in the frame areas 642a and 642b to be created, and the outline 492 is applied only to the portion included in the atmosphere area 501. Alternatively, the blurring outline 493 is displayed.

In step S3310, the water image data 503 is grasped based on the drawing list of this time, and in step S3311, the parameters of the water image data 503 are grasped based on the drawing list of this time. Then, in step S3312, the water image data 503 is drawn in the frame areas 642a and 642b to be created, and the main drawing process ends. Since the blue semi-transparent color information and the transparency information are set in all the pixels 462 of the water image data 503, the color information set in the unit area 461 and the blue color are set in the drawing target unit area 461. Color information obtained by blending with the color information is set. The blending is performed based on the transparency information set in the water image data 503.

As described above, by creating the single-color character sprite data 451 and drawing the single-color character sprite data 451 at a position slightly deviated from the position where the character 491 is drawn vertically and horizontally, the outline display The area 454 is drawn in the frame areas 642a and 642b to be created. Then, the character sprite data 451 is drawn in the frame areas 642a and 642b to be created in such a manner as to overwrite the outline display area 454 or the blurred outline display area 474. As a result, the outline display area 454 or the blurred outline display area 474 is displayed by slightly protruding from the character sprite data 451 vertically and horizontally. The protruding portion is displayed as an outline 492 or a blurred outline 493. The outline 492 or the blurred outline 493 can be displayed uniformly on all sides of the character 491. Further, the single color information set in the unit area 461 included in the outline display area 454 or the blurred outline display area 474 can be changed according to the effect to be executed. Therefore, the same character sprite data 451 can be used to display outlines 492 or blur outlines 493 of different colors on the outer edge of the same character 491. Furthermore, the thickness of the outline 492 or the blur outline 493 can be changed by changing the position where the single-color character sprite data 451 is arranged.

The memory module 633 stores a plurality of types of character sprite data 451 one by one, and grasps one character sprite data 451 a plurality of times at the start timing or the update timing and repeatedly draws on the frames 642a and 642b to be created. It was configured to do. Specifically, in order to draw the outline display area 454, the character sprite data 451 is grasped four times and arranged vertically and horizontally to the left and right of the character 491, and the character sprite is drawn to draw the character 491. The data 451 is grasped once and arranged in the frames 642a and 642b to be created. Thereby, the character 491 and the outline 492 or the blurred outline 493 can be displayed using one character sprite data 451. Compared to the case where the data for displaying the character 491 and the data for displaying the outline 492 or the blurred outline 493 are individually stored in the memory module 633, the data capacity to be stored in advance can be reduced.

The four different parameter information necessary for arranging the character sprite data 451 by shifting the character 491 vertically and horizontally is derived from the parameter information for drawing the character 491. As a result, the data capacity to be stored in advance is compared with the case where the parameter information for drawing the character 491 and the four different parameter information for drawing the outline display area 454 are individually stored in the memory module 633. Can be reduced.

After drawing the outline display area 454 in the frame areas 642a and 642b to be created, the unit area 461 included in the water area 502 is overwritten with black color information, and then the character sprite data 451 is added to the outline display area 454. Alternatively, the drawing is performed in a manner of overwriting in the blurred outline display area 474. As a result, with respect to the character 491, the outline 492 or the blur outline 493 is displayed in the region existing in the atmosphere region 501, but the outline 492 or the blur outline 493 is not displayed in the region existing in the water region 502. In this way, the outline 492 or the blur outline 493 can be partially displayed for the character 491.

The outline display area 454 is reduced, and then expanded again to the original size to create the blurred outline display area 474. Then, the character sprite data 451 is drawn in such a manner as to overwrite the blurred outline display area 474. As a result, a blurred outline 493 with a blurred outline can be displayed on the outer edge of the character 491. Since the blurring process is selectively executed in the outline display area 454, it is possible to display a combination of a clear image of the character 491 and a blurring outline 493 with a blurred outline.

In the case of the final notification effect, a red blur outline 493 is displayed on the outer edge of the character 491, and in the case of high-expectation effect, a red outline 492 is displayed on the outer edge of the character 491. Further, in the case of the low expectation effect, a black outline 492 is displayed on the outer edge of the character 491. As a result, the player can know the expectation of a big hit and the like by looking at the outer edge of the character 491.

<Another form of outline display production>
In the configuration for executing the outline display effect described above, the target to which the outline 492 is added is not limited to the character 491 represented by using the two-dimensional character sprite data 451. For example, a character represented by using a three-dimensional object may be selected as a target to which the outline is added.

Specifically, first, an object for displaying a character is set in the world coordinate system based on the coordinates set in the parameter of the object, and the normal projection data is obtained by projecting it on the screen area PC12. create. Then, in the normal projection data, a texture for displaying the character is applied to the projection area where the object is actually projected.

Next, the object for displaying the character is set to a position in the world coordinate system, which is moved by a predetermined amount in the positive direction of the x-axis from the coordinates set in the parameter of the object, and the same object is set. Is set to a position moved by a predetermined amount in the negative direction of the x-axis from the coordinates set in the parameter of the object. In addition, the object for displaying the character is set to a position that is moved in the positive direction of the y-axis by a predetermined amount in the world coordinate system from the coordinates set in the parameter of the object, and the same object is set. It is set at a position moved by a predetermined amount in the negative direction of the y-axis with respect to the coordinates set in the parameter of the object.

Projection data for outline display is created by projecting the four objects set in the world coordinate system onto the screen area PC12. Then, in the outline display projection data, a single color information is set to all the dots forming the projection area in which the four objects are actually projected.

The two projection data have the same rectangle and the same size. In the two projection data, the same number of dots are lined up in the vertical direction and the same number of dots are lined up in the horizontal direction. Therefore, each dot forming the normal projection data and each dot forming the projection data for outline display are associated with each other on a one-to-one basis.

Next, the projection data for outline display is set as the basic data, and the normal projection data is set as the priority data to execute the combining process. In the combining process, the color information set in the dots forming the basic data is updated according to the color information and the transparency information set in the dots forming the priority data. Specifically, when the non-transparent transparency information is set for the priority data dot, the corresponding dot of the basic data is overwritten with the color information set for the priority data dot. When semi-transparent transparency information is set for a priority data dot, the color information and the basic information set for the priority data dot are based on the transparency information set for the priority data dot. The color information set in the corresponding dot of the data is blended, and the color information obtained by the blending is overwritten on the corresponding dot of the basic data. Then, when the transparency information set to the dot of the priority data is complete transparency, the color information set to the corresponding dot of the basic data is maintained.

Thereby, in the overwritten basic data, a single-color outline is displayed at the outer edge of the character. The outer shape of the projection area of the object for displaying the character changes according to the relative relationship between the object for displaying the character and the viewpoint in the world coordinate system. Therefore, in the configuration in which the two-dimensional data for displaying the outline is stored in the memory module 633 in advance, it is necessary to store a large amount of two-dimensional data in order to correspond to various outer shapes of projection data. .. On the other hand, in the configuration in which the projection data for displaying the character and the projection data for displaying the outline are individually created, only one object for displaying the character stored in the memory module 633 is used. Since the character and the outline can be displayed as a result, the amount of data stored in the memory module 633 can be reduced.

In the configuration for executing the outline display effect described above, the target for drawing the outline display area 454 is not limited to the frame areas 642a and 642b that are the creation target. For example, the frame buffer 642 may be provided with an outline drawing area for creating the data of the outline display area 454 or the blurred outline display area 474, and the outline display area 454 may be drawn in the outline drawing area. ..

The timing of drawing the outline display area 454 is not limited to the start timing and all update timings. For example, the data of the outline display area 454 corresponding to the shape of the character sprite data 451 or the blurred outline display only at the timing when the new type of character sprite data 451 is used among the start timing and all the update timings. The data of the working area 474 is created and separately saved, and when the data of the outline display area 454 corresponding to the character sprite data 451 is already separately saved, the separately-displayed outline display is performed. The data in the working area 454 or the data in the blurred outline display area 474 may be read and used.

Specifically, the frame buffer 642 is provided with an outline drawing area corresponding to an area smaller than the display surface G of the symbol display device 31. At the start timing, the VDP 635 shifts the single-color character sprite data 451 vertically and horizontally in the outline drawing area, and draws the outline display area 454. The VDP 635 sets an α value of “0” to the pixel 462 in which the single-color character sprite data 451 is not arranged in the outline drawing area.

When the confirmation notification effect is performed, an outline display area 454 for displaying the thick blur outline 493 is drawn. Then, after the outline display area 454 is reduced, the outline display area 454 is enlarged again to the original size, and the data of the blurred outline display area 474 is created and separately stored.

When the high-expectation effect is performed, the outline display area 454 for displaying the thick outline 492 is drawn, and the obtained data is stored separately. When the low-expectation effect is performed, the outline display area 454 for displaying the thin outline 492 is drawn, and the obtained data is stored separately.

The created data of the blurred outline display area 474 or the created outline display area 454 includes one reference pixel 462. Further, in the memory module 633, parameters for arranging the data of the blurred outline display area 474 or the outline display area 454 in the frame areas 642a and 642b to be created are set at the start timing and each update timing. Table is stored. The display CPU 631 sets a parameter for arranging the data of the blurred outline display area 474 or the outline display area 454 in the frame areas 642a and 642b to be created in the drawing list based on the table. Then, the VDP 635 refers to the drawing list and grasps a parameter for arranging the data of the blurred outline display area 474 or the outline display area 454 in the frame areas 642a and 642b to be created.

In the confirmation notification effect, the high-expectation effect, or the low-expectation effect, the data of the blurring outline display area 474 or the outline display area 454 that has been created once is stored until the effect ends. At each update timing, the VDP 635 grasps the character sprite data 451 to be used this time, and then the data of the blurred outline display area 474 or the outline display area 454 corresponding to the character sprite data 451 is already created. It is determined whether or not If the data is already created, the separately stored data of the blurred outline display area 474 or the outline display area 454 is read and used. If the data has not been created, the data of the blurred outline display area 474 or the data of the outline display area 454 corresponding to the current character sprite data 451 is newly created and separately stored.

The same character sprite data 451 is created this time by creating and separately storing the data of the blurred outline display area 474 or the outline display area 454 corresponding to the area smaller than the display surface G of the symbol display device 31. The data in the blurring outline display area 474 or the data in the outline display area 454 can be used even when they are arranged at different positions.

Since the outline display area 454 of the same character sprite data 451 is not drawn twice or more in the confirmation notification effect, the high expectation effect, or the low expectation effect, the processing load for executing the outline display effect is reduced. can do.

In the configuration for executing the outline display effect described above, the effect added to the character 491 by arranging the character sprite data 451 a plurality of times in the frame areas 642a and 642b to be created is not limited to the outline 492. For example, an afterimage of the moving character 491 can be displayed.

Specifically, the character sprite data 451 is read and the color information set in all the pixels 462 forming the character sprite data 451 is changed to black color information to create the black character sprite data 451. To do. Then, with respect to the character 491 drawn in the frame areas 642a and 642b to be created, a plurality of black character sprite data 451 are arranged side by side in the direction opposite to the moving direction of the character 491 (direction of the moving source). ..

As a result, the area in which the black color information is set is displayed as an afterimage of the moving character 491, and it is displayed in an easy-to-understand manner that the character 491 moved from the movement source to the current position. Since the character 491 and the afterimage of the character 491 are displayed using the same character sprite data 451, data for displaying the character 491 and data for displaying the afterimage of the character 491 are stored separately. In comparison, the data capacity stored in the memory module 633 can be reduced.

By arranging the character sprite data 451 multiple times in the frame areas 642a and 642b to be created, the shadow of the character 491 reflected on the wall behind the character 491 can be displayed.

Specifically, the character sprite data 451 is read out, and the color information set in all the pixels 462 forming the character sprite data 451 is changed to black color information to convert the black character sprite data 451. create. Then, in the frame areas 642a and 642b to be created, the black character sprite data 451 is arranged at a position shifted by a predetermined distance diagonally to the upper right from the area in which the character 491 is drawn. By drawing the normal character sprite data 451 in a manner of overwriting the shadow, the shadow of the character 491 reflected on the wall behind the character 491 can be displayed.

Further, by enlarging the black character sprite data 451 arranged in the frame areas 642a and 642b to be created to display the shadow, the shadow of the character 491 reflected on the wall at a position distant from the character 491 is displayed. be able to. Since the character 491 and the shadow of the character 491 are displayed using the same character sprite data 451, data for displaying the character 491 and data for displaying the shadow of the character 491 are stored separately. In comparison, the data capacity stored in the memory module 633 can be reduced.

Further, a translucent aura can be displayed on the whole body of the character 491. First, the normal character sprite data 451 is drawn in the frame areas 642a and 642b to be created. After that, the same character sprite data 451 is read out, and the color information set in all the pixels 462 forming the character sprite data 451 is changed to red color information and is set in all the pixels 462. The transparency information is changed to semi-transparent transparency information to create aura sprite data. Then, the aura display area is drawn by shifting the aura sprite data from the character 491 in the vertical and horizontal directions.

Specifically, when color information is not set in the unit area 461 in which the aura display area is drawn, the color information of the aura display area is set in the unit area 461 as it is. On the other hand, when color information is set in the unit area 461 in which the aura display area is drawn, the color information set in the unit area 461 and the color information set in the aura display area are combined. , The blending is performed based on the transparency information set in the aura display area, and the blending result is set to the drawing target dot.

Accordingly, the red semi-transparent aura can be displayed on the whole body of the character 491. Since the aura display area is drawn using the character sprite data 451, the image data stored in the memory module 633 in advance is compared with the case where the image data for displaying the aura display area is stored in advance. The data capacity of can be reduced.

<Another form of the above embodiment>
It should be noted that the present invention is not limited to the description of the above-described embodiment, and various modifications and improvements can be made without departing from the spirit of the present invention. For example, you may change as follows. By the way, the configuration of the following another mode may be applied individually or in combination with the configuration of the above embodiment.

(1) In the meter display effect, the sphere display effect, the cloud display effect, and the aura display effect, the method of applying the texture to the projection data of the object is to apply the texture to the projection data obtained by projecting the object on the screen area PC12. It is not limited to the method applied. For example, after applying the texture to the object, the object may be projected onto the screen area PC12.

In the meter display effect, the texture 281 for a meter is projected in parallel onto the parallel projection area 262, so that the dot information on the surface of the meter object 261 existing in the parallel projection area 262 shows the color information of the projected texture 281 for the meter. And set transparency information. After that, by projecting the meter object 261 onto the screen area PC12, the color information and the transparency information of the meter texture 281 are set in each dot of the meter projection area 251.

In the sphere display effect, the sphere display texture 342 is applied to the simplified version object 321 arranged in the world coordinate system by UV mapping. After that, by projecting the simplified version object 321 onto the screen area PC12, projection data of the simplified version object 321 to which the sphere display texture 342 is applied is created.

In the cloud display effect, the cloud display texture 362 is applied to the cloud display object 361 arranged in the world coordinate system by UV mapping. After that, by projecting the cloud display object 361 onto the screen area PC12, the cloud display two-dimensional data 363, which is the projection data 352 of the cloud display object 361 to which the cloud display texture 362 is applied, is created.

In the aura display effect, the partial texture is applied to the character object arranged in the world coordinate system by UV mapping. After that, by projecting the character object onto the screen area PC12, projection data of the character object to which the partial texture is applied is created.

(2) Another type of pachinko machine different from the above embodiment, such as a pachinko machine in which the electric accessory opens 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 the special device. The present invention can also be applied to a pachinko machine that generates a right when entering and a big hit, a pachinko machine provided with another accessory, an arrangement ball machine, a game machine such as a sparrow ball.

In addition, a game machine that is not a ball-ball type, for example, is equipped with a plurality of reels as a plurality of revolving bodies provided with a plurality of types of symbols in the circumferential direction, starts the rotation of the reel by inserting a medal and operating the start lever, and stops. After the reel is stopped by operating the switch, a slot that gives the player benefits such as payout of medals if a specific symbol or combination of specific symbols is established on the effective line visible from the display window The present invention can be applied to a machine. In this case, the present invention can be applied to various controls of the slot machine, and in a configuration including a display device such as a liquid crystal display device in addition to the reels, the present invention can be applied to control related to image display in the display control device. Can be applied.

In addition, a pachinko machine and a slot machine that include a take-in device and start the rotation of a reel by operating a start lever after a predetermined number of game balls stored in a storage section have been taken in by the take-in device. The present invention can be applied to a gaming machine in which

<Regarding Invention Groups Extracted from the Above Embodiments>
The features of the invention group extracted from the above-described embodiments will be described below, showing effects and the like as necessary. Note that, in the following, for ease of understanding, the configuration corresponding to the above embodiment is appropriately shown in parentheses or the like, but the present invention is not limited to the specific configuration shown in brackets or the like.

<Feature A group>
Features A1. Arrangement means for arranging the image data of the object, which is three-dimensional information, in the virtual three-dimensional space (function for executing the processing of steps S702 to S704 in the VDP 135), and viewpoint setting means for setting the viewpoint in the virtual three-dimensional space. (A function of executing the process of step S705 in the VDP 135), projecting the image data of the object on a projection plane (screen area PC12) set based on the viewpoint, and based on the data projected on the projection plane. Generated by a data generation unit (display CPU 131, geometry calculation unit 151, rendering unit 152) having a drawing setting unit (a function of executing the processing of steps S709 to S711 in the VDP 135) that generates generation data (drawing data). Storage means (frame buffer 142) for storing the generated generated data,
Display control means (display circuit 155 of VDP135) for outputting and displaying an image corresponding to the generated data stored in the storage means on the display means (symbol display device 31),
In a gaming machine equipped with
The arranging means is
Scale changing means (step S1009 in VDP135 for changing the scale of the predetermined object data (meter object 261) for displaying the predetermined individual images (meters 241a to 241e, 242) (reduction ratio of the meter object 261 in the longitudinal direction). Function that executes the process of
A predetermined arrangement means for arranging the predetermined object data in the virtual three-dimensional space (a function for executing the process of step S1010 in the VDP 135);
A specific arrangement means for arranging the specific object data (frame object 231 and blank object 291) in the virtual three-dimensional space (a function of executing the process of step S1105 in the VDP 135, a function of executing the process of step S1111 in the VDP 135);
Equipped with
The drawing setting unit executes the process of step S1212 in the VDP 135 that enables the display of the predetermined individual image by using the predetermined texture data (meter texture 281) corresponding to the predetermined object data. Function)
The texture utilization means is
First reference data in the predetermined object data (side C on the fixed end side of the meter object 261 that generates the reference data 263 and 298 on the fixed end side) and second reference data (on the moving end side in the specific object data) A defined range (for parallel projection) defined using a plurality of reference data including a side B on the moving end side of the frame object 231 for generating the reference data 264 and a blank object 291 for generating the reference data 292 on the moving end side. An application range setting unit that defines an area) as an application range of the predetermined texture data (function to execute the processes of steps S1208, S1209, and S1211 in the VDP 135);
Of the predetermined texture data in which the specified range is the applicable range, the display target setting is such that the data of a portion corresponding to the predetermined range (meter projection area 251) defined by the predetermined object data is the display target. Means (function of executing the process of step S1212 in the VDP 135),
A gaming machine characterized by being equipped with.

According to the characteristic A1, the specified range, which is the applicable range of the predetermined texture data, is specified by a plurality of reference data including the first reference data and the second reference data. On the other hand, the display target range of the predetermined texture data is determined according to the predetermined range defined by the predetermined object data. Therefore, the range to be displayed in the predetermined texture data can be changed without changing the application range of the predetermined texture data.

On the other hand, in the configuration in which the correspondence between the predetermined object data and the predetermined texture data is constant, and the scale of the predetermined object data is changed, the application range of the predetermined texture data and the display target range are changed. In order to change only the display target range of the predetermined object data without changing the application range of, the process of changing the correspondence between the predetermined object data and the predetermined texture data is performed in addition to the process of changing the scale of the predetermined object data. Need to do.

Therefore, the application range of the predetermined texture data is defined by a plurality of reference data including the first reference data of the predetermined object data and the second reference data of the specific object data. It is possible to reduce the processing load for changing the range to be displayed in the predetermined texture data while keeping the constant.

Feature A2. The scale changing means changes the scale of the predetermined object data in a predetermined direction,
The first reference data is the reference data for defining one end (fixed end side) in the predetermined direction in the specified range,
The gaming machine according to Feature A1, wherein the second reference data is the reference data for defining the other end (moving end side) in the predetermined direction in the specified range.

According to the characteristic A2, the length in the direction in which the scale of the predetermined object data changes in the application range of the predetermined texture data is determined by the positional relationship between the first reference data and the second reference data in the virtual three-dimensional space. Since the positional relationship between the first reference data and the second reference data can be changed without being affected by the change mode of the scale of the predetermined object data, the positions of the first reference data and the second reference data can be changed. By keeping the relationship constant and changing the scale of the predetermined object data in a constant direction, it is possible to change the display target range of the predetermined texture data while keeping the application range of the predetermined texture data constant.

Features A3. When the scale changing unit sets the scale of the predetermined object data to a predetermined scale (the same 100% magnification as in the initial state), the specific arrangement unit is one end of the predetermined direction in the predetermined object data. Then, the specific object data is arranged in the virtual three-dimensional space in such a manner that one end on the side opposite to the first reference data (side D on the moving end side of the meter object 261) matches the second reference data. The gaming machine described in the feature A2.

According to the characteristic A3, when the scale of the predetermined object data is set to the predetermined scale, one end of the predetermined object data in a fixed direction, one end opposite to the first reference data and the second reference data are In addition to the matching, the length of the predetermined object data in the fixed direction and the length of the predetermined texture data in the fixed direction in the fixed range match. Therefore, it is possible to perform an effect including the timing when the entire application range of the predetermined texture data becomes the display target range.

Features A4. Features A1 to A3 characterized in that the specific arranging means arranges the specific object data in the virtual three-dimensional space in such a manner that the positional relationship between the first reference data and the second reference data is constant. The gaming machine according to any one of 1.

According to the characteristic A4, the configuration in which the positional relationship between the first reference data and the second reference data is kept constant allows the display range of the predetermined texture data to be predetermined while keeping the application range of the predetermined texture data constant. It can be changed according to the scale of the object data.

Features A5. The specific object data is object data (frame object 231) for displaying a frame image (frames 231a to 231e) of the predetermined individual image, according to any one of features A1 to A4. Amusement machine.

According to the characteristic A5, since the image data of the object for defining the application range of the predetermined texture data is the same as the image data of the object for displaying the frame image, the application range of the predetermined texture data is defined. By arranging the image data of the object for doing so, it is possible to avoid the situation where the display content of the predetermined individual image is changed. In addition, in comparison with the case where the image data of the object for defining the application range of the predetermined texture data and the image data of the object for displaying the frame image are individually stored, the data capacity stored in advance Can be reduced.

Features A6. The gaming machine according to any one of features A1 to A4, wherein the specific object data is not a display target but object data (blank object 291) arranged to define the specified range.

According to the characteristic A6, the projection range of the predetermined texture data can be defined by arranging the second specific object data which is not the display target. Since the second specific object data is not the display target, the content of the predetermined individual image is not changed by arranging the second specific object data. Therefore, the applicable range of the predetermined texture data can be defined regardless of the content of the display image.

Features A7. The gaming machine according to Feature A6, wherein the specific object data is one-dimensional object data.

According to the characteristic A7, by suppressing the data capacity of the second specific object data for defining the application range of the predetermined texture data to the minimum, an increase in the data capacity to be stored in advance is suppressed and the second specific object data is stored. The processing load for arranging in the virtual three-dimensional space can be reduced.

Feature A8. As the predetermined individual image, the predetermined arrangement unit includes a first predetermined individual image (for example, a meter 241a located below the first character 221) and a second predetermined individual image (for example, a second predetermined individual image different from the first predetermined individual image). In order to display the meter 242a) located below the two characters 222, by accessing twice the address of the one predetermined object data stored in the data storage means (memory module 133), the virtual 3 Arranging the two predetermined object data at different positions in the dimensional space,
The scale changing unit includes the scale of the predetermined object data arranged to display the first predetermined individual image and the scale of the predetermined object data arranged to display the second predetermined individual image. And are different,
The texture utilization means accesses the address of one predetermined texture data stored in the data storage means twice in order to display the first predetermined individual image and the second predetermined individual image. The gaming machine according to any one of features A1 to A7, wherein the predetermined texture data is applied to two predetermined object data arranged at different positions in the virtual three-dimensional space.

According to the characteristic A8, a plurality of different individual images can be displayed by using one predetermined object data and one predetermined texture data stored in the data storage means. Since it is possible to minimize the number of object image data and the number of texture data required to display a plurality of different individual images, it is possible to suppress an increase in the amount of data stored in advance.

Features A9. The gaming machine according to any one of features A1 to A8, wherein the predetermined texture data is image data of a pattern that changes along a direction in which the scale of the predetermined object data is changed.

According to the characteristic A9, the range of the display target of the predetermined texture data is changed by changing the scale of the predetermined object data, and the predetermined individual image whose pattern changes according to the scale of the predetermined object data is used. Can be displayed. The player can easily understand that the range of the display target of the predetermined texture data has changed.

It should be noted that any one or a plurality of configurations of the features A1 to A9, the features B1 to B5, the features C1 to C10, and the features D1 to D8 may be applied to the configuration of any one of the features A1 to A9. .. Thereby, it becomes possible to exert a synergistic effect by the combined configuration.

The invention of the characteristic group A can solve the following problems.

As a kind of gaming machine, a pachinko gaming machine, a slot machine, etc. are known. As these game machines, those provided with a display device such as a liquid crystal display device are known. The game machine is equipped with a memory in which image data is stored in advance, and a predetermined image is displayed on the display unit of the display device by using the image data read from the memory. Becomes

In recent years, an attempt has been made to display a more stereoscopic image by using image data defined in three dimensions instead of simply displaying a two-dimensional image. When performing the display, an object that is three-dimensional image data is set in the virtual three-dimensional space, and generated data is generated by projecting the object on a plane from a desired viewpoint. Then, a signal is output to the display device based on the generated data, so that a stereoscopic image is displayed.

Here, in the gaming machine as illustrated above, a configuration capable of suitably performing display control is required, and there is still room for improvement in this respect.

<Feature B group>
Feature B1. Arrangement means for arranging the image data of the object, which is three-dimensional information, in the virtual three-dimensional space (function for executing the processing of steps S702 to S704 in the VDP 135), and viewpoint setting means for setting the viewpoint in the virtual three-dimensional space. (A function of executing the process of step S705 in the VDP 135), projecting image data of the object on a projection plane (screen area PC12) set based on the viewpoint, and based on the projection data projected on the projection plane. And a data setting unit (display CPU 131, geometry calculation unit 151, rendering unit 152) having a drawing setting unit (a function of executing the processes of steps S709 to S711 in the VDP 135) that generates generated data (drawing data) by Storage means (frame buffer 142) for storing the generated generated data,
Display control means (display circuit 155 of VDP135) for outputting and displaying an image corresponding to the generated data stored in the storage means on the display means (symbol display device 31),
In a gaming machine equipped with
The arranging means is
A means for arranging a partial corresponding object (simplified object 321) in which the projection target surface that is a part of the surface is a projection target and the non-projection target surface that is a part of the surface is not the projection target (in VDP135) A function of executing the process of step S1403),
Means for setting the angle of the partial corresponding object so that the projection target surface is the projection target and the non-projection target surface is not the projection target (the processing of step S1303, step S1306, step S1312 and step S1316 in the display CPU 131 is executed. Function) and
Equipped with
The drawing setting means uses the corresponding texture data (sphere display texture 342) corresponding to the projection target surface to enable display of an image corresponding to the projection target surface (step in VDP135). Function for executing the process of S1506),
The correspondence utilizing means changes the range applied to the projection target surface in the corresponding texture data in accordance with the angle of the partially corresponding object in the virtual three-dimensional space (range of step S1504 and step S1505 in VDP135). A game machine characterized by having a function of executing processing.

According to the feature B1, in the configuration in which the angle of the partial corresponding object is set so that the projection target surface becomes the projection target and the non-projection target surface does not become the projection target, it is applied to the projection target surface according to the angle of the partial corresponding object. With the configuration in which the range of the corresponding texture data is changed, a plurality of images having different contents displayed at different timings are three-dimensional objects having a structure displayed by using partially corresponding objects as a part of the structure. It is possible to give the player an impression that the image is viewed from a plurality of angles.

Compared with the case of using an object for displaying the entire three-dimensional object to be displayed, an increase in the amount of data stored in advance for displaying the three-dimensional object is suppressed, and the object to be displayed becomes three. It is possible to reduce the processing load for displaying a three-dimensional object.

Feature B2. The game machine according to feature B1, wherein the partial corresponding object has a structure for displaying a spherical surface as the projection target surface.

According to the feature B2, it is possible to display a spherical surface in all images when a three-dimensional object to be displayed is viewed from a plurality of angles. Therefore, it is possible to display a spherical surface wider than the spherical surface corresponding to the structure for displaying the spherical surface of the projection target surface while suppressing an increase in the amount of data stored in advance and reducing the processing load.

Feature B3. In the partial corresponding object, when the projection data includes a projection area in which the partial corresponding object is projected, in the partial corresponding object, a position that causes an outer edge of the projection area is The gaming machine according to feature B1 or B2, which has more vertices than a portion that causes an inner portion of the projection region.

According to the feature B3, in the configuration in which the partial corresponding object is arranged at an angle at which the projection target surface is the projection target, the number of vertices of the portion that causes the inner portion of the projection area of the partial corresponding object is determined as the outer edge of the projection area of the partial corresponding object. By making the number of vertices smaller than the number of vertices in the projection area of the partially corresponding object, the number of vertices in the area corresponding to the inner portion of the projection area of the partially corresponding object is equal to or greater than that Compared with the case described above, it is possible to suppress an increase in the amount of data stored in advance for using the partial corresponding object and reduce the processing load for using the partial corresponding object.

Feature B4. Features B1 to B3 characterized in that the range changing unit changes the range applied to the projection target surface in the corresponding texture data every time the angle of the partial corresponding object set by the arranging unit changes. The gaming machine according to any one of 1.

According to the feature B4, in the configuration in which the angle of the partial corresponding object is set such that the projection target surface of the partial corresponding object becomes the projection target, the corresponding texture applied to the projection target surface every time the angle of the partial corresponding object changes. By changing the range of the data, it is possible to give the player the impression that the display range of the three-dimensional object to be displayed is changed at the timing when the angle of the partially corresponding object is changed.

Feature B5. The gaming machine according to any one of features B1 to B4, wherein the arranging unit sets an angle of the partial corresponding object such that an angle of the partial corresponding object with respect to the viewpoint is always constant.

According to the feature B5, since the partial corresponding object is always projected from the one direction onto the projection plane, it is possible to use the partial corresponding object corresponding to the projection from only one direction. The data capacity of the partial corresponding object can be reduced as compared with the case of using the partial corresponding object corresponding to projection from multiple directions.

It should be noted that any one or a plurality of configurations of the features A1 to A9, the features B1 to B5, the features C1 to C10, and the features D1 to D8 may be applied to the configuration of any one of the features B1 to B5. .. Thereby, it becomes possible to exert a synergistic effect by the combined configuration.

The invention of the characteristic group B can solve the following problems.

As a kind of gaming machine, a pachinko gaming machine, a slot machine, etc. are known. As these game machines, those provided with a display device such as a liquid crystal display device are known. The game machine is equipped with a memory in which image data is stored in advance, and a predetermined image is displayed on the display unit of the display device by using the image data read from the memory. Becomes

In recent years, an attempt has been made to display a more stereoscopic image by using image data defined in three dimensions instead of simply displaying a two-dimensional image. When performing the display, an object that is three-dimensional image data is set in the virtual three-dimensional space, and generated data is generated by projecting the object on a plane from a desired viewpoint. Then, a signal is output to the display device based on the generated data, so that a stereoscopic image is displayed.

Here, in the gaming machine as illustrated above, a configuration capable of suitably performing display control is required, and there is still room for improvement in this respect.

<Characteristic C group>
Feature C1. Storage means (frame buffer 142) for storing the generated data (drawing data) generated by the data generation means (display CPU 131, geometry calculation part 151, rendering part 152) based on the image data;
Display control means (display circuit 155 of VDP135) for outputting and displaying an image corresponding to the generated data stored in the storage means on display means (display surface G of the pattern display device 31),
In a gaming machine equipped with
The data generating means,
The first corresponding data (projection data 352 of the cloud display object 361, aura head projection data 382b) that enables the image of the specific shape to be displayed in the first size, and the image of the specific shape more than the first size. Use setting means (steps S1901 to S1906 in the VDP 135) for setting each of the second correspondence data (projection data 351 of the clipping object 364 and head projection data 372b) that can be displayed in the second small size into a usable state. Function for executing the processing of step S2001 to step S2006 in the VDP 135),
Center of the image of the specific shape of the first size and the image of the specific shape of the second size (center corresponding point 352c of the cloud display object 361, center corresponding point 351c of the clipping object 364, head aura When the positional relationship between the first corresponding data and the second corresponding data is adjusted so that the center corresponding point 382f of the object 382a and the center corresponding point 372f of the head object 372a) match, the first size of the In the image of the specific shape, a portion (frame area 353a, head aura area 392) protruding outside the image of the specific size of the second size is a display target image (blurred frame area 367a, aura 412) in the first corresponding data. To 417), in the data group that enables the display of the image of the specific shape in the first corresponding data, the data group that enables the display of the image of the specific shape in the second corresponding data. Non-display means for setting a corresponding portion (a portion corresponding to the clipping projection area 351a in the two-dimensional data for cloud display and a portion corresponding to the head projection area 372c in the aura head projection data 382b) as a non-display target (A function of executing the processing of steps S2103 to S2106 in the VDP 135),
A gaming machine characterized by being equipped with.

According to the characteristic C1, by using the first correspondence data and the second correspondence data, in addition to the image of the specific shape of the first size and the image of the specific shape of the second size, the image of the specific shape of the first size In, it is possible to display an image of only the outer frame portion of the image. In addition to the first correspondence data and the second correspondence data, in comparison with a configuration in which data capable of displaying only an image of a frame portion of an outer edge of the image of a specific shape of the first size is stored in advance, It is possible to suppress an increase in the amount of data stored in advance.

Feature C2. The use setting means separates the first correspondence data and the second correspondence data from different image data (cloud display object 361, clipping object 364, head object 372a, head aura object 382a). The gaming machine described in the feature C1 which is generated.

According to the characteristic C2, the data for generating the first corresponding data is different from the data for generating the second corresponding data. Therefore, each corresponding data can be generated based on the data suitable for generating each corresponding data, and the processing load for generating each corresponding data can be reduced.

Feature C3. The data generating means,
A means (in the VDP 135) for arranging the first corresponding object (cloud display object 361, head aura object 382a), which is three-dimensional information, as the image data for generating the first corresponding data. A function of executing the process of step S1903),
As the image data for generating the second corresponding data, a second corresponding object (cutout object 364) having the same shape as the first corresponding object and being three-dimensional information having a smaller size than the first corresponding object. , The head object 372a) so that the coordinates and angles of the second corresponding object in the virtual three-dimensional space are the same as the coordinates and angles of the first corresponding object in the virtual three-dimensional space. Means for arranging in the dimensional space (a function for executing the processing of steps S2002 and S2003 in the VDP 135),
Viewpoint setting means for setting a viewpoint in the virtual three-dimensional space (a function for executing the processing of step S705 in the VDP 135);
Means for projecting the first corresponding object onto the projection plane (screen area PC12) set based on the viewpoint to generate the first corresponding data (a function for executing the process of step S1904 in the VDP 135);
Means for projecting the second corresponding object onto the projection plane to generate the second corresponding data (a function for executing the process of step S2004 in the VDP 135);
A gaming machine according to feature C2, which is provided with.

According to the characteristic C3, since the second corresponding object has the same shape as the first corresponding object and has a smaller size than the first corresponding object, the coordinates for arranging the first corresponding object in the virtual three-dimensional space and The same value can be used for each of the angle and the coordinate and the angle for arranging the second corresponding object in the virtual three-dimensional space. Further, the first corresponding data and the second corresponding data are generated by setting the size of the first corresponding object to the size corresponding to the first size and the size of the second corresponding object to the size corresponding to the second size. It is possible to reduce the processing load for doing so.

Feature C4. In the feature C1, the use setting unit generates each of the first correspondence data and the second correspondence data from the same image data (for example, the cloud display object 361, for example, the head object 372a). The game machine described.

According to the characteristic C4, since the same image data is used, it is possible to suppress an increase in the data capacity stored in advance for generating the first corresponding data and the second corresponding data.

Feature C5. The non-display means corresponds to a data group capable of displaying the image of the specific shape in the second corresponding data among the data group capable of displaying the image of the specific shape in the first corresponding data. Frame image data (frame display two-dimensional data 353, head aura two-dimensional) that enables display of a frame image of an outer edge in the image of the specific shape of the first size by making the portion to be displayed non-displayed. A frame image generation unit (function of executing the processes of steps S2103 to S2106 in the VDP 135) for generating the data 392a) is provided,
The data generation unit changes the content of the first correspondence data based on the frame image data, so that the image of the specific shape of the first size displayed by the first correspondence data and the frame are displayed. The frame image of the outer edge displayed by the image data and the frame image of the outer edge overlap in the depth direction in a manner that the frame image of the outer edge is on the front side, and the frame image of the outer edge is the outer edge of the image of the specific shape of the first size Outer edge portion changing means for generating change data (cloud drawing data 368, aura character drawing data 421a) capable of displaying an image displayed on the part (function of executing the processing of steps S1810 to S1812 in the VDP 135) The gaming machine according to any one of the features C1 to C4, which is characterized by comprising:

According to the characteristic C5, since the frame image of the outer edge displayed by the frame image data is displayed on the outer edge portion of the image of the specific shape displayed by the first correspondence data, the outer edge of the image of the specific shape is displayed. It is possible to change only the content of the outer edge portion without changing the content inside the portion. Since the frame image data is generated using the first correspondence data, it is possible to change the content of the outer edge portion in the image of the specific shape while suppressing an increase in the data capacity to be stored in advance.

Feature C6. The outer edge portion changing unit performs, on the frame image data, blurring processing (processing of steps S1805 to S1809 in the VDP 135) for blurring the frame image of the outer edge that can be displayed by the frame image data. After that, the contents of the first corresponding data are changed based on the frame image data after the blurring processing, the gaming machine according to the feature C5.

According to the characteristic C6, in the image of the specific shape, only the image of the outer edge portion can be changed to the blurred image without changing the content inside the outer edge portion. Since the configuration is such that the frame image data is generated using the first correspondence data and the blurring process is executed on the frame image data, it is possible to suppress the increase in the amount of data to be stored in advance and reduce the amount of data stored in the specific shape image. The image of the outer edge can be blurred.

Feature C7. The image of the specific shape is an image of a first portion that is a part of the image of the specific shape (for example, an image of the body 375 of the character 371) and a portion of the image of the specific shape, and the first portion of the image. And an image of a second portion (for example, an image of the right arm portion 373 of the character 371) that has an overlapping area overlapping the image of the first portion and is located on the front side of the image of the first portion,
The use setting means allows the first correspondence image of the first portion to display the image of the first portion in the first size and the second correspondence data to display the image of the second portion in the first size. The first correspondence data of the part, and the usable state,
In the frame image generation means, in the frame image data of the first portion that can display the frame image of the outer edge in the image of the first portion of the first size, and in the image of the second portion of the first size. And a frame image data of a second portion that can display the frame image of the outer edge,
The outer edge portion changing means is configured such that the outer edge frame image displayed by the frame image data of the first portion is an image in which the outer edge portion of the image of the first portion is set in front of the outer edge portion. The change data of the first part (two-dimensional data for body part with aura 415a) that allows the change image to be displayed and the frame image of the outer edge displayed by the frame image data of the second part are the second part of the second part. Change data of the second part (aura-equipped right-arm two-dimensional data 413a) capable of displaying a changed image of the second part, which is the image set on the front side of the outer edge part in the image, and
In the data generation unit, the modified image of the first portion and the modified image of the second portion have the overlapping area, and the modified image of the second portion is on the front side of the modified image of the first portion. In such a manner, by combining the change data of the first part and the change data of the second part, the contents of the outer edge part of the overlapping area in the image of the first part and the image of the second part in the image of the second part are combined. The game machine according to feature C5 or C6, wherein the content of the outer edge portion of the overlapping area and combined data (aura character drawing data 421a) are changed.

According to the characteristic C7, the change data of the first part and the change data of the second part are individually generated and combined. When the data for displaying the image in which the content of the outer edge portion is changed is generated in the state where the image of the first portion and the image of the second portion are overlapped, the content of the outer edge portion of the overlapping area is not changed. On the other hand, the change data of the first part in which the content of the outer edge part of the first part is changed and the change data of the second part in which the content of the outer edge part of the second part is changed are individually generated. By synthesizing with each other, it is possible to display an image of a specific shape in which the content of the outer edge portion of the overlapping area is also changed.

Feature C8. The frame image generation means is capable of displaying the image of the specific shape in the first corresponding data after setting single color information in the area corresponding to the image of the specific shape in the first corresponding data. In the image of the specific shape of the first size, by making a portion of the data group corresponding to the data group capable of displaying the image of the specific shape in the second corresponding data non-display target, The gaming machine according to any one of features C5 to C7, wherein the frame image data capable of displaying the frame image of the outer edge in which the single color information is set is generated.

According to the characteristic C8, the first correspondence data is used to generate the frame image data capable of displaying the frame image of the outer edge of the single color, thereby suppressing the increase in the amount of data to be stored in advance and controlling the specific shape. The outer edge portion of the image can be changed to a single color.

Feature C9. The data generating means,
Saving means for saving the change data generated by the outer edge portion changing means (a function of executing the process of step S1813 in the VDP 135, a function of executing the process of step S2812 in the VDP 135),
The amusement machine according to any one of features C5 to C8, wherein the change data stored in the storage unit is used without newly generating the change data.

According to feature C9, when usable change data is saved, the saved change data is used without generating new change data, so that the change data is not saved. Thus, the processing load for using the changed data can be reduced.

Feature C10. The use setting means,
A means for arranging the image data of the object (cloud display object 361, clipping object 364, head aura object 382a, head object 372a), which is three-dimensional information, in the virtual three-dimensional space (in step S1903 in the VDP 135). A function of executing the process, a function of executing the process of step S2003 in the VDP 135),
Viewpoint setting means for setting a viewpoint (viewpoint PC 11) in the virtual three-dimensional space (a function for executing the processing of step S705 in the VDP 135);
Image data of the object is projected on a projection plane (screen area PC12) set based on the viewpoint, and each of the first correspondence data and the second correspondence data is based on the data projected on the projection plane. Means for generating (the function of executing the process of step S1904 in the VDP 135, the function of executing the process of step S2004 in the VDP 135),
The gaming machine according to any one of the features C5 to C9, which is characterized by comprising:

According to the characteristic C10, the first correspondence data and the second correspondence data are generated based on the data in which the image data of the object is projected on the projection plane, and the first correspondence data and the second correspondence data are used to identify the object. In the image of the shape, since the image in which the content of the frame portion of the outer edge is changed is displayed, as compared with the structure in which the frame image data matching the shape of the frame portion of the outer edge at each timing is stored in advance. It is possible to suppress an increase in the amount of data stored in advance.

Note that any one or more of the features A1 to A9, the features B1 to B5, the features C1 to C10, and the features D1 to D8 may be applied to the configuration of any one of the features C1 to C10. .. Thereby, it becomes possible to exert a synergistic effect by the combined configuration.

The invention of the characteristic group C can solve the following problems.

As a kind of gaming machine, a pachinko gaming machine, a slot machine, etc. are known. As these game machines, those provided with a display device such as a liquid crystal display device are known. The game machine is equipped with a memory in which image data is stored in advance, and a predetermined image is displayed on the display unit of the display device by using the image data read from the memory. Becomes

In recent years, an attempt has been made to display a more stereoscopic image by using image data defined in three dimensions instead of simply displaying a two-dimensional image. When performing the display, an object that is three-dimensional image data is set in the virtual three-dimensional space, and generated data is generated by projecting the object on a plane from a desired viewpoint. Then, a signal is output to the display device based on the generated data, so that a stereoscopic image is displayed.

Here, in the gaming machine as illustrated above, a configuration capable of suitably performing display control is required, and there is still room for improvement in this respect.

<Feature D group>
Feature D1. A storage unit (frame buffer 642) for storing the generated data (drawing data) generated by the data generation unit (the control unit 651 of the VDP 635) based on the image data;
Display control means (display circuit 655 of VDP 635) for outputting and displaying an image corresponding to the generated data stored in the storage means on display means (display surface G of the symbol display device 31),
In a gaming machine equipped with
The data generating means,
By setting the color information to be applied to the predetermined individual image data (character sprite data 451) for displaying the predetermined individual image (character 491) to the special information (the color information of the outline 492, the color information of the blurring outline 493). A specific generation unit (a function of executing steps S3402 to S3404 in the VDP 635) that generates specific individual image data (sprite data 451 for a single-color character);
Part of the specific individual image (outline display area 454) corresponding to the specific individual image data overlaps on the back side with respect to the predetermined individual image, and part of the specific individual image exists outside the predetermined individual image. So as to set the specific individual image data and the predetermined individual image data (a function of executing the process of step S3309 in the VDP 635, a function of executing the process of step S3406 in the VDP 635),
A gaming machine characterized by being equipped with.

According to the feature D1, since the specific individual image data and the specific individual image data are set in a mode in which a part of the specific individual image exists outside the predetermined individual image, the specific individual image and the specific individual image are displayed. The image is partly different from the image displayed only by the predetermined individual image. Since the specific individual image data is data generated by using the predetermined individual image data, each of the image displayed by only the predetermined individual image and the image displayed by the predetermined individual image and the specific individual image is displayed. The image data necessary for this is one type of predetermined individual image data. Compared with a configuration in which a plurality of types of predetermined individual image data are stored in advance in order to display a plurality of different types of predetermined individual images, the increase of the capacity of the image data memory is suppressed while the predetermined individual image data is displayed. The display mode can be changed.

Feature D2. Characteristic D1 characterized in that the predetermined setting means shifts the specific individual image data to a plurality of positions so that the periphery of the predetermined individual image is surrounded by the image portion (outline 492) of the specific individual image. Gaming machine described in.

According to the feature D2, the specific individual image data generated by using the predetermined individual image data is set at a plurality of positions so as to be set, so that the image portion of the specific individual image is suppressed while suppressing the increase in the capacity of the image data memory. This makes it possible to surround the entire outer edge of the predetermined individual image.

Feature D3. In the specific individual image that is displayed outside the predetermined individual image, the predetermined setting means sets the specific individual image data so that the thickness of the image region that extends outside the predetermined individual image is constant or substantially constant. The gaming machine described in the feature D2, wherein

According to the feature D3, the specific individual image has an image region that extends beyond the outer edge of the predetermined individual image, and the image region exists outside the entire outer edge of the predetermined individual image in a form having a constant or substantially constant thickness. Therefore, the specific individual image can be used to display the outline on the entire outer edge of the predetermined individual image. Compared to a configuration in which image data for displaying a predetermined individual image including an outline is stored in advance separately from the predetermined individual image, the increase in the capacity of the image data memory is suppressed and the surroundings of the predetermined individual image are suppressed. The outline can be displayed.

Feature D4. The specific generation means generates the specific individual image data (single color character sprite data 451) of a single color by setting single color information in the predetermined individual image data as the specific information. The gaming machine according to any one of the features D1 to D3.

According to the feature D4, it is possible to display the specific individual image having the same shape as the predetermined individual image and having a single color outside a part or all of the outer edge of the predetermined individual image. In comparison with a configuration in which individual image data for displaying a predetermined individual image having a single color area outside a part or all of the outer edge is stored separately from the predetermined individual image, the image data memory It is possible to suppress an increase in capacity.

Feature D5. The data generation unit includes an image blurring unit (a function of executing the processes of steps S3410 and S3411 in the VDP 635) that performs an image blurring process for blurring the content of the specific individual image on the specific individual image data. ,
When the predetermined individual image data and the predetermined individual image data are set, the predetermined setting unit sets the specific individual image data that has been subjected to the image blurring process as the specific individual image data. The gaming machine according to any one of features D1 to D4.

According to the feature D5, by setting the specific individual image and the specific individual image subjected to the image blurring process, the specific individual image and the specific individual image in which only the specific individual image is blurred can be displayed. Since the predetermined individual image and the blurred specific individual image are displayed using one type of predetermined individual image data, image data for displaying the predetermined individual image and the blurred specific individual image separately from the predetermined individual image It is possible to suppress an increase in the capacity of the image data memory, as compared with the configuration in which is stored.

Feature D6. The image blurring unit enlarges the specific individual image with respect to the specific individual image data (processing of step S3411 in VDP 635) and reduces the specific individual image (processing of step S3410 in VDP 635). The game machine according to Feature D5, wherein the image blurring process is performed by performing one of the two and then performing the other.

According to the characteristic D6, since the image blurring process is configured by the enlargement process and the reduction process, it is not necessary to add a dedicated program for blurring the specific individual image. Therefore, it is possible to execute the image blurring process on the specific individual image data while suppressing an increase in the data capacity of the program stored in advance.

Feature D7. The image blurring means performs the image blurring process on the specific individual image data in a manner that the size of the specific individual image after the image blurring process becomes the same as the size of the specific individual image before the image blurring process. The gaming machine according to feature D6, characterized in that

According to the characteristic D7, since the size of the specific individual image displayed by the specific individual image data does not change before and after the image blurring process, the specific individual image has the same size as the predetermined individual image outside the predetermined individual image, and the image blurring process is performed. The executed specific individual image can be displayed. The size of the specific individual image changes before and after the image blur processing, and the size of the specific individual image after the image blur processing becomes the size of the specific individual image before the image blur processing for the specific individual image data after the image blur processing. It is possible to reduce the processing load for using the specific individual image data that has been subjected to the image blurring processing, as compared with the configuration that executes the processing for returning.

Feature D8. A storage unit (frame buffer 642) for storing the generated data (drawing data) generated by the data generation unit (the control unit 651 of the VDP 635) based on the image data;
Display control means (display circuit 655 of VDP 635) for outputting and displaying an image corresponding to the generated data stored in the storage means on display means (display surface G of the symbol display device 31),
In a gaming machine equipped with
The data generation unit enlarges the specific individual image with respect to the specific individual image data (sprite data 451 for single color character) for displaying the specific individual image (outline display area 454) (VDP635). In step S3411) and reduction processing for reducing the specific individual image (processing in step S3410 in VDP635) and then the other, thereby blurring the specific individual image. Characteristic gaming machine.

According to the characteristic D8, since the specific individual image data is configured to generate the blurred specific individual image data by performing the enlarging process and the reducing process, the specific individual image data is displayed separately from the specific individual image data. It is possible to suppress an increase in the capacity of the image data memory, as compared with a configuration in which image data for performing the above is stored in advance.

Further, since the processing performed on the specific individual image data for blurring the specific individual image is configured by the enlargement processing and the reduction processing, it is not necessary to add a dedicated program for blurring the specific individual image. Therefore, it is possible to display the blurred specific individual image while suppressing an increase in the data capacity of the program stored in advance.

It should be noted that any one or more of the features A1 to A9, the features B1 to B5, the features C1 to C10, and the features D1 to D8 may be applied to the configuration of any one of the features D1 to D8. .. Thereby, it becomes possible to exert a synergistic effect by the combined configuration.

The invention of the characteristic group D can solve the following problems.

As a kind of gaming machine, a slot machine, a pachinko gaming machine, etc. are known. These gaming machines include a control board on which an element such as a memory in which a control program for a game is stored is mounted, and a series of games are controlled by the control board. It is also known that the CPU and the memory are not individually mounted on the control board, but are mounted on the control board in an integrated state.

In the above-mentioned gaming machine, there is known one provided with a display device having a display screen, such as a liquid crystal display device. In such a gaming machine, a memory for image data in which image data is stored in advance is mounted, and a predetermined image is displayed on the display screen by using the image data read from the memory.

Here, in the gaming machine as illustrated above, a configuration capable of suitably performing display control is required, and there is still room for improvement in this respect.

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

Pachinko gaming machine: operating means operated by a player, game ball launching means for launching a game ball based on the operation of the operating means, a ball passage for guiding the launched game ball to a predetermined game area, and a game A gaming machine that includes each game component arranged in the area and gives a bonus to a player when a game ball passes through a predetermined passage portion of each of the game components.

Rotating drum type game machines such as slot machines: The rotation of the revolving body is started based on the operation of the start operation means, the rotation of the revolving body is stopped based on the operation of the stop operation means, and the player is responsive to the design after the stop. A gaming machine that gives benefits to.

10... Pachinko machine, 31... Symbol display device, 131... Display CPU, 133... Memory module, 135... VDP, 142... Frame buffer, 151... Geometry calculation section, 152... Rendering section, 155... Display circuit, 221... First Character: 222... Second character, 231... Frame object, 231a to 231e... Frame, 241a to 241e, 242... Meter, 251... Meter projection area, 261... Meter object, 263... Meter object 261 fixed end Fixed-side reference data generated by side C on side 264... Moving-end reference data generated by side B on moving end of frame object 231, 281... Texture for meter, 291... Blank object, 292... Reference data on the moving end generated by the blank object 291, 298... Reference data on the fixed end generated by the side C on the fixed end side of the meter object 261, 321... Simplified version object, 342... Texture for displaying sphere, 351 ... Projection data of cutout object 364, 351a ... Cutout projection area, 351c ... Center corresponding point of cutout object 364, 352 ... Projection data of cloud display object 361, 352a ... Cloud display projection area, 352c ... Cloud display Corresponding point of the object 361, 353... 2D data for frame display, 353a... Frame area, 361... Object for cloud display, 364... Object for clipping, 367a... Blurred frame area, 368... Drawing data for cloud, 372... Character, 372a... Head object, 372b... Head projection data, 372c... Head projection area, 372f... Center corresponding point of head object 372a, 373... Right arm, 375... Torso, 382a... Head Aura object, 382b... Aura head projection data, 382f... Center corresponding point of head aura object 382a, 392... Head aura area, 392a... Head aura two-dimensional data, 412-417... Aura, 413a ... two-dimensional data for right arm part with aura, 415a... two-dimensional data for body part with aura, 421a... drawing data for character with aura, 451... sprite data for character, 454... outline display area, 491... character, 492... Outline, 493... Blur outline, 635... VDP, 642... Frame buffer, 651... Control unit, 655... Display circuit, D... Meter object 261 Of the moving end side of G, display screen, PC 12... screen area.

Claims (1)

Arrangement means for arranging image data of an object which is three-dimensional information in a virtual three-dimensional space, viewpoint setting means for setting a viewpoint in the virtual three-dimensional space, and the object on a projection plane set based on the viewpoint. And a storage unit that stores the generated data generated by the data generation unit that has a drawing setting unit that projects image data of the image data and that generates generated data based on the projection data projected on the projection plane.
Display control means for outputting and displaying an image corresponding to the generated data stored in the storage means on the display means;
In a gaming machine equipped with
The arranging means is
A means for arranging, in the virtual three-dimensional space, a partial corresponding object in which a projection target surface that is a part of a surface is a projection target and a non-projection target surface that is a part of a surface is not a projection target;
Means for setting an angle of the partial corresponding object so that the projection target surface is a projection target and the non-projection target surface is not a projection target;
Equipped with
The drawing setting means includes a corresponding use means that enables display of an image corresponding to the projection target surface by using corresponding texture data corresponding to the projection target surface,
The correspondence using means includes a range changing means for changing a range to be applied to the projection target surface in the corresponding texture data according to an angle of the partially corresponding object in the virtual three-dimensional space ,
The game machine , wherein the partial corresponding object has a structure for displaying the spherical surface as the projection target surface .

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