JP2012239819A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To display a three-dimensional image by the number of parallaxes corresponding to the preference of a player.SOLUTION: The game machine includes: three-dimensional image display devices 9, 1050 which have image display bodies 9a, 1051 where pixels P composed of a plurality of sub-pixels p1 to p9 for displaying a plurality of parallax images different in points of view constituting a three-dimensional image are repeatedly placed adjacently, and emission direction restricting elements 9b, 1057 for restricting emission directions of the respective parallax image light beams emitted from the respective sub-pixels to prescribed directions corresponding to the parallax images, and display a three-dimensional image comprising the parallax images; display control means 86, 213, 1091a, 1092 for controlling the display of the three-dimensional image display device; and parallax difference receiving means 86, 517, 1091a, 1058 for receiving, from a player, the number of parallaxes to be the different number of parallax images displayed at the sub-pixels included in the pixels. The display control means perform control so as to display the parallax images in the number of parallaxes received by the parallax number receiving means to the sub-pixels.

Description

  The present invention relates to a gaming machine capable of playing a predetermined game and capable of displaying a stereoscopic image related to the game.

  In a conventional gaming machine, as a method of displaying a stereoscopic image related to a game such as an effect, a parallax image is displayed on the front surface of an image display body in which pixels composed of a plurality of subpixels that display different parallax images are repeatedly arranged. In some cases, a so-called integral imaging method is employed in which an emission direction limiting element is provided that limits the emission direction of the parallax image light to a predetermined direction (see, for example, Patent Document 1).

JP 2009-239665 A

  However, in Patent Document 1, since the number of parallax images displayed on the sub-pixels included in each image constituting the image display body, that is, the number of parallaxes in the pixels is always constant, each game There is a problem that a stereoscopic image with the number of parallaxes according to the user's preference cannot be displayed.

  The present invention has been made paying attention to such problems, and an object of the present invention is to provide a gaming machine capable of displaying a stereoscopic image with the number of parallaxes according to the player's preference.

In order to solve the above-mentioned problem, a gaming machine according to claim 1 of the present invention provides:
A gaming machine (pachinko machine 1, slot machine 1001) capable of playing a predetermined game and capable of displaying stereoscopic images (stereoscopic images A to I),
An image display body (image liquid crystal) in which pixels (pixels P) composed of a plurality of subpixels (subpixels p1 to p9) capable of displaying a plurality of parallax images having different viewpoints constituting the stereoscopic image are repeatedly arranged adjacently. Panel 9a, image liquid crystal panel 1051), and emission direction limiting elements (vertical lenticular sheet 9b, vertical lenticular sheet 1057) that limit the emission direction of each parallax image light emitted from each sub-pixel to a predetermined direction corresponding to the parallax image. A stereoscopic image display device (variable display device 9, presentation display device 1050) capable of displaying a stereoscopic image composed of the parallax images,
Display control means (effect control CPU 86, display control unit 213, sub CPU 1091a, display control circuit 1092) for controlling the display of the stereoscopic image display device;
A parallax number receiving means (a CPU 86 for effect control, a parallax number changing button 517, a sub CPU 1091a, a parallax number changing button) for receiving a parallax number, which is the number of different parallax images displayed on subpixels included in the pixel, from the player. 1058),
With
The display control means performs control to display a parallax image having the number of parallaxes received by the parallax number receiving means on the sub-pixels.
According to this feature, the player designates his / her favorite number of parallaxes with the parallax number accepting means, so that the parallax image of the designated number of parallaxes is displayed on the sub-pixel. A stereoscopic image with the number of parallaxes according to the user's preference can be displayed.

The gaming machine of means 1 of the present invention is the gaming machine according to claim 1,
Provided with parallax image generation means (effect control CPU 86, parallax image generation unit 264, sub CPU 1091a) capable of generating parallax images corresponding to the number of sub-pixels (sub-pixels p1 to p9) included in the pixel (pixel P). ,
When the display control means (effect control CPU 86, display control unit 213, sub CPU 1091a, display control circuit 1092) displays the stereoscopic image on the stereoscopic image display device (variable display device 9, effect display device 1050), The parallax image generating unit generates a parallax image corresponding to the number of sub-pixels, and the parallax number receiving unit (effect control CPU 86, parallax number changing button 517, sub CPU 1091a, parallax number during display of the stereoscopic image. When the change button 1058) accepts a new number of parallaxes that is different from the number of parallaxes at that time, among the parallax images generated in advance by the parallax image generating means, the parallax image corresponding to the new number of parallaxes is selected as the sub-pixel. It is characterized by controlling the display on the screen.
According to this feature, a parallax image corresponding to the number of sub-pixels, that is, the maximum number of parallax images is generated even when a new parallax number is received from a player during display of a stereoscopic image. Thus, compared to the case where a parallax image with a new number of parallaxes is generated after the acceptance, a parallax image with a new number of parallaxes can be quickly displayed on the sub-pixel. Can be quickly implemented.

The gaming machine of means 2 of the present invention is the gaming machine described in means 1,
In the implementation period of the effect in which the stereoscopic image is displayed (notice effect S1), the number of parallaxes received by the parallax number receiving means (effect control CPU 86, parallax number change button 517, sub CPU 1091a, parallax number change button 1058). The parallax number changeable period (the production period T1, the production period T3, the production period T5) and the parallax number change impossible period (the production period T2, where the parallax number cannot be changed by reception in the parallax number receiving means) The production period T4) is preset,
The display control means (effect control CPU 86, display control unit 213, sub CPU 1091a, display control circuit 1092) is the parallax image generation means (effect control CPU 86, parallax image generation unit 264) during the parallax number changeable period. , The sub CPU 1091a) controls to generate a parallax image corresponding to the number of sub-pixels.
According to this feature, generation of parallax images corresponding to the number of sub-pixels, that is, generation of the maximum number of parallax images only needs to be performed in the period in which the number of parallaxes can be changed. The processing load for generating these parallax images can be reduced compared to the case where the parallax images are always displayed during image display.

The gaming machine of means 3 of the present invention is the gaming machine according to any one of claim 1, means 1, and means 2,
By displaying a predetermined suggestive effect stereoscopic image on the stereoscopic image display device (variable display device 9, effect display device 1050), it is suggested that the player is in an advantageous state or an advantageous state. Providing effect control means (effect control CPU 86, sub CPU 1091a) that implements suggested effects suggested by the difference in the number of parallaxes of the effect stereoscopic image,
The effect control means is configured such that the number of parallaxes identified using a determination table (parallax number determination table D) for determining the number of parallaxes of the suggestive effect stereoscopic image is the parallax number receiving means (effect control CPU 86, parallax). When the number of parallaxes is less than or equal to the number of parallax received from the player with the number changing button 517, the sub CPU 1091a, and the parallax number changing button 1058), the specified number of parallaxes is determined as the number of parallaxes of the suggestive effect stereoscopic image. When the number of parallax specified using the table is larger than the number of parallax received from the player by the parallax number receiving means, the number of parallax received from the player is determined as the number of parallax of the suggestive stereoscopic image,
The display control means performs control to display a stereoscopic image for suggestion effect with the number of parallax determined by the effect control means on the stereoscopic image display device.
According to this feature, even if the determination table corresponding to each parallax number that can be designated by the player is not prepared and stored in advance by the parallax number receiving means, the suggestion that the parallax number received by the player is matched. The suggestion effect by the stereoscopic image for effect can be implemented.

The gaming machine of means 4 of the present invention is the gaming machine according to claim 1 or means 1 to means 3, wherein
A cancel operation means (an effect control CPU 86, an operation button 516, a sub CPU 1091a, an effect switch 1056) that can be operated by a player during the game is provided,
The stereoscopic image display device (variable display device 9, effect display device 1050) can also display non-stereoscopic images,
The display control means (production control CPU 86, display control unit 213, sub CPU 1091a, display control circuit 1092) plays a game in the cancel operation means when displaying a stereoscopic image of a predetermined effect on the stereoscopic image display device. On the condition that the cancel operation (the long press of the operation button 516 or the effect switch 1056) is received from the person, at least the period until the effect ends (3D display stop period TS), the stereoscopic image of the effect Control to stop the display and display the non-stereoscopic image of the effect on the stereoscopic image display device;
It is characterized by that.
According to this feature, when the player wants to cancel the display of the stereoscopic image displayed in each effect during the game, the display of the stereoscopic image is canceled by operating the cancel operation means. Therefore, the player can play the game by stopping the display of the stereoscopic image and switching to the display of the non-stereoscopic image during the game.
That is, as disclosed in Japanese Patent Application Laid-Open No. 09-164253, as a display mode, there is a game machine that automatically changes between a mode for displaying a stereoscopic video and a mode for displaying a non-stereo video. Depending on the type of stereoscopic image, even if it is desired to cancel the display of the stereoscopic image and switch to the display of the non-stereo image, the problem that it is not possible to switch to the non-stereo image can be solved.

For the gaming machine of means 4 of the present invention, there are a plurality of the effects (notice effect S1, variable effect S2, super reach effect S3), and a cancelable effect (notice that the display of the stereoscopic image is permitted to be canceled) Production S1) and non-cancelable productions (change production S2, super reach production S3) for which display stop of the stereoscopic image is not permitted,
When the display control means (production control CPU 86, display control unit 213) receives a cancel operation from the player in the cancel operation means (production control CPU 86, operation button 516), the effect being performed is canceled. It is preferable to stop the display of the stereoscopic image of the effect as a further condition that it is a possible effect, and in this way, the player can stop the stereoscopic display only in the cancelable effect, and is inadvertent Therefore, it is possible to avoid that the stereoscopic display is stopped and the effect becomes unclear or the interest is remarkably lowered.

  Further, regarding the gaming machine of the means 4 of the present invention, when the effect of the stereoscopic image displayed on the stereoscopic image display device (variable display device 9) is the cancelable effect (notice effect S1), It is preferable to provide notifying means (production control CPU 86) for notifying that display of a stereoscopic image can be stopped (displaying “Cancel OK”). In this way, the player can display a stereoscopic image. Whether or not can be canceled can be accurately grasped.

Regarding the gaming machine of the means 4 according to the present invention, the cancelable period during which the cancel operation can be accepted (the effect period T1, the effect period T3, the effect period T5) and the cancel are performed during the cancelable effect implementation period. An uncancellable period (production period T2, production period T4) for which the operation cannot be accepted is set,
In the cancelable period, the display control means (production control CPU 86, display control unit 213) displays on the display means (variable display device 9) when the stereoscopic image and the cancel operation are received. It is preferable to perform control to simultaneously generate a stereoscopic image in parallel, and in this way, a non-stereo image is generated in parallel with the stereoscopic image displayed on the display means during the cancelable period. When the cancel operation is accepted, it is possible to quickly shift to the display of the non-stereo image, and the parallel generation of the non-stereo image and the stereo image only needs to be performed during the cancelable period. In comparison, the processing load for generating these images can also be reduced.

  Further, for the gaming machine of the means 4 of the present invention, when the display control means (the effect control CPU 86, the display control unit 213) accepts the cancel operation, a predetermined switching after the operation is performed. It is preferable to switch to the non-stereo image at the time point (the time point when the effect period T2 is changed to the effect period T3 and the time point when the effect period T4 is changed to the effect period T5). Predetermined switching at a suitable time, for example, a time when the player is less confused even when moving to a non-stereoscopic image, and the change in the image is small because the processing load for image generation is small and the switching process is easy By setting it to the point in time, it is possible to avoid as much as possible that the player will be confused by switching to a non-stereoscopic image or that the processing load will increase and cause problems. That.

Further, for the gaming machine of the means 4 of the present invention, a stereoscopic display stop period (3D display stop period TS) in which the display of the stereoscopic image is stopped by a cancel operation by the cancel operation means (production control CPU 86, operation button 516). Stop period determining means (effect control CPU 86) for determining
Aggregating means for summing up the number of cancel operations performed again after a predetermined period (cancellation count addition period TK) elapses after the stereoscopic display is stopped for the first time after the stereoscopic display stop period ends. Cancel counter),
With
The stop period determining means preferably determines a longer period as the stereoscopic display stop period as the number of times counted by the counting means (the number of cancellations stored in the cancel counter) increases. For example, when the player repeatedly performs the cancel operation, the stereoscopic display stop period becomes longer, so that the time for the player to perform the cancel operation can be reduced.

In addition, for the gaming machine of the present invention, there are a plurality of the effects (notice effect S1, variable effect S2, super reach effect S3), and the parallax number changeable effect (notice effect S1) for which the change in the number of parallaxes is permitted. ) And a parallax number non-changeable effect (change effect S2, super reach effect S3) for which the change of the parallax number is not permitted,
When the display control means (the effect control CPU 86 and the display control unit 213) receives a new number of parallaxes from the player in the parallax number receiving means, the effect being implemented is the effect that the number of parallaxes can be changed. As a further condition, it is preferable to perform control to display the parallax image of the accepted number of parallax on the sub-pixel, and in this way, the player can change the number of parallaxes only in the parallax number changeable effect. Therefore, it is possible to avoid that the number of parallaxes is inadvertently changed and the production becomes unclear or the interest is significantly reduced.

  Further, regarding the gaming machine of the present invention, when the effect of the stereoscopic image displayed on the stereoscopic image display device (variable display device 9) is the effect of changing the number of parallaxes (notification effect S1), the stereoscopic image is displayed. It is preferable to provide notifying means (production control CPU 86) for notifying that the number of parallaxes of the image can be changed (displaying “change parallax number OK”). It is possible to accurately grasp whether or not the number of parallaxes can be changed.

In addition, for the gaming machine of the present invention, during the period of execution of the parallax number changeable effect, the parallax number changeable period during which the parallax number receiving unit can accept a new number of parallaxes (effect period T1, effect period) T3, production period T5) and a parallax number change impossible period (production period T2, production period T4) in which the reception of a new number of parallaxes by the parallax number receiving unit is disabled, are set.
The display control means (the effect control CPU 86 and the display control unit 213) performs control to generate a parallax image corresponding to the number of sub-pixels by the parallax image generation means during the parallax number changeable period. Preferably, in this way, during the period in which the number of parallaxes can be changed, a parallax image corresponding to the number of sub-pixels, that is, the maximum number of parallax images is generated. Transition to the display of a stereoscopic image with a large number of parallaxes, and the generation of the maximum number of parallax images only needs to be performed in the period in which the number of parallaxes can be changed. Thus, the processing load for generating these parallax images can also be reduced.

  In the gaming machine of the present invention, when the display control means (the effect control CPU 86, the display control unit 213) receives a new number of parallaxes by the parallax number receiving means, the display control means determines in advance after the reception. It is preferable to perform switching to the new number of parallaxes at a predetermined switching time (switching time from the production period T2 to the production period T3, switching time from the production period T4 to the production period T5). If this is the case, it is possible to compare changes in images that are suitable for switching, for example, when the number of parallaxes changes, the player is less confused and the processing load for generating parallax images is relatively small and switching is easy. By setting an appropriate time point or the like as a predetermined switching time point, the player may be confused by switching the number of parallaxes, or the processing load may increase and cause problems. As much as possible be avoided.

It is a front view which shows the pachinko machine which is the gaming machine of execution example 1 where this invention is applied. It is a rear view which shows a pachinko machine. It is a block diagram which shows the circuit structural example of a pachinko machine. It is a block diagram showing a circuit configuration example in the effect control board. It is a figure which shows the VRAM area | region in SDRAM. It is a figure which shows the structure of the fluctuation | variation display apparatus of a pachinko machine, the display state in a fluctuation | variation display apparatus, and the visual recognition state of the image from a player's viewpoint position. It is a figure which shows the parallax image displayed on each subpixel. (A) is a figure which shows the display state of the subpixel in the case of displaying a stereoscopic image, (b) is a figure which shows the display state of the subpixel in the case of displaying a non-stereoscopic image. (A)-(d) is a figure which shows the display state of the subpixel in the case of each set parallax number. It is a figure which shows the state which sets the number of parallax with a parallax number change button. It is a figure which shows the simultaneous display state of 2D image and 3D image. (A) is a figure which shows the display of the stereo image reproduced | regenerated with a variable display apparatus in a notice effect, (b) is a figure which shows the display of the stereo image reproduced | regenerated with a variable display apparatus in a super reach effect. (C) is a table | surface which shows the relationship between the three-dimensionality and speed of each character displayed and displayed by a stereo image. It is a time chart when cancellation operation is made in production period T5. It is a time chart when cancellation operation is made in production period T4. It is a time chart when operation which changes the parallax number of a three-dimensional image is made | formed in notice effect S1. (A) is a time chart showing a 3D display stop period when a cancel operation is performed, (b) is a time chart showing reset of the number of cancels when no cancel operation is performed, (c) Is a 3D display suspension period determination table. It is a figure which shows the modification about a reservation notice effect. It is explanatory drawing which shows the random number which CPU for production control uses. (A)-(c) is a figure which shows the parallax number determination table in the case of each set parallax number. It is explanatory drawing which shows the flow of a super reach production. It is a figure which shows the modification of a parallax number determination table. It is a figure which shows the correction rule in the modification of a parallax number determination table. (A)-(c) is a figure which shows the display state of a subpixel in case the parallax number is three. (A)-(c) is a figure which shows the relationship between the viewpoint position of a player's left-right direction, and the display state of the image liquid crystal panel. (A), (b) is a figure which shows the relationship between the viewpoint position of a player's front-back direction, and the display state of the image liquid crystal panel. It is a front view of the slot machine which is the game machine of Example 2 to which this invention was applied. It is a block diagram which shows the structure of a slot machine. It is a figure which shows the structure of the fluctuation | variation display apparatus of another form.

  A mode for carrying out a gaming machine according to the present invention will be described below based on Examples 1 and 2.

  A gaming machine according to the first embodiment will be described with reference to FIGS. First, reference numeral 1 in FIG. 1 is a gaming machine to which the present invention is applied.

  First, the overall configuration of a pachinko gaming machine that is an example of the gaming machine of the present invention will be described. FIG. 1 is a front view of a pachinko gaming machine 1 (hereinafter abbreviated as “pachinko machine 1”) as seen from the front, and FIG. 2 is a rear view showing the pachinko machine 1. In the following description, the front side (player side) in FIG. 1 will be described as the front side of the pachinko machine 1, and the back side will be described as the back side. In addition, the front surface of the pachinko machine 1 in the present embodiment is an opposing surface that faces the player when the pachinko machine 1 is viewed from the player side.

  The pachinko machine 1 is mainly configured by an outer frame 100 (see FIG. 2) formed in a vertically long rectangular shape, and a front frame 101 (see FIG. 2) attached to the outer frame 100 so as to be openable and closable. . A glass door frame 102 and a lower door frame 103 are provided on the front surface of the front frame 101 so as to be openable and closable around one side, respectively.

  As shown in FIG. 1, the upper front portion of the lower door frame 103 attached to the lower side of the glass door frame 102 is a game ball storage unit that can store pachinko balls (hitting balls) as game media (game balls). An upper plate portion 3 a having a hitting ball supply tray (also referred to as an upper plate) 3 formed on the upper surface thereof protrudes toward the front of the pachinko machine 1 (front direction of the pachinko machine 1). Further, below the upper plate portion 3a, a lower plate portion 4a (protruding portion) having a surplus sphere storage plate (also referred to as a lower plate) 4 formed on the upper surface is disposed in front of the pachinko machine 1 (the front surface of the pachinko machine 1). Direction). Also, below this upper plate portion 3a, an operation lever 600, which will be described later, is pivotally supported, and a lower plate portion 4a (also called a lower plate) 4 is formed on the upper surface. The projecting portion) is projected toward the front of the pachinko machine 1 (front direction of the pachinko machine 1). A hitting operation handle (operation knob) 5 for firing a pachinko ball is provided on the right side.

  The operation lever 600 includes an operation rod that is held by the player, and a trigger switch is provided at a predetermined position of the operation rod (for example, a position where the index finger of the operator is applied when the player holds the operation rod). A trigger button is provided. The trigger button can be operated in a predetermined direction by performing a push / pull operation with a predetermined operation finger (for example, index finger) while the player holds the operation lever of the operation lever 600 with an operation hand (for example, the left hand). What is necessary is just to be comprised. Lever switches 510a to 510d arranged in four directions in order to detect a tilting operation with respect to the operating rod may be provided inside the main body of the lower plate 4a below the operation lever 600.

  Further, a parallax number change button 517 for setting a parallax number of a stereoscopic image, which will be described later, is provided on the left side of the upper plate portion 3a so that the player can perform a pressing operation. The parallax number change button 517 includes a plus button in which a parallax number change switch 517a is provided and displayed as “+”, and a minus button in which a disparity number change switch 517b is provided and processed as “−”. That is, the parallax number change button 517 of the present embodiment corresponds to the parallax number receiving means of the present invention.

  In addition, the member that forms the upper plate 3 can be operated by a player to perform a predetermined instruction operation by, for example, pressing a predetermined position on the upper surface of the upper plate 3 main body (for example, above the operation lever 600). An operation button 516 is provided. The operation button 516 may be configured to be able to detect a predetermined instruction operation such as a pressing operation from a player mechanically, electrically, or electromagnetically. A button switch 516a (see FIG. 3) for detecting an operation action of the player performed on the operation button 516 may be provided inside the main body of the upper plate at the installation position of the operation button 516. Further, the operation button 516 can be operated to cancel the stereoscopic image display, that is, to switch to a non-stereo image by pressing the operation button 516 when setting the parallax number by the parallax number changing button 517 described above. It is said that. That is, the operation button 516 of the present embodiment corresponds to the cancel operation means of the present invention.

  A pair of left and right speakers 27a and 27b, which will be described later, are disposed on the front left and right sides of the lower door frame 103.

  A transparent game board 6 detachably attached to the front frame 101 is disposed on the back surface of the glass door frame 102. The game board 6 is a structure including a plate-like body constituting the game board 6 and various components attached to the plate-like body. A game area 7 is formed on the front surface of the game board 6.

  In the vicinity of the center of the game area 7, a variable display device (decorative symbol display device) 9 including a plurality of variable display areas, each displaying a decorative symbol for presentation, can be seen through the transparent game board 6. Thus, it is provided on the back surface of the game board 6. In addition, a special symbol display device (special symbol display device) 8 (see FIG. 3) for variably displaying special symbols as a plurality of types of identification information that can identify each of them is provided at predetermined locations on the game board 6. . The fluctuation display device 9 has, for example, three fluctuation display areas (symbol display areas) “left”, “middle”, and “right”. The variable display device 9 displays decorative symbols as decorative information as a plurality of types of identification information that can be identified during the variable symbol display period of the special symbols by the special symbol indicator 8. I do. The variable display device 9 is controlled by devices such as an effect control microcomputer 81 (see FIG. 3) mounted on an effect control board 80 described later.

  The special symbol display 8 is realized by a simple and small display (for example, 7-segment LED) capable of variably displaying numbers 0 to 9, for example.

  Further, as shown in FIG. 6, the variable display device 9 irradiates the liquid crystal panel 9a for displaying a stereoscopic image (video) and the planar light from the rear side to the front side of the liquid crystal panel 9a for image. An image display comprising an integral imaging type autostereoscopic display liquid crystal display device having a backlight 9c and a vertical lenticular sheet 9b as an emission direction limiting element provided on a substantially entire front surface of the image liquid crystal panel 9a. Realized in the device. The variation display device 9 performs a variation display of the decorative symbol during the variation display period of the special symbol by the special symbol indicator 8.

  In the present embodiment, the variable display device 9 will be described with reference to an example in which a liquid crystal display device is used as the image liquid crystal panel 9a. However, the present invention is not limited to this example. Any display device capable of display is acceptable, and an organic or inorganic electroluminescence (EL) panel, display device of other image display forms such as PDP (Plasma Display Panel), dot matrix LED, FED (Field Emission Display), etc. It may be constituted by.

  As shown in FIG. 6, the image liquid crystal panel 9a has a plurality of pixels P each of which is composed of three primary colors (RGB) arranged in the vertical direction and having independent luminance information for each primary color in the horizontal direction and the vertical direction. Arranged and configured. As shown in FIG. 7, each pixel P will be described in detail. Each pixel P is composed of nine subpixels p1 to p9 that are each composed of three primary colors (RGB) and are divided into a comparatively long length. Arranged and configured. Hereinafter, each subpixel for each pixel P will be described with subpixel numbers p1 to p9 from the left to the right in the drawing. The sub-pixels p1 to p9 having the same sub-pixel number among the plurality of adjacent pixels P display the stereoscopic images A to I or the non-stereo image a corresponding to the sub-pixels p1 to p9.

  More specifically, as illustrated in FIG. 8A, when displaying a stereoscopic image, the display control unit 213 displays, for example, stereoscopic images A to P that are different parallax images on the subpixels p1 to p9 of each pixel P. I is displayed, and when a non-stereo image is displayed as shown in FIG. 8B, the same non-stereo image a is displayed on all the subpixels p1 to p9 of each pixel P. It is supposed to be.

  Further, the display control unit 213 to be described later separately displays different parallax images or the same parallax image for each of the sub-pixels p1 to p9 of each pixel P according to the type of performance of the pachinko machine 1, the position of the player, and the like. As a control to be displayed, or as a modification described later, black display (non-display) control is performed.

  Next, as shown in FIG. 6, the vertical lenticular sheet 9b is made of a thin plate member made of a light-transmitting material, and the back surface to be attached to the image liquid crystal panel 9a is formed in a substantially flat shape. The front surface, which is the side, is formed in a curved surface that bulges in a substantially bowl shape toward the player side in a continuous manner in a wavy shape that is approximately equal to the horizontal width of each pixel P.

  In more detail, as shown in FIG. 7, the vertical lenticular sheet 9 b is most facing toward the front surface of each pixel P at the position of the central subpixel p5 among the nine subpixels arranged side by side on the left and right of each pixel P. It is formed as a bulging curved surface, and is used as a lens that radiates a maximum of nine parallax images constituting a stereoscopic image displayed on each of the sub-pixels p1 to p9 in nine different directions. That is, the vertical lenticular sheet 9b limits the emission direction of each parallax image light emitted from each subpixel p1 to p9 to a predetermined direction corresponding to the parallax image.

  The aspect of the stereoscopic image that can be viewed from the viewpoint position of the player will be described in detail. For example, when the player sets the viewpoint position to the front of the pachinko machine 1, the display target sub-position located at the center among the nine sub-pixels p1 to p9. Only the image displayed on the pixel p5 can be viewed, and the remaining subpixels p1 to p4 and p6 to p9 other than the display target subpixel p5 in this case cannot be viewed. Accordingly, the player visually recognizes the display target subpixel p5 of each pixel P in this case, and thereby recognizes the stereoscopic image E of the predetermined display object corresponding to the image viewed from the frontal position as the viewing position as the display object. be able to. In the side area of the screen, the display target subpixel may be corrected according to the size of the screen in response to the change in the viewing direction.

  Similarly, for example, when the player sets the viewpoint position to the left slightly from the front in front of the pachinko machine 1, the player is displayed on, for example, the display target subpixel p3 located slightly to the left of the center among the nine subpixels p1 to p9. In this case, the remaining subpixels p1, p2, and p4 to p9 other than the display target subpixel p3 cannot be viewed. Therefore, the player visually recognizes the image displayed on the display target sub-pixel p3 in this case, so that the three-dimensional image C of the predetermined display object corresponding to the image visually recognized from the position slightly on the left side from the front in front as the viewing position. Can be recognized as a display object.

  That is, on each of the subpixels p1 to p9, stereoscopic images A to I of a predetermined display object corresponding to the images of the display object viewed from different viewing positions can be displayed.

  As shown in FIG. 1, a start winning device 15 having a first starting port 15 a and a second starting port 15 b as a winning region that can accept a pachinko ball is provided below the fluctuation display device 9. In the start winning device 15, the first start port 15a is provided in the upper part, and the second start port 15b is provided in the lower part. A pair of movable pieces 13 and 13 are provided on the left and right sides of the second start port 15b in such a manner that an opening / closing operation can be performed. The first start port 15a is open upward and is always in a state where a pachinko ball can enter (accept). On the other hand, the second start port 15b is provided with a structure around the first start port 15a above and the movable pieces 13 and 13 are provided on the left and right, so that the movable pieces 13 and 13 are in a closed state. When the movable pieces 13 and 13 are in an open state, the pachinko ball can enter (accept). Thus, the first start port 15a does not change the easiness of winning, and the second start port 15b changes the easiness of winning according to the opening / closing operation of the movable pieces 13, 13.

  The starting prize-winning device 15 is able to win in the state where the movable pieces 13 and 13 are in the closed state, although it is difficult to win in the second starting port 15b (that is, the pachinko ball has won a prize). It may be configured to be difficult). In addition, the start winning device 15 may be provided with only the first start port 15a that does not change the easiness of winning as a start port, and it is easy to win by opening and closing the movable pieces 13, 13. Only the second start port 15b whose height changes may be provided.

  The movable pieces 13 and 13 of the start prize-winning device 15 are driven by the solenoid 16 when an opening condition described later is satisfied, so that the movable pieces 13 and 13 are opened from the closed state for a predetermined period and then closed. When the movable pieces 13 and 13 of the start winning device 15 are in the open state, the pachinko ball is easy to win the second start port 15b (easy to start start) and is advantageous to the player (first state). ) On the other hand, when the movable pieces 13 and 13 of the start winning device 15 are in the closed state, the pachinko ball does not win the second start opening 15b (it becomes difficult to start winning), which is a disadvantageous state for the player (second state). State). The winning ball that has entered the first start port 15a is guided to the back of the game board 6 and detected by the first start port switch 14a. The winning ball that has entered the second start port 15b is guided to the back of the game board 6 and detected by the second start port switch 14b.

  The predetermined number of the game board 6 displays four numbers indicating the number of valid winning balls that have entered the first starting port switch 14a or the second starting port switch 14b, that is, the number of reserved memories (also referred to as starting memory or starting winning memory). A special symbol storage memory display 18 (see FIG. 3) is provided. The special symbol reservation storage display 18 displays up to four reservation storage numbers in the order of winning. The special symbol hold memory display 18 increases the stored data in the hold memory by 1 and increases the number of LEDs in the lit state by 1 every time there is a start winning in the first start port 15a or the second start port 15b. Each time the special symbol display 8 starts the variable display, the special symbol storage memory display 18 decreases the storage data of the storage by 1 and decreases the number of LEDs in the lit state by 1 (that is, one LED Is turned off. Specifically, the special symbol hold storage display 18 shifts the lighting state every time the special symbol display 8 starts the variable display. In this example, an upper limit number (up to 4) is provided for the number of reserved memories by winning to the first start port 15a or the second start port 15b. However, the present invention is not limited to this, and the upper limit number of the reserved storage number may be a value of 4 or more, or may be a value less than 4.

  A special variable winning ball device 20 using an opening / closing plate that is opened and closed by a solenoid 21 is provided below the start winning device 15. The special variable winning ball apparatus 20 is provided with a big winning opening that is opened and closed by an opening / closing plate, and the opening / closing plate is controlled to an open state (first state) advantageous to the player in the big hit gaming state, and the big hit gaming state In other states, the open / close plate is controlled to a closed state (second state) which is disadvantageous to the player. As described above, the special variable winning ball apparatus 20 satisfies the release condition when it enters the big hit gaming state. Of the winning balls that are won in the special variable winning ball apparatus 20 and guided to the back of the game board 6, the winning ball that has entered one (V winning area: special area) and the pachinko ball that has entered the other area are counted as they are. 23. A solenoid 21a (see FIG. 3) for switching the route in the special winning opening is also provided on the back of the game board 6.

  When the pachinko ball passes through the gate 32 and is detected by the gate switch 32a, the variable display on the normal symbol display 10 which displays the normal symbols as a plurality of types of identification information in a variable manner is started. In this embodiment, left and right LEDs (not shown) are turned on alternately by turning on the LEDs alternately. For example, if the left LED is turned on at the end of the change display, it becomes a hit. . When the stop symbol on the normal symbol display 10 becomes a predetermined symbol (winning symbol), the opening condition of the movable pieces 13 and 13 of the start winning device 15 is established, and the movable pieces 13 and 13 in the start winning device 15 are 13 is opened for a predetermined number of times for a predetermined time. In the vicinity of the normal symbol display 10, the normal symbol holding memory display 41 (see FIG. 3) having a display unit with four LEDs for displaying the number of memorized effective passing spheres that have passed through the gate 32, that is, the starting passing memorized number. ) Is provided. Every time there is a pachinko ball passing through the gate 32, the stored data of the start passing memory is incremented by 1, and the normal symbol holding memory display 41 increments the LED to be lit by 1. Then, every time the variable display on the normal symbol display 10 is started, the stored data of the start passage memory is decreased by 1, and the LED to be lit is decreased by 1.

  The game board 6 is provided with a plurality of normal winning ports including a first normal winning port 29 and a second normal winning port 30 as a winning area of a winning device that accepts a pachinko ball and allows winning. The winning of the pachinko ball to the first normal winning opening 29 is detected by the first winning opening switch 29a. The winning of the pachinko ball in the second normal winning opening 30 is detected by the second winning opening switch 30a. The first starting port 15a, the second starting port 15b, and the big winning port also constitute a winning area of the winning device that accepts a pachinko ball and allows winning. In addition, decorative light emitting portions 25L and 25R in which decorative LEDs 25a blinking and displayed during the game are provided around the left and right of the game area 7, and an out port 26 for collecting pachinko balls that have not won a prize is provided at the bottom. There is.

  Two speakers 27L and 27R that emit sound effects are provided at the left and right upper portions outside the game area 7, and two speakers 27a and 27b that emit sound effects are provided at the left and right lower portions. On the outer periphery of the game area 7, a top lamp module 530 in which various LEDs such as a rotating body LED are incorporated, a left light emitting unit 28L in which a left frame LED 28b (see FIG. 3) is incorporated, and a right frame LED 28c (see FIG. 3). ) Is built in. Further, a decoration LED is installed around each structure (such as a big prize opening) in the game area 7. The LED for the rotating body, the left frame LED 28b, the right frame LED 28c, and the decoration LED are examples of the decoration light emitter provided in the pachinko machine 1.

  In this example, a prize ball LED 51 that is lit during award ball payout is provided at a predetermined position of the left light emitting unit 28L, and a ball break LED 52 that is lit when a supply ball is cut is provided at a predetermined position of the right frame LED 28c. Is provided.

  Various light emitting means such as prize ball LED 51, ball-out LED 52, decoration LED 25 a, left frame LED 28 b, right frame LED 28 c, and each LED in the top lamp module 530 are based on the effect control command output from the main board 31. Lighting control (LED control) is performed based on the serial signal output from the computer 81. In addition, sound generation control (sound control) from the speakers 27L, 27R, 27a, and 27b is also performed by the effect control microcomputer 81.

  A pachinko ball launched from a hitting ball launcher (not shown) by operating the hitting operation handle 5 of the player enters the game area 7 through a hitting guide rail (not shown), and then descends the game area 7. When a pachinko ball enters the first start port 15a and is detected by the first start port switch 14a, or enters the second start port 15b and is detected by the second start port switch 14b, a special symbol variation display is displayed. If it can be started, the special symbol on the special symbol display 8 starts to be displayed in a variable manner. If the special symbol variable display is not ready to start, the number of reserved memories is increased by one.

  The variation display of the special symbol on the special symbol display 8 stops when the variation display time set every time the variation display is performed. If the special symbol (stop symbol) at the time of stoppage is a jackpot symbol (also referred to as a jackpot display result) as a specific display result, it will be a jackpot and the game will shift to a jackpot gaming state. In the big hit gaming state, the special variable winning ball apparatus 20 is released until a predetermined time elapses or a predetermined number (for example, ten) of pachinko balls wins. Then, if the pachinko ball wins the V winning area while the special variable winning ball apparatus 20 is opened and is detected by the count switch 23, a continuation right is generated and the special variable winning ball apparatus 20 is opened again. The generation of the continuation right is permitted with a predetermined number of times such as 15 rounds as an upper limit value. Such control is called repeated continuation control. In the repeated continuation control, a state in which the special variable winning ball apparatus 20 is opened is called a round.

  If the special symbol on the special symbol display 8 at the time of stoppage is a predetermined special big-hit symbol (probable variation big-hit symbol) among the big-hit symbols (probability big-hit symbol) ) Becomes a more advantageous state for the player, a probability variation state (hereinafter referred to as a probability variation state) that becomes higher than the normal gaming state, which is a normal state different from the big hit gaming state. Hereinafter, the probability variation state is also referred to as a high probability state (sometimes abbreviated as a high probability state). Further, the non-probable change state is also referred to as a low probability state (sometimes abbreviated as a low probability state).

  In addition, when the display result of the special symbol when the variable display on the special symbol display 8 is stopped is the probability variation big hit symbol, the variable time is reduced after the big hit gaming state, and the control is performed for a predetermined period of time. The Compared to the normal gaming state, the time-short state is a variation display time of each of the special symbol display 8, the variation display device 9, and the normal symbol display 10 (the time from the start of variation to the time when the display result is derived and displayed). ) Is a control state in which display results are derived and displayed at an early stage. Further, during the time-short state, the probability that the stop symbol in the normal symbol display 10 becomes a winning symbol is increased, and the opening time of the movable pieces 13 and 13 of the start winning device 15 is lengthened and the number of times of opening is increased. . During the time-short state, since the display time of the symbol variation is shortened, the number of reserved memories to be described later is digested early, and the start winning that occurs exceeding the upper limit (for example, “4”) of the number of reserved memories becomes invalid. Since it is easy to derive and display the jackpot display result early in the short term, it is easy to derive and display the jackpot display result early, so the display result of the variable display is likely to become the display result of the jackpot symbol from a time efficient viewpoint It becomes a gaming state advantageous to the player. As described above, in the case of a probable big hit, the high probability state and the short time state are controlled in a predetermined period after the end of the big hit gaming state. The short time state over a predetermined period after the end of the jackpot gaming state is the earlier, until the next jackpot gaming state occurs or until the special symbols and decorative symbols are displayed a predetermined number of times (100 times). Continue until either condition is met.

  Also, when considering the payout of pachinko balls according to the winning, the time-short state is shorter than the non-time-short state and the normal symbol variation display time is shortened, and the stop symbol in the normal symbol display 10 becomes a winning symbol. The probability is increased, the opening time of the movable pieces 13 and 13 of the start winning device 15 at the time of winning is lengthened, and the number of times of opening the movable pieces 13 and 13 of the starting winning device 15 at the time of hitting is increased. Based on this, the movable pieces 13 and 13 of the start winning device 15 are likely to be in an open state as compared with the normal gaming state. Accordingly, in the short-time state, it is easy to generate a prize (including both a case where the start prize is valid and a case where the prize is invalid) in the second start port 15b, so the number of pachinko balls ( The ratio of the number of pachinko balls (the number of balls to be paid out) to be paid out as winning balls according to the winning is greater than the number of hitting balls) as compared to the normal gaming state. In general, the ratio of the number of paid-out balls for winning a prize to the number of shot balls is called “base”. For example, when there are 40 payout balls with respect to 100 shot balls, the base is 40 (%). In the case of this embodiment, for example, a time-short state having a higher base than a non-time-short state such as a normal gaming state is called a high base state, and conversely, a base game state having a lower base compared to such a high base state. Such a non-short-time state is called a low base state.

  In this way, the ratio of the number of award balls paid out by winning a prize to the number of balls launched is generally called “base”, but the maximum number of pachinko balls fired per unit time such as 1 minute is limited to a certain number. ing. For this reason, the “base” can also be indicated by a total value of the number of winning balls paid out by winning a plurality of winning openings provided in the game area in a unit time. For example, assuming that the maximum number of pachinko balls fired per unit time is 100, the total number of award balls paid out by winning in a unit time matches the general “base” value. Based on such relevance, in the present embodiment, each of the first start port 15a, the second start port 15b, the first normal winning port 29, and the second normal winning port 30 is an abnormality monitoring target winning port, A total value of the number of paid-out balls of the winning ball due to the winning of the abnormality monitoring target winning opening is called a base, and is used as an object of abnormality monitoring regarding winning.

  Whether the probability variation state (high probability state) or the non-probability variation state (low probability state) is determined based on whether or not the probability variation flag, which is a flag set in the probability variation state, is set. . Whether the time-short state (high base state) or the non-time-short state (low base state) is determined is determined based on whether or not the time-short flag, which is a flag set in the time-short state, is set. Is done.

  In addition, in the state that is not controlled to the above-mentioned time-short state, every time the number of special symbols on-hold storage exceeds a predetermined number, the memory that controls the memory variation shortened state that shortens the variation display time of the special symbol and the decorative symbol Variation shortening control is performed. The memory fluctuation shortening control ends when the number of reserved symbols for special symbols is less than a predetermined number. Therefore, even in a state where the time-short state is not controlled, there is a case where the variation display time of the special symbol and the decorative symbol is shortened.

  The decorative symbols that are variably displayed in the variable display device 9 are variably displayed in a predetermined relationship with the special symbol variation display in order to enhance the decoration effect of the special symbol variation display in the special symbol display 8. It is a symbol with a special meaning. The predetermined relationship for such symbols includes, for example, the relationship in which the decorative symbol variation display starts when the special symbol variation display is started, and the special symbol display result at the end of the special symbol variation display. This includes a relationship in which the decorative symbol display result is derived and displayed and the decorative symbol variation display is terminated. When the special symbol display 8 derives and displays a predetermined jackpot symbol as a display result, the variable display device 9 derives and displays a combination of the jackpot symbol with left, middle and right symbols as a display result. The Such a display result of the jackpot symbol by the special symbol and the display result of the combination of the jackpot symbol by the decoration symbol are referred to as a jackpot display result.

  The special symbol display 8 and the fluctuation display device 9 have a correspondence relationship as described above, and therefore, in the following description, these may be collectively referred to as a fluctuation display unit.

  Next, the reach display mode (reach) will be described. The reach display mode (reach) in the present embodiment means that the symbols that have not been stopped when the stopped symbols constitute a part of the jackpot symbol, and that all or This is a state where some symbols are synchronously displayed while constituting all or part of the jackpot symbol.

  For example, in the variable display device 9, an effective line (one effective line in the case of this embodiment) that becomes a big hit when the symbol stops is determined in advance, and a part of the display area on the effective line is preliminarily set. A state in which the variable display is performed in the display area on the active line that has not been stopped when the predetermined symbol is stopped (for example, among the left, middle, and right variable display areas in the variable display device 9) The left and right display areas are stopped and the same display is still displayed, and the middle display area is still in the variable display mode), and all or part of the display area on the active line A state in which all or a part of the jackpot symbol is configured and displayed in a synchronized manner (for example, all the left, middle, and right display areas in the variation display device 9 are displayed in a varying manner and are always the same. The state) variable display in a state where the handle is aligned is made that reach the display mode or reach.

  Also, during the reach, an unusual effect may be performed with LEDs or sounds. This production is called reach production. Further, in the case of reach, a character (an effect display imitating a person or the like, which is different from a design (decoration design or the like)) or a display mode (for example, a color or the like) of the background image of the variable display device 9 is displayed. ) May change. This change in character display and background display mode is called reach effect display. In addition, some reach is set so that when it appears, a big hit is likely to occur compared to a normal reach. Such special (specific) reach is called super reach.

  In addition, for the variable display device 9, there is a case where a big hit announcement effect is given to notify that there is a possibility of a big hit in the variable display that triggers a big hit.

  In this embodiment, as the big hit, a plurality of types of big hits such as a normal big hit and a probable big hit are provided. In the following description, when “big hit” is simply indicated without specifying the types of big hits, it is a case where these multiple types of big hits are representatively shown.

  Usually, the big hit is a big hit (non-probable big hit) that becomes a low probability state and a low base state by not being in a probable change state after the end of the big hit gaming state and being in a short time state. Such a state with a low probability state and a low base state is called a low probability low base state. The probable big hit is a big hit that becomes a probable state after the end of the big hit gaming state, a high probability state in which the time is short for a predetermined period, and a high base state. Such a state with a high probability state and a high base state is referred to as a highly accurate high base state. After the probability variation big hit, when the predetermined period elapses, the time reduction state ends, and the state becomes a high probability state and a low base state. Such a state having a high probability state and a low base state is referred to as a high probability low base state.

  Next, the structure of the back surface (back surface) of the pachinko machine 1 will be described with reference to FIG. FIG. 2 is a rear view showing the pachinko machine.

  As shown in FIG. 2, on the back side of the pachinko machine 1, a variable display control unit 49 including an effect control board 80 on which an effect control microcomputer for controlling the variable display device 9 is mounted, a game control microcomputer, and the like are mounted. Various boards such as a game control board (main board) 31, an audio output board 70, an LED driver board (not shown), and a payout control board 37 on which a payout control microcomputer for performing ball payout control is mounted. is set up.

  Further, on the back side of the pachinko machine 1, there are provided a power supply board 960 and a launch control board 91A on which power supply circuits for generating various power supply voltages such as DC30V, DC21V, DC12V, and DC5V are mounted. The power supply board 960 is attached to the back side of the launch control board 91A, and the payout control board 37 is overlapped on the back side, but the exposed part exposed so as to be visible from the outside without overlapping the payout control board 37 includes: Main board 31 in pachinko machine 1 and each electrical component control board (production control board 80 and payout control board 37) and each electrical component provided in pachinko machine 1 (parts that operate when power is supplied) A power switch is provided as power supply permission means for executing or cutting off power supply. Furthermore, a replaceable fuse is provided inside the power switch in the exposed portion (inside the substrate).

  The electrical component control board is mounted with electrical component control means including an electrical component control microcomputer. The electrical component control means is an electrical component (game device: ball payout device 97, variable display device 9, LED, etc.) provided in the pachinko machine 1 in accordance with a command signal (control signal) as a command from the game control means or the like. Light emitters, speakers 27L, 27R, 27a, 27b, etc.). Hereinafter, description may be made by including the main board 31 in the electric component control board. In that case, the electrical component control means mounted on the electrical component control board includes a game control means and a means for controlling the electrical components provided in the pachinko machine 1 in accordance with a command signal from the game control means or the like. Point to each. A substrate on which a microcomputer other than the main substrate 31 is mounted may be referred to as a sub-substrate.

  On the back surface of the pachinko machine 1, a terminal board (not shown) provided with terminals for outputting various information to the outside of the pachinko machine 1 is installed above. On the terminal board, at least a ball break terminal for introducing the output of the ball break detection switch 167 and outputting it externally, a terminal for a prize ball for outputting prize ball information (prize ball number signal) and a ball lending A ball lending terminal for externally outputting information (ball lending number signal) is provided. Near the center, an information terminal board (information output board) 36 provided with terminals for outputting various information from the main board 31 to the outside of the pachinko machine 1 is installed.

  Pachinko balls stored in a ball tank 38 capable of storing balls supplied from an unillustrated gaming machine installation island, pass through the tank rail, and reach a ball dispensing device 97 covered with a case cover through a curve rod. The ball path 761 above the ball payout device 97 is provided with a ball break detection switch 167 as a game medium break detection means for detecting that there is no ball in the passage. When the ball break detection switch 167 detects a ball break, the payout operation of the ball payout device 97 is stopped. The ball break detection switch 167 is a switch for detecting the presence or absence of a pachinko ball in the pachinko ball passage. When the ball break detection switch 167 detects a shortage of pachinko balls, the pachinko balls 1 are replenished from the replenishment mechanism provided on the gaming machine installation island.

  When a large number of pachinko balls as prizes based on winning prizes or pachinko balls based on ball lending requests are paid out and the upper plate 3 is full, the pachinko balls are guided to the lower plate 4 through an overflow ball passage described later. When the pachinko ball is further paid out, the switch piece (not shown) presses the full tank switch 19 (see FIG. 3) as the storage state detection means, and the full tank switch 19 as the storage state detection means is turned on. In this state, the rotation of the payout motor in the ball payout device is stopped, the operation of the ball payout device is stopped, and the driving of the ball hitting device is also stopped.

  FIG. 3 is a block diagram illustrating an example of a circuit configuration in the main board 31. 3 also shows a payout control board 37, a relay board 77, and an effect control board 80 mounted on the pachinko machine 1. The main board (game control board) 31 includes a game control microcomputer 156 serving as a basic circuit (corresponding to game control means) for controlling the pachinko machine 1 according to a program, a gate switch 32a, a first start port switch 14a, Input that gives various signals such as a power-off signal and a clear signal to the game control microcomputer 156 in addition to signals from the second start port switch 14b, the count switch 23, the first winning port switch 29a, and the second winning port switch 30a. The circuit 68, the solenoid 16 that opens and closes the movable pieces 13 and 13 of the start winning device 15, the solenoid 21 that opens and closes the special variable winning ball device 20, and the solenoid 21a for switching the path in the special winning opening are micro-game control. An output circuit 69 driven in accordance with a command from the computer 156; It has been mounting.

  The game control microcomputer 156 includes a ROM 54 for storing a game control (game progress control) program and the like, a RAM 55 as storage means (variation data storage means for storing fluctuation data) used as a work memory, and a program. Therefore, it includes a CPU 56 that is a processor that performs a control operation, and an I / O port 57. The game control microcomputer 156 is a one-chip microcomputer.

  In the game control microcomputer 156, the CPU 56 executes control according to a program stored in the ROM 54. Therefore, the execution (or processing) of the game control microcomputer 156 as described below specifically means that the CPU 56 executes control according to a program. The same applies to microcomputers mounted on substrates other than the main substrate 31. The game control means is realized by a game control microcomputer 156 including a CPU 56.

  The game control microcomputer 156 includes a clock circuit that generates a clock signal, a reset controller that functions as a system reset means, a random number circuit, and a CTC that sends an interrupt request signal to the CPU 56.

  The random number circuit is a hardware circuit that is used to generate a random number for determination to determine whether or not to win a jackpot based on the display result of the variation display of the special symbol and the decorative symbol. The random number circuit updates numerical data in accordance with a set update rule within a numerical range in which an initial value (for example, 0) and an upper limit value (for example, 65535) are set, and at random timing. Based on the fact that the start winning time generated is the time of reading (extracting) the numerical data, it has a random number generation function in which the numerical data to be read becomes a random value.

  The game control microcomputer 156 reads the numerical data from the random number circuit as the random number value R1 when a start winning to the first starting port switch 14a or the second starting port switch 14b occurs, and specifies a specific value based on the numerical data. It is determined whether or not to make a jackpot display result as a display result, that is, whether or not to make a jackpot. When it is determined that the game is a big hit, the gaming state is shifted to a big hit gaming state as a specific gaming state advantageous to the player. The determination as to whether or not to win is actually executed based on the random number value extracted at the time of starting winning at the start of the variation display of the special symbol and the decorative symbol. Whether the random number generated by the random number circuit is a big hit, such as a random number for probability variation determination for determining whether or not to make a probability variation, and a random number for variation pattern determination for determining a variation pattern of a special symbol. It may be used as a random number for determination other than determination.

  In addition, as shown in FIG. 21, a reserved memory display unit that performs the same display as the display of the special symbol reserved memory display 18 is provided in a predetermined area of the variable display device 9 so that the player can change the status of the reserved memory. In order to make it easy to grasp, the determination as to whether or not to make a big hit, the determination as to whether it is a super reach, or the like is performed at the time of starting winning a prize, the determination result is notified to the effect control board 80, and the effect control board 80 It is possible to grasp in which held memory a big hit occurs and whether a super reach occurs, and change the display mode of the held memory that grasps the occurrence of the big hit and super reach to the normal display mode. Thus, a hold notice effect that suggests in advance to the player that there is a high possibility of a big hit or a super reach may be implemented.

  The clock circuit outputs a system clock signal to the CPU 56, and outputs a reference clock signal CLK having a predetermined period generated by dividing the system clock signal to each random number circuit. When a low level signal is input for a certain period, the reset controller outputs a predetermined initialization signal to the CPU 56 and each random number circuit to reset the game control microcomputer 156 as a system.

  The RAM 55 is a backup RAM as a volatile storage means that is partially or wholly backed up by a backup power source created on the power supply board 960. That is, even when the power supply to the pachinko machine 1 is stopped, even when the power supply is cut off, a predetermined period (until the capacitor as the backup power supply is discharged and the backup power supply cannot be supplied) or a part of the RAM 55 All contents are saved. In particular, at least data corresponding to the control state of the game (special symbol process flag or the like) and data indicating the number of unpaid prize balls are stored in the RAM 55 as backup data. The data corresponding to the control state is data necessary for restoring the control state before the occurrence of a power failure or the like based on the data when the power is restored after a power failure or the like.

  Further, a power-off signal indicating that the power supply voltage from the power supply board 960 has dropped below a predetermined value is input to the input circuit 68. The power-off signal is input to the input port of the game control microcomputer 156 via the input circuit 68. A clear signal indicating that a clear switch for instructing to clear the contents of the RAM is operated is input to the input circuit 68 at the input port of the game control microcomputer 156. The clear signal is input to the input port of the game control microcomputer 156 via the input circuit 68.

  Each of the plurality of switches is connected to the input port of the game control microcomputer 156 via the input circuit 68. Thereby, the game control microcomputer 156 receives an input detection signal indicating the input state of each switch from each of the plurality of switches.

  Further, the output circuit 78 mounted on the game control microcomputer 156 transmits the effect control command output by the CPU 56 to the effect control board 80 via the relay board 77. Further, the output circuit 78 outputs a control signal output from the CPU 56 to the special symbol display 8, the special symbol hold storage display 18, the normal symbol display 10, and the normal symbol hold storage display 41 via the relay board 77. Then, it is supplied to the special symbol display 8, the special symbol hold storage display 18, the normal symbol display 10, and the normal symbol hold storage display 41 through the relay board 77.

  The game control microcomputer 156 transmits an effect control command (effect control signal) as a control signal for instructing effect control including display control, sound control, and LED control to the effect control board 80.

  The effect control commands transmitted to the effect control board 80 by the game control microcomputer 156 include a designation command, a variable display command, and a lottery result designation command even when waiting for a customer.

  The customer waiting demonstration designation command is an effect control command (customer waiting demonstration designation command) for designating the display during the customer waiting demonstration by the game control microcomputer 156, and a predetermined time has elapsed after the change of the special symbol is finished. When the customer waiting demo designation command is sent to the effect control board 80, a predetermined customer waiting demo screen is displayed on the variable display device 9. In other words, normally, when a player changes, there is a period in which the player is absent, so it is assumed that these waiting-for-demo demonstration designation commands are due to the player changing. When it is output.

  The variable display command is an effect control command that is transmitted at the start of variation in order to specify a variation pattern of a decorative symbol that is variably displayed on the variation display device 9 in response to variable display of a special symbol. Is a command to specify.

  In addition, the lottery result designation command notifies the effect control board 80 of the lottery result based on the random number value (the lottery result such as the big hit or the big hit type in the case of the big win) at the start of the variable display. The production control board 80 uses the lottery result notified by the lottery result designation command as the display result of the variable display device 9 so that the three decorative symbols are not aligned. Or, it is determined whether the display result is a normal jackpot display result (for example, a display result with even-numbered decorative symbols) or a probabilistic big hit display result (for example, a display result with odd-numbered decorative symbols).

  The effect control board 80 receives an effect control command from the game control microcomputer 156 via the relay board 77, and performs display control of effect display on the variable display device 9 and output control of sound effects (effect sound). Electric component control means such as a microcomputer 81 for effect control to be performed is mounted.

  In this embodiment, the effect control microcomputer 81 mounted on the effect control board 80 receives the effect control command from the game control microcomputer 560 via the relay board 77 and variably displays the decorative symbols. Display control of the display device 9 and sound output control from the speakers 27L, 27R, 27a, and 27b are performed.

  Further, the effect control microcomputer 81 mounted on the effect control board 80 detects detection signals from the lever switches 510a to 510d, the button switch 516a, and the parallax number change switches 517a and 517b. The operation or operation of the operation button 516 by the player or the operation of the parallax number change button 517 is detected.

  In addition, the production control microcomputer 81 performs display control of the stage LED 25b provided on the game board 6, and the prize ball LED 51, the ball cut LED 52, the left frame LED 28b, the right frame LED 28c provided on the frame side, Moreover, lighting control of each LED in the top lamp module 530 is performed.

  As shown in FIG. 4, the effect control board 80 includes an effect control microcomputer 81 including an effect control CPU 86 and a RAM 85. In the effect control board 80, the effect control CPU 86 operates in accordance with a program stored in the built-in ROM 84, and receives an effect control command via the input circuit 260. Among these, the ROM 84 includes a time chart (see FIGS. 13 and 14) and a 3D display stop period determination that can specify the cancellation of the stereoscopic image display, the changeable period of the number of parallaxes, the non-changeable period, and the like in each effect described later. A table (see FIG. 16) is stored, and a cancel counter (not shown) is stored in the RAM 85. Further, the effect control CPU 86 performs display control processing for causing the VDP (video display processor) 262 to perform display control of the variable display device 9 such as generation of an image to be displayed on the variable display device 9 based on the effect control command. carry out.

  In this embodiment, a VDP 262 that performs display control of the variable display device 9 in cooperation with the effect control microcomputer 81 is mounted on the effect control board 80.

  As shown in FIG. 4, the VDP 262 is an image data ROM 263 in which data such as characters (image data such as persons, animals, characters, figures, symbols, etc., or CG data) as image element data used as sprite images is stored. A display control circuit is configured together with an SDRAM 210 (synchronous DRAM) used as a VRAM (video RAM) area and a parallax image generation unit 264 including a parallax image generation IC for generating a parallax image.

  In the image data ROM 263, in addition to data for generating a two-dimensional image such as image element data used as a sprite image, a stereoscopic image for one screen (full screen) is provided for each predetermined number of parallaxes of the image liquid crystal panel 9a. Corresponding image data generated in advance is stored.

  In this embodiment, among the stereoscopic images for one screen (full screen), a parallax image corresponding to a predetermined subpixel (in this embodiment, a parallax image of the subpixel p5 at the center position) is converted into a non-stereo image. By storing the image data of these stereoscopic images, the image data corresponding to the non-stereo images is also stored, and the storage capacity can be reduced.

  In addition, the image data ROM 263 does not store image data of all stereoscopic images displayed on the image liquid crystal panel 9a, but it is difficult to generate parallax images constituting the stereoscopic image, for example, parallax Only what is used in the case of including display of different contents depending on the difference in direction is stored, and other stereoscopic images (parallax images) are stored by the parallax image generation unit 264 as described later. It is generated by generating each parallax image from a stereoscopic image.

  The effect control CPU 86 reads out necessary data from the image data ROM 263 storing the two-dimensional (2D) image data and the stereoscopic (3D) image data for displaying the stereoscopic (3D) image in accordance with the received effect control command. Is output to the VDP 262. As described above, the image data ROM 263 stores character image data and moving image data displayed on the variable display device 9, specifically, people, characters, figures, symbols, etc. (including decorative designs), and background images. It is a ROM for storing two-dimensional or three-dimensional image data in advance. The VDP 262 reads out image data from the image data ROM 263 in response to a command from the effect control CPU 86. The VDP 262 performs display control based on the read image data.

  The VDP 262 is a system register 202 that stores various settings of the VDP 262, and attributes (parameters used when drawing the character. The drawing order of the character, the number of colors, the scaling ratio, the palette number, the coordinates, etc. Attribute register 203 for storing (designated data), a drawing control unit 206 for controlling drawing of an image in a drawing area (to be described later) of the VRAM area, and a control or drawing area for transferring CG data stored in the CGROM 205 to the VRAM area A data transfer control unit 211 that performs control to transfer the two-dimensional image drawn on the parallax image generation unit 264 and control to transfer the parallax image generated by the parallax image generation unit 264 to the VRAM region; Video signal for displaying image data stored in the area The display control unit 213 that outputs the R (red), G (green), and B (blue)) signals and the synchronization signal, and the video signal output from the display control unit 213 is converted into an analog signal to form the variation display device 9 This is an integrated circuit on which DA converters 214, 215, etc. for outputting to the image liquid crystal panel 9a are mounted.

  A system bus and a CG bus are provided inside the VDP 262. The system bus and the CG bus are connected to the CPU 86 of the effect control microcomputer 81 via the CPU interface 201, and the CG bus is a CG bus interface. It is connected to the image data ROM 263 via 204. The CG bus is connected to the parallax image generation unit 264 and the parallax image generation IC via the IC interface 205. A system register 202 is connected to the system bus, and an attribute register 203 is connected to the CG bus, so that the CPU 86 can access the system register 202 and the attribute register 203.

  The drawing control unit 206, the data transfer control unit 211, and the display control unit 213 are connected to the system bus so that the system register 202 can be accessed. The drawing control unit 206 and the data transfer control unit 211 are connected to the CG bus, and can access the image data ROM 263 and the attribute register 203.

  Further, a VRAM bus is further provided inside the VDP 262, and the VRAM bus is connected to the SDRAM 210 via the VRAM bus interface 209. A drawing controller 206, a data transfer controller 211, and a display controller 213 are connected to the VRAM bus so that the VRAM area of the SDRAM 210 can be accessed via the VRAM bus.

  The system register 202 includes a system control register for storing instructions such as initial setting, drawing, and data transfer, an interrupt control register for storing an output instruction for an interrupt signal to be described later, a drawing area in the VRAM area, and arrangement of palette data. A drawing register for storing an area and the like, a data transfer register for storing a transfer source address and a transfer destination address at the time of data transfer, a display register for storing a display area in the VRAM area, and the like are allocated.

  The CPU interface 201 outputs a V blank interrupt signal to the CPU 86 at every start of V blank (an image update period), and outputs various other interrupt signals to the CPU 86.

  The display control unit 213 performs display processing for outputting image data of the display area of the VRAM area specified by the display register as a video signal. In this embodiment, the display area and the drawing area are switched every V blank. For this reason, the area assigned as the drawing area in a certain V blank is drawn, and in the next V blank, the display area is switched, so that the image data drawn in the previous V blank is displayed and output. In the meantime, drawing is performed in the other area.

  The non-stereoscopic image display performed by the display control unit 213 will be described in detail. The display control unit 213 generates a two-dimensional image (non-stereoscopic image) or image data in response to a command from the effect control CPU 86. The parallax image data of a predetermined sub-pixel of the stereoscopic image is read from the ROM 263, and this image data is displayed as a non-stereo image in a single band display area of the image liquid crystal panel 9a (see FIG. 8B).

  Next, the display of the stereoscopic image stored in the image data ROM 263 will be described in detail. The display control unit 213 corresponds to the stereoscopic image of the image liquid crystal panel 9a from the image data ROM 263 in response to a command from the effect control CPU 86. The image data to be read is read, and each parallax image included in the read image data is displayed on the sub-pixel of each pixel.

  By doing so, the sub-pixel of each pixel is an image at a position corresponding to the pixel, and a parallax image from each line-of-sight direction is displayed, so that the player can visually recognize the left and right eyes. Due to the difference, different parallax images are visually recognized by the left and right eyes, so that the image displayed on the image liquid crystal panel 9a is visually recognized as a stereoscopic image. The same applies to a stereoscopic image composed of parallax images generated from a non-stereo image by the parallax image generation unit 264.

  FIG. 5 is a diagram showing the configuration of the VRAM area of the SDRAM 210 in this embodiment. The VRAM area includes a palette area in which palette data is arranged, a character buffer in which necessary characters are read from the image data ROM 263 and stored, and palette data (character display) when the drawing control unit 206 draws an image. Each area such as a CG buffer for temporarily storing CG data is allocated to temporarily store (data in which color is defined) and when the drawing control unit 206 draws an image.

  In the VRAM area, there is a non-stereo image display area in which image data based on a non-stereo image displayed on the image liquid crystal panel 9a is stored, and image data based on a non-stereo image displayed on the image liquid crystal panel 9a. A non-stereoscopic image drawing area to be drawn is assigned. These non-stereoscopic image display area and non-stereoscopic image drawing area are switched every V blank. For this reason, image data of a non-stereo image is drawn in an area assigned as a non-stereo image drawing area in a certain V blank, and this area is switched to a non-stereo image display area in the next V blank. The image data of the non-stereo image drawn in the previous V blank is displayed and output as a non-stereo image on the image liquid crystal panel 9a, and the image data is drawn in the other region during that time.

  Further, in the VRAM area, a stereoscopic image display area in which image data based on the stereoscopic image displayed on the image liquid crystal panel 9a is stored, and image data based on the stereoscopic image displayed on the image liquid crystal panel 9a are drawn. A stereoscopic image drawing area is allocated. The three-dimensional image display area and the three-dimensional image drawing area are switched every V blank. For this reason, in the area assigned as the stereoscopic image drawing area in a certain V blank, the image data of the stereoscopic image is drawn, and in the next V blank, this area is switched to the stereoscopic image display area. The image data of the stereoscopic image drawn in the blank is displayed and output as a stereoscopic image on the image liquid crystal panel 9a, and the image data of the non-stereo image is drawn in the other area during that time.

  As described above, the non-stereo image display area and the non-stereo image drawing area, the stereo image display area and the stereo image drawing area, respectively, draw image data in one area and image data in the other area for each V blank. By alternately displaying images on the image liquid crystal panel 9a as an image, the drawing control unit 206 of the present embodiment can perform drawing processing on the non-stereoscopic drawing area and the stereoscopic image drawing area in parallel. In addition, the display control unit 213 displays the image data of the non-stereoscopic image display area on the image liquid crystal panel 9a as a non-stereoscopic image, or uses the stereoscopic image data of the stereoscopic image display area as a stereoscopic image. It is possible to display on the liquid crystal panel 9a.

  As described above, the production control CPU 86 can access the system register 202 and the attribute register 203 via the CPU interface 201, and these systems are in accordance with the process data that defines the display pattern of the variable display device 9 described above. By storing execution instructions and necessary data in the register 202 and the attribute register 203, the VDP 262 is indirectly controlled.

  In the process data, the setting contents that the effect control CPU 86 performs on the system register 202 and the attribute register 203 are determined for each V blank. The setting contents of the system register 202 include drawing, data transfer commands, CG data and palette data for performing data transfer, and attribute settings. The setting contents of the attribute register 203 are attributes, that is, parameters used when drawing a character.

  In the process data, an attribute is set so that the image is updated every V blank. For this reason, the image is updated every V blank.

  Next, drawing control of a two-dimensional image (non-stereo image) in the present embodiment will be described. In order for the drawing control unit 206 to perform the drawing process, it is necessary that characters necessary for drawing be arranged in the VRAM area. In other words, it is necessary to place a character serving as source data of the sprite image in the VRAM area.

  For this reason, when the effect control CPU 86 executes the effect, it issues a transfer command from the image data ROM 263 to the VRAM area for all the characters necessary to execute the effect. As a result, the data transfer control unit 211 arranges all the characters necessary for the performance in the VRAM area. When performing an effect, the same character is often used for drawing repeatedly, but the data stored in the image data ROM 263 is compressed, and it takes time to read it. In this way, by placing all necessary characters in the VRAM area at the initial stage of performing the rendering, the time required for drawing can be reduced compared to reading data from the image data ROM 263 for each frame. It becomes. In this embodiment, when the effect control CPU 86 executes the effect, a transfer command from the image data ROM 263 to the VRAM area for all the characters necessary for the reproduction of the moving image is executed. A necessary character transfer command may be issued each time.

  Further, in order for the drawing control unit 206 to perform drawing processing, it is necessary to set an attribute in the attribute register 203. Since the attribute is different for each V blank, the attribute according to the process data is stored in the attribute register 203 for each V blank.

  Then, after starting the production, the production control CPU 86 sets an attribute in the attribute register 203 for each V blank, and then commands execution of reading of the attribute. Along with this, the drawing control unit 206 reads the attribute of the attribute register 203 and instructs the output of the reading end interrupt signal when the reading is completed. In response to this, the effect control CPU 86 commands execution of drawing, and the drawing control unit 206 draws image data in the non-stereoscopic image drawing area in accordance with the read attribute.

  When generating a stereoscopic image of a non-stereo image drawn in these non-stereo image drawing areas, the drawn non-stereo image is transferred to the parallax image generation unit 264 to generate a parallax image, and the generation A stereoscopic image composed of the parallax images thus transferred is transferred and drawn in the stereoscopic image drawing area.

  In this way, since the image drawing area and the image display area are separate for the stereoscopic image and the non-stereo image, the image drawing area and the image display area are more common in the stereoscopic image and the non-stereo image described above. A transition from a non-stereo image to a stereo image or a transition from a stereo image to a non-stereo image can be performed quickly.

  As shown in FIG. 8A and FIG. 9A, the display control unit 213 is a stereoscopic image that is a different parallax image for each of the nine sub-pixels p1 to p9 in response to a command from the effect control CPU 86. By displaying the images A to I, a stereoscopic image with a maximum of 9 parallaxes can be displayed on the image liquid crystal panel 9a, but it is the same as a predetermined plurality of subpixels among the nine subpixels p1 to p9. By displaying the image data, it is possible to display parallax images having different predetermined numbers of parallaxes.

  More specifically, as shown in FIG. 9B, for example, the display control unit 213 displays the same stereoscopic image B on the subpixels p1 and p2 on one end side and the subpixel on the other end side. By displaying the same stereoscopic image H on p8 and p9 and displaying the stereoscopic images C to G, which are different parallax images, on the other central subpixels p3 to p7, the total number of parallaxes is 7 parallaxes. The parallax image can be displayed on the image liquid crystal panel 9a.

  For example, as shown in FIG. 9C, the display control unit 213 displays the same stereoscopic images C and D on the subpixels p1, p2, and p3 and p4 on one end side, and the other end. By displaying the same stereoscopic images F and G on the subpixels p6, p7, p8, and p9 on the side, and displaying the stereoscopic image E that is a different parallax image on the central subpixel p5, the number of parallaxes is 5 as a whole. A parallax image that is parallax can be displayed on the image liquid crystal panel 9a.

  Alternatively, for example, as illustrated in FIG. 9D, the display control unit 213 displays the same stereoscopic image D on the one-side subpixels p <b> 1 to p <b> 3 and the same on the center-side subpixels p <b> 4 to p <b> 6. The stereoscopic image E is displayed, and the same stereoscopic image F is displayed on the other end side sub-pixels p7 to p9, so that a parallax image having a parallax number of 3 as a whole is displayed on the image liquid crystal panel 9a. be able to.

  That is, the display control unit 213 according to the present exemplary embodiment controls the parallax image displayed on each sub-pixel, thereby converting the stereoscopic image into an image liquid crystal with different parallax numbers of 3 parallax, 5 parallax, 7 parallax, and 9 parallax. It can be displayed on the panel 9a.

  Next, the parallax number setting operation performed by the player will be described. Regardless of whether the pachinko machine 1 is producing effects, the effect control CPU 86 can accept a parallax number setting change operation by the parallax number change button 517.

  As illustrated in FIG. 10, for example, when the number of parallaxes of the stereoscopic image before setting is “3 parallax”, the player presses the plus button of the parallax number change button 517 once to perform “5 parallax”. The setting is changed to. Similarly, when the number of parallaxes is “5 parallax”, the setting is changed to “7 parallax” by pressing the plus button of the parallax number changing button 517 once, and the number of parallaxes is “7 parallax”. In this case, the setting is changed to “9 parallax” by pressing the plus button of the parallax number changing button 517 once.

  Further, for example, when the parallax number of the stereoscopic image before setting is “9 parallax”, the player changes the setting to “7 parallax” by pressing the minus button of the parallax number changing button 517 once. Similarly, when the number of parallaxes is “7 parallax”, the setting is changed to “5 parallax” by pressing the minus button of the parallax number changing button 517 once, and the number of parallaxes is “5 parallax”. In this case, the setting is changed to “3 parallax” by pressing the minus button of the parallax number changing button 517 once.

  In the present embodiment, the display control unit 213 displays a stereoscopic image having only the desired number of parallaxes set by the above-described operation. For example, the display control unit 213 sets the display mode of the pachinko machine 1 as an effect. Accordingly, a stereoscopic image having a predetermined number of parallaxes may be temporarily displayed within a range that does not exceed the set desired number of parallaxes and does not place a burden on the player. More specifically, for example, when “7 parallax” is set, a stereoscopic image of “3 parallax” or “5 parallax” may be temporarily displayed.

  Furthermore, even if the set number of parallaxes is any of “3 parallax”, “5 parallax”, “7 parallax”, or “9 parallax”, by pressing the operation button 516, The setting is changed so that stereoscopic image display with the number of parallaxes is canceled and a non-stereoscopic (2D) image is displayed.

  In this way, the player designates his / her favorite number of parallaxes with the parallax number change button 517 so that a parallax image with the designated number of parallaxes is displayed on the sub-pixel. A stereoscopic image with the number of parallaxes according to preference can be displayed.

  In particular, the player gains and loses interest and burden on his eyes (if the number of parallaxes is large, the interest is increased, but the image changes with a little movement, so the eyes are likely to get tired, while the number of parallaxes If there is little, the interest can be suppressed, but the image does not change even if it moves a little, so the eyes are hard to get tired), so you can select the desired number of parallaxes, so you can play while suppressing your own eye strain I can enjoy it.

  Further, when the player wants to stop displaying the stereoscopic image displayed in each effect during the game, the player can operate the operation button 516 to stop the display of the stereoscopic image. The player can play the game by stopping the display of the stereoscopic image and switching to the display of the non-stereo image during the game.

  The display control unit 213 is not necessarily limited to displaying a stereoscopic image on all nine subpixels p1 to p9. For example, an imaging unit 11 (see FIG. 24) having an infrared imaging unit 11b that images a player with infrared radiation unit 11a and infrared light emitted from the infrared radiation unit 11a at a predetermined position on the front surface of the pachinko machine 1. In addition, a position detection processing unit (not shown) that specifies the position of the player from the infrared image captured by the imaging unit 11 is provided, and the display control unit 213 responds to a command from the effect control CPU 86 with nine sub-pixels p1 to p1. Among p9, the nth display target subpixel p (n) that can be viewed from the viewpoint position of the player in the left-right direction specified by the position detection processing unit and the subpixel adjacent to both sides of the display symmetric subpixel p (n) Control is performed to display a stereoscopic image (parallax image) on p (n−1) and p (n + 1), and the remaining pixels excluding these subpixels p (n), p (n−1), and p (n + 1) Subpixel Hide (if non-display state is black, if the non-display state is transparent black display) may be performed control to.

  In this way, in the image liquid crystal panel 9a constituting the stereoscopic image display device, a parallax image is displayed on a display target subpixel that is a part of the subpixels, while a parallax is displayed on subpixels other than the display target subpixel. Since no image is displayed, it is possible not only to reduce the occurrence of interference fringes caused by the interference of parallax image light with each other, but also to display the parallax displayed on each subpixel, as compared to displaying parallax images on all subpixels. When an image is generated, the processing load for generating the parallax image can be reduced.

  The positions of the display target sub-pixels that display these three-dimensional images (parallax images) are sequentially changed as will be described later in accordance with changes in the viewpoint position of the player specified by the position detection processing unit.

  In this way, by changing the display target sub-pixel in time series according to the change in the position of the player, the player side does not need to change the viewpoint position in accordance with the display. However, the present invention is not limited to this, and these display target sub-pixels do not change in time series according to the change in the player's viewpoint position, so that only the same sub-pixel displays a parallax image in a fixed manner. The player side may change the viewpoint position in accordance with the display.

  In addition, the display control unit 213 is not limited to the individual display of the stereoscopic images A to I that are parallax images corresponding to the sub pixels p1 to p9 as described above. For example, among the sub pixels p1 to p9, Control to assign and display the same stereoscopic image to some subpixels adjacent to each other, or display the same stereoscopic image to some subpixels in this way and hide other subpixels or display black By performing the control, it is possible to change the number of display images and the number of parallax images of the subpixels p1 to p9. Hereinafter, a specific example will be described with reference to FIG.

  A display mode in the case where the number of parallax images is 3 is illustrated.

  For example, as illustrated in FIG. 23A, the display control unit 213 corresponds to an image of a display object viewed from the position directly in front of the three subpixels p4 to p6 on the center side among the nine subpixels p1 to p9. Display the same stereoscopic image E, which is a parallax image to be displayed, and three subpixels p1 to p3 and subpixels p7 to p9 on each of the left and right sides of the subpixels p4 to p6. By performing control to display the same stereoscopic image D and stereoscopic image F that are parallax images corresponding to images, the number of parallaxes of the stereoscopic image can be substantially changed from 9 parallaxes to 3 parallaxes.

  Further, for example, as illustrated in FIG. 23B, the display control unit 213 displays an image of a display object viewed from the frontal position on the three sub pixels p4 to p6 on the center side among the nine sub pixels p1 to p9. Display the same stereoscopic image E, which is a parallax image corresponding to, and two subpixels p2 and p3 and subpixels p7 and p8 on the left and right sides of the subpixels p4 to p6. The same stereoscopic image D and stereoscopic image F, which are parallax images corresponding to the image of the object, can be displayed, respectively, and the other subpixels p1 and p9 at the left and right ends can be controlled to be non-displayed or displayed black.

  Further, for example, as illustrated in FIG. 23C, the display control unit 213 displays the parallax corresponding to the image of the display object viewed from the frontal position on the central subpixel p5 among the nine subpixels p1 to p9. A stereoscopic image E as an image is displayed, and a parallax image corresponding to an image of a display object viewed from each of the left and right sides is displayed on each of two subpixels p3 and p4 and subpixels p6 and p7 on each of the left and right sides of the subpixel p5. The same three-dimensional image D and three-dimensional image F can be displayed, and the other subpixels p1, p2 and subpixels p8, p9 on the left and right ends can be controlled to be non-displayed or displayed black.

  Next, a specific example of controlling display / non-display of each of the subpixels p1 to p9 based on the left and right positions of the player specified by the position detection processing unit described above will be described.

  In response to the instruction from the effect control CPU 86, the display control unit 213 sets a predetermined sub-pixel corresponding to the left-right viewpoint position of the player identified by the position detection processing unit among the nine sub-pixels p1 to p9. What is necessary is just to perform control which displays the three-dimensional image by which the three-dimensionality was defined according to the player's viewpoint position.

  More specifically, in the display control unit 213, for example, as shown in FIG. 24A, the viewpoint position of the player specified by the position detection processing unit is located at the approximate center in the left-right direction with respect to the pachinko machine 1. In this case, the display control unit 213, among the nine subpixels p1 to p9, can display the central display target subpixel p5 and the display symmetric subpixel p5 that can be viewed from the central viewpoint position of the player specified by the position detection processing unit. Are controlled to display stereoscopic images D, E, and F, which are parallax images corresponding to the viewing position, on the adjacent subpixels p4 and p6, and the remaining subpixels excluding these subpixels p4 to p6 are non-displayed. Control the display.

  Also, as shown in FIG. 24B, the display control unit 213 performs display control when the viewpoint position of the player specified by the position detection processing unit is located on the left side in the left-right direction with respect to the pachinko machine 1. The unit 213 displays parallax images corresponding to the viewing positions on the three display target subpixels p1 to p3 that can be viewed from the viewpoint position on the left side of the player identified by the position detection processing unit among the nine subpixels p1 to p9. Control is performed to display certain stereoscopic images A, B, and C, and control is performed to hide the remaining subpixels excluding these subpixels p1 to p3.

  Further, as shown in FIG. 24C, the display control unit 213 performs display control when the viewpoint position of the player specified by the position detection processing unit is located on the right side in the horizontal direction with respect to the pachinko machine 1. The unit 213 displays parallax images corresponding to the viewing positions on the three display target subpixels p7 to p9 that can be viewed from the viewpoint position on the right side of the player identified by the position detection processing unit among the nine subpixels p1 to p9. Control to display a certain stereoscopic image G, H, and I is performed, and control to hide the remaining subpixels excluding these subpixels p7 to p9 is performed.

  In addition, the display control unit 213 selects a predetermined sub-pixel corresponding to the viewpoint position in the front-rear direction of the player identified by the position detection processing unit among the nine sub-pixels p1 to p9 in response to the instruction from the effect control CPU 86. Then, control is performed to display a stereoscopic image in which the stereoscopic degree is determined in accordance with the viewpoint position of the player.

  More specifically, for example, as shown in FIG. 25A, the display control unit 213 is configured such that the player's viewpoint position specified by the position detection processing unit is separated by a relatively close distance from the pachinko machine 1. Displays a parallax image on some of the nine subpixels p1 to p9 and three subpixels p4 to p6 in the center, and for example, as shown in FIG. When the position is separated from the pachinko machine 1 by a relatively long distance, a parallax image is displayed on more subpixels than the above-mentioned number of subpixels, for example, all nine subpixels p1 to p9. That is, control is performed to change the parallax number of the stereoscopic image so as to be proportional to the separation distance between the player and the pachinko machine 1.

  In this way, even if the player moves in the left-right direction or the front-rear direction during the game, the sub-pixel or sub-pixel group corresponding to the moved position is specified as the display target sub-pixel, and the display target sub-pixel is Since the parallax image is displayed, it is possible to display a good stereoscopic image with less interference fringes corresponding to the position change of the player.

  In addition, in this way, the stereoscopic image can be appropriately changed in accordance with the position of the player, for example, the perspective, etc., and the stereoscopic display can be performed according to the position of the player.

  In particular, when the player's viewpoint position specified by the position detection processing unit is close to the pachinko machine 1, the display control unit 213 displays a stereoscopic image with a low stereoscopic degree, and the player's viewpoint position is relative to the pachinko machine 1. When the player is far away, by displaying a stereoscopic image having a high stereoscopic degree, the stereoscopic degree of the stereoscopic image is changed so as to be proportional to the distance between the player and the pachinko machine 1, so that the player can Even if they are far away, the presence of the stereoscopic image can be enhanced according to the distance.

  Further, in this embodiment, not only the entire display area of the image liquid crystal panel 9a is displayed only as a three-dimensional (3D) image or a two-dimensional (2D) image, but for example, as shown in FIG. A stereoscopic (3D) image is displayed on the left half display area (first display area) of the liquid crystal panel 9a, and a two-dimensional (2D) image is displayed on the right half display area (second display area) of the image liquid crystal panel 9a. By displaying, a two-dimensional (2D) image and a stereoscopic (3D) image can be displayed simultaneously.

  That is, the image liquid crystal panel 9a includes a left half display area (first display area) for displaying a stereoscopic (3D) image and a right half display area (second display area) for displaying a two-dimensional (2D) image. The effect control CPU 86 generates a stereoscopic (3D) image and a two-dimensional (2D) image in the left half display area (first display area) and the right half display area (second display area). Control to display at the same time.

  That is, as in the present embodiment, when the display area of the variable display device 9 is a rectangle that is long in the horizontal direction, the left and right display areas are provided by increasing the distance between the center positions of the display areas. Even if a stereoscopic (3D) image and a two-dimensional (2D) image are displayed in the display area at the same time, it is possible to reduce the possibility that the player will visually recognize the stereoscopic (3D) image and the two-dimensional (2D) image at the same time. Therefore, it is possible to reduce the difficulty of visually recognizing the stereoscopic (3D) image by simultaneously viewing the stereoscopic (3D) image and the two-dimensional (2D) image. ) When displaying an image and a two-dimensional (2D) image at the same time, a display area is provided on the left and right sides of the horizontally long display area, and a stereoscopic (3D) image and a two-dimensional (2D) image are displayed. It is preferable to display.

  In the case where these three-dimensional (3D) image and two-dimensional (2D) image are displayed simultaneously, a three-dimensional (3D) image is provided by providing a relatively wide black display area at the boundary of the display area on the left and right. And the possibility of simultaneously viewing a two-dimensional (2D) image may be reduced.

  Further, as shown in FIG. 11, a stereoscopic (3D) image and a two-dimensional (2D) image are simultaneously displayed in the left half display area (first display area) and the right half display area (second display area). When displaying, a display body displayed in a three-dimensional (3D) image, for example, a decorative pattern or the speed of movement of a character (moving speed) is displayed on a display body displayed in a two-dimensional (2D) image, such as a decorative pattern or character. By generating and displaying a stereoscopic image (parallax image) so as to be slower than the speed of movement (moving speed), the moving speed of the display body can be changed between a stereoscopic (3D) image and a two-dimensional (2D) image. Therefore, compared with the same case, it is possible to reduce the player from feeling uncomfortable by visually recognizing a fast-acting stereoscopic (3D) image.

  Further, in this embodiment, during the customer waiting demonstration, an inter-island passage formed between the gaming machine installation island where the pachinko machine 1 is installed and the gaming machine installation island facing the gaming machine installation island is passed. A stereoscopic (3D) image for demonstration that can be stereoscopically viewed well at the viewpoint position of a passerby who is a player is displayed.

  As for the stereoscopic (3D) image display for demonstration, the production control board 80 receives the customer waiting demonstration designation command from the game control microcomputer 156 and moves to the customer waiting demonstration state, and then the PR ( Introduction) A predetermined customer-waiting demo image consisting of an image or the like is displayed on the image liquid crystal panel 9a. In the present embodiment, the effect control board 80 performs control to display all the subpixels p1 to p9 as the customer waiting demo image. In this way, a waiting-for-customs demonstration in which a good stereoscopic (3D) image can be seen in a wider viewing angle from various viewpoint positions of a player traveling through an inter-island passage that is farther than the player of the pachinko machine 1 By changing to an image, a player passing through an island passage can visually recognize a demo image waiting for a customer with a good stereoscopic image.

  In this way, at the time of a customer-waiting demonstration in which no player is present in the pachinko machine 1, it is possible to see a good stereoscopic (3D) image from the viewpoint position of the passer-by over a wider viewing angle. In contrast, the pachinko machine 1 can exert an effect of arousing a willingness to play.

  Next, the display of the effect implemented in the fluctuation | variation display apparatus 9 is demonstrated. In the pachinko machine 1 according to the present embodiment, different types of effects such as a notice effect for notifying the possibility of a super reach and a possibility of a big hit and a super reach effect for notifying the possibility of a big hit are implemented. .

  The case where these notice effects and super reach effects are implemented will be described as an example. As shown in FIG. 12A, FIG. 12B, and FIG. 13, in the variation pattern that becomes the super reach effect, the notice effect S1 that is performed at the start of the change display, and the super effect after the notice effect S1. It is mainly composed of a change effect S2 until the reach effect is started and the super reach effect S3.

  Among these, in the notice effect S1, as shown in FIG. 12A, the variable display device 9 includes a space shuttle CH1 having, for example, a three-dimensionality (a large number of parallaxes) that protrudes greatly from the player by a three-dimensional image. The space shuttle CH2 having a smaller solidity (smaller number of parallaxes) than the space shuttle CH1, the small boat CH3 having a smaller stereoscopic degree (smaller number of parallaxes) than the space shuttle CH2, and a smaller stereoscopic degree (smaller number of parallaxes) than the small boat CH3. ) Star CH4, is displayed.

  In this way, by making a difference in the stereoscopic degree (the number of parallaxes) for each character displayed on the variable display device 9, the space shuttle CH1 having the highest degree of stereoscopic degree (the largest number of parallaxes) is more advantageous to the player. The space shuttle CH2, which is stereoscopically displayed so that it can be viewed with a wide viewing angle, is smaller than the space shuttle CH1 (the number of parallaxes is small), and the space shuttle CH2 is stereoscopically displayed so that it can be seen by the player with a relatively narrow viewing angle than the space shuttle CH1. Has been. Further, the small boat CH3 having a smaller degree of solidity (having a smaller number of parallaxes) than the space shuttle CH2 is stereoscopically displayed so that it can be seen by the player with a relatively narrow viewing angle than the space shuttle CH2, and the three-dimensionality is smaller than that of the small boat CH3. The small star CH4 (having a small number of parallaxes) is stereoscopically displayed so that it can be seen by the player with a relatively narrow viewing angle than the small boat CH3.

  For convenience of explanation, FIG. 12A shows a state in which all four types of characters from the space shuttle CH1 to the star CH4 are displayed on the variable display device 9, but in the notice effect S1. Actually, one or two of these characters are sequentially displayed step by step, and a step-up notice is given to notify the possibility of a big hit or super reach. For this reason, since the number of characters displayed on the variable display device 9 is smaller than in the case of super reach described later, the processing load on the VDP 262 that performs drawing processing and display processing in these effects is Since it is lighter than the implementation period of the super reach production, the processing load of the switching process for switching from the stereoscopic display to the non-stereoscopic display can be sufficiently covered, so that the player can change the display by pressing the operation button 516. The display in the device 9 is a cancelable effect capable of switching from stereoscopic display to non-stereoscopic display.

  Further, the fluctuation effect S2 is a period in which the display of the fluctuation display device 9 is changed after the end of the notice effect S1 and before the start of the super reach effect S3. For this reason, since it is a period when the production | presentation etc. which display a character etc. are not implemented, this fluctuation production S2 is made into the period when the display of a stereo image is not made. Therefore, since the stereoscopic display itself is not performed, it is natural that the stereoscopic image cancel operation is invalid.

  In these variation effects S2, a stereoscopic image may be displayed by displaying a specific character or the like.

  On the other hand, in the super reach production S3, as shown in FIG. 12 (b), in addition to the space shuttle CH1 to the star CH4, characters such as UFOCH5 and Saturn CH6 having substantially the same three-dimensionality as the space shuttle CH2 are simultaneously displayed. An effect displayed on the variable display device 9 is performed.

  For this reason, in the super reach effect S3, since the VDP 262 needs to perform drawing processing and display processing of more characters than the notice effect S1, the load on the VDP is very large. Since there is a fear that the processing load of the switching process for switching to non-stereoscopic display cannot be sufficiently covered, in the super reach production S3, the player presses the operation button 516 so that the display on the variable display device 9 is stereoscopically displayed. It is an uncancellable effect that cannot be switched from non-stereoscopic display.

  In the notice effect S1 and the super reach effect S3, the effect control CPU 86 causes the display control unit 213 to display an image based on the image data drawn by the above-described drawing control on the image liquid crystal panel 9a. In FIG. 9, a stereoscopic image is displayed.

  When performing these three-dimensional displays, the effect control CPU 86 controls the movement speed of each character to change according to the three-dimensionality of the three-dimensionally displayed character. Specifically, as shown in FIG. 12C, the effect control CPU 86 has a high degree of stereoscopicity of each character displayed as a stereoscopic image on the variable display device 9 (for example, the number of parallaxes is 9). The display is controlled so that the moving speed of the character becomes lower as the stereoscopic display is made so that the player can view with a wider viewing angle. In addition, the effect control CPU 86 has a medium degree of solidity (for example, five parallaxes) for each character displayed as a stereoscopic image on the variable display device 9, that is, the player is relatively narrower than the degree of stereoscopicity. When the visual angle is visible, the display is controlled so that the medium speed is higher than when the stereoscopic degree is large, and the stereoscopic degree of each character displayed as a stereoscopic image on the variable display device 9 is small (for example, the number of parallaxes). 3), that is, the display is controlled so that the moving speed of the character becomes higher as the stereoscopic display is made so that the player can view with a narrow viewing angle.

  Therefore, in this embodiment, as shown in FIG. 12A, the moving speed of the space shuttle CH1 displayed with the highest stereoscopic degree (the largest number of parallaxes) for the player is the slowest. The drawing of the space shuttle CH1 is controlled by the effect control CPU 86, and the space shuttle CH2, UFOCH5, Saturn CH6 so that the moving speed becomes faster as the three-dimensionality decreases with the space shuttle CH2, UFOCH5, Saturn CH6, and the small boat CH3. The rendering of the small boat CH3 is controlled by the effect control CPU 86. As a result, the moving speed of the star CH4 displayed with the smallest stereoscopic degree (the smallest number of parallaxes) is the fastest, and the moving speed of the space shuttle CH1 displayed with the highest stereoscopic degree (the largest number of parallaxes). Is controlled by the effect control CPU 86 so as to be the slowest.

  For this reason, even if the player moves his / her line of sight in accordance with the movement of a character whose stereoscopic display is large (close to the number of parallaxes) so as to be close to himself / herself, these stereoscopic degrees are large (parallax). Since the movement of the character itself is controlled slowly, the character close to you moves quickly, so that the player quickly moves the viewpoint quickly with the movement, so that the player's movement It is possible to prevent eyestrain from increasing and the player from feeling uncomfortable.

  As shown in FIGS. 13 to 15, the notice effect S1 of the present embodiment is composed of five periods of effect periods T1, T2, T3, T4, and T5. Among these effect periods T1, T2, T3, T4, and T5, the effect periods T1, T3, and T5 are more than the effect periods T2 and T4. Is a small change production period.

  In addition, during the presentation periods T1, T3, and T5, when the player presses the operation button 516 for a predetermined time (long press) in the notice presentation S1, the display on the stereoscopic image on the variable display device 9 is non-stereoscopic. It is possible to switch to image display. Hereinafter, switching from the display of the stereoscopic image to the display of the non-stereoscopic image in the change display device 9 will be described.

  As shown in FIG. 13 and FIG. 14, the effect control CPU 86 forms a stereoscopic image in the VRAM area in the drawing control unit 206, and the stereoscopic image with the number of parallaxes set at that time and the non-stereo image Start drawing in parallel. At the same time, the effect control CPU 86 causes the image liquid crystal panel 9a to display the stereoscopic image of the set number of parallax drawn by the display control unit 213, and displays the notice effect S1 in a state where the player can visually recognize the stereoscopic image. Start.

  In the series of presentation periods T1, T2, T3, T4, and T5 of the notice presentation stage S1, the production periods T1, T3, and T5 are displayed on the variable display device 9 as stereoscopic images more than the presentation periods T2 and T4. Since it is a small change effect period with a small number and operation, as described above, the load on the rendering process in the effect periods T2 and T4 is light in the VDP 262, so that the process for switching to a non-stereoscopic image can be performed. Yes. For this reason, the production periods T1, T3, and T5 are cancelable periods in which the player can press the operation button 516 to easily switch the display of the stereoscopic image of the announcement effect S1 to the display of the non-stereo image. On the other hand, in the production periods T2 and T4, on the contrary, since the load on the drawing process is relatively large, it is impossible to cancel the stereoscopic image display of the notice production S1 to the non-stereo image display. It is said that.

  In other words, in this embodiment, even if the player presses the operation button 516 during the production periods T2 and T4 where the number of characters and actions displayed as a stereoscopic image are large, the display cannot be switched to a non-stereoscopic image. Therefore, the player can be prevented from being confused by suddenly switching the display from a three-dimensional image to a non-stereoscopic image in which the number and movement of these characters are drastically changed.

  In the production periods T1, T3, and T5, which are cancelable periods, the production control CPU 86 displays “cancel OK” as shown in FIG. 12A, and a variable display that does not interfere with the display of the stereoscopic (3D) image. By displaying in the lower right position of the device 9, the player is notified that the display of the stereoscopic (3D) image can be canceled. On the other hand, in the production periods T2 and T4, which are non-cancellable periods, the production control CPU 86 does not display “cancel OK” as shown in FIG.

  In other words, the effect control CPU 86 can stop the display of the stereoscopic image when the effect of the stereoscopic image displayed on the variable display device 9 serving as the display means is the notice effect S1 that is a cancelable effect. Since the player has a function of notifying means for displaying “Cancel OK”, the player can accurately grasp whether or not the display of the stereoscopic image can be stopped.

  Then, as shown in FIG. 13, for example, when the player presses the operation button 516 for a predetermined time in an effect period T5 which is a cancelable period of the notice effect S1, the effect control CPU 86 performs variable display as a cancel operation. The stereoscopic image displayed on the device 9 is immediately switched to display a non-stereo image.

  When the stereoscopic image drawing area and the non-stereoscopic image drawing area are separately provided in the VRAM area as in this embodiment, the effect control CPU 86 presses the operation button 516 by the player for a predetermined time. Then, the drawing control unit 206 stops only the drawing of the stereoscopic image out of the drawing of the stereoscopic image and the non-stereo image in the VRAM area, and the display control unit 213 draws the stereoscopic image in parallel with the stereoscopic image. The previously non-stereoscopic image may be displayed on the image liquid crystal panel 9a instead of the stereoscopic image.

  In other words, the effect control CPU 86 enables the player to visually recognize the non-stereoscopic image displayed on the image liquid crystal panel 9a with both eyes. Thereafter, in the variable display device 9, after the period of the super reach effect S <b> 3 in which the variable display ends until the later-described 3D display stop period TS (see FIG. 16A), which will be described later, elapses. In addition, the display by the non-stereoscopic image is continued.

  That is, at the time of accepting a cancel operation from the player, since the non-stereo image is displayed and the display of the stereo image is stopped, it is possible to quickly switch from the stereo image to the non-stereo image. It can be avoided that the discomfort of the player due to the display continues.

  In the state where the stereoscopic image is displayed on the variable display device 9 in the notice effect S1, the rendering of the stereoscopic image and the rendering of the non-stereoscopic image are performed in parallel only during the rendering periods T1, T3, and T5, which are cancelable periods. Let In this way, when the player presses the operation button 516 during the production periods T1, T3, T5 in which the load on the VDP 262 is less than the production periods T2, T4, the non-stereoscopic images drawn in parallel are read out immediately. By displaying the non-stereoscopic image on the variable display device 9, the display can be quickly switched from the stereoscopic image display to the non-stereoscopic image display, and in the production periods T <b> 2 and T <b> 4 when a relatively high load is applied to the VDP 262. By not rendering the stereoscopic image, it is possible to prevent the processing load for rendering these non-stereo images from being further applied to the VDP 262.

  As shown in FIG. 14, when the player presses the operation button 516 for a predetermined time in the production period T4 that is an uncancellable production of the notice effect S1, the effect control CPU 86 displays the notice effect S1 in the effect period. The display of the stereoscopic image on the variable display device 9 is continued until an effect period T5 that is an effect that can be canceled from T4.

  Then, at the time when the notice effect S1 is switched from the effect period T4 to the effect period T5, the effect control CPU 86 sends the VRAM to the drawing control unit 206 in the same manner as when the operation button 516 is pressed for a predetermined time in the effect period T5. The drawing of the stereoscopic image in the area is stopped and the drawing of the non-stereo image is started, and the non-stereo image drawn in the VRAM area is displayed on the image liquid crystal panel 9a instead of the stereoscopic image.

  In the present embodiment, when the player presses the operation button 516 for a predetermined time in the production period T4 which is a production that cannot be canceled, the notice display device 9 is switched when the notice production S1 is switched from the production period T4 to the production period T5. However, when the player presses the operation button 516 for a predetermined time in the effect period T2, the notice effect S1 is changed from the effect period T2 to the effect period T3. The display of the stereoscopic image on the variable display device 9 is switched to the display of a non-stereo image at the time when the display is switched to.

  In other words, in this embodiment, the cancel operation itself is accepted even in the production periods T2 and T4 that are set as the non-cancelable period, and when the production periods T2 and T4 have passed, the display is shifted to non-stereoscopic display. Therefore, there is no need to perform a cancel operation again when the cancelable periods T3 and T5 are entered, and the player can reduce troublesome operations. However, the present invention is not limited to this, and these effects In periods T2 and T4, the acceptance of the cancel operation itself may be invalidated.

  As described above, in the 3D display suspension period TS in which the display of the stereoscopic image is prohibited when the display is switched from the display of the stereoscopic image to the display of the non-stereoscopic image by the cancel operation of the player, the same player operates Each time the button 516 is pressed for a predetermined time, it is extended.

  Specifically, as shown in FIG. 16A, when the stereoscopic display is started on the variable display device 9, the effect control CPU 86 cancels in advance from the time when the display of the stereoscopic image is started. The timing of the time set as the addition period TK is started.

  When the player presses the operation button 516 for a predetermined time during the cancel count addition period TK, the effect control CPU 86 adds 1 as a cancel count to a cancel counter (not shown) stored in the RAM 85.

  Then, if the production period in which the player presses the operation button 516 for a predetermined time is the production periods T1, T3, and T5 in which the production is cancelable, the production control CPU 86 uses that point as a switching point. If the production period in which 516 is pressed for a predetermined time is the production periods T2 and T4 which are productions that cannot be canceled, the time point when the production period T2 is switched to the production period T3 or the time point when the production period T4 is switched to the production period T5 is used as a switching point. As described above, the stereoscopic image display on the variable display device 9 is switched to the non-stereoscopic image display, and the 3D display suspension period TS is started.

  At this time, the effect control CPU 86 refers to the 3D display stop period determination table stored in the ROM 84 and the cancel counter stored in the RAM 85 as shown in FIG. The time of the 3D display suspension period TS corresponding to the number of cancels being performed is determined. The time of the 3D display stop period TS stored in this 3D display stop period determination table is stored in association with each number of cancellations so that it becomes a long time sequentially as the number of cancellations increases. . For this reason, the 3D display suspension period TS is continued for a longer time as the number of cancellations stored in the cancellation counter increases.

  By doing in this way, when the same player repeatedly performs a cancel operation, the 3D display stop period TS, which is the stereoscopic display stop period, is lengthened, so that it is possible to reduce the trouble of the player performing a cancel operation.

  When the 3D display suspension period TS ends, the effect control CPU 86 performs control to enable display of a stereoscopic image on the variable display device 9. And in the variable display implemented after making it possible, when the effect which displays a stereo image is made, control which performs this stereo image is performed. When an effect accompanied by display of a stereoscopic image is being executed on the variable display device 9 at the time when the 3D display stop period TS ends, the effect control CPU 86 performs the 3D display stop period until the execution of the effect ends. Extend the end of TS. For this reason, in the present embodiment, the effect displayed on the non-stereoscopic image on the variable display device 9 is not suddenly switched to the display on the stereoscopic image by the end of the 3D display suspension period TS. Can prevent confusion.

  On the other hand, as shown in FIG. 16B, when the player does not press the operation button 516 for a predetermined time in the cancel count addition period TK, the effect control CPU 86 determines when the cancel count addition period TK ends. The reset count stored in the RAM 85 is reset.

  That is, if the player who has once performed the cancel operation does not perform the cancel operation again when the stereoscopic image is displayed, that is, if the player accepts the display of the stereoscopic image, the cancel count is reset. Therefore, it can be avoided that the number of cancellations is unnecessarily added and the 3D display suspension period TS becomes unnecessarily long.

  In the present embodiment, the number of cancels is reset when the cancel count addition period TK, which starts counting with the start of the stereoscopic display, has elapsed without a cancel operation by the player. When the player performs the cancel operation a plurality of times, the number of cancellations is added, and after the 3D display stop period TS corresponding to the number of cancellations is set and the stereoscopic display is prohibited, the stereoscopic display can be performed again. Even if the game is finished, the effect with the stereoscopic display is not necessarily executed during the period until the player finishes the game. Therefore, the player plays the game without executing the effect with the stereoscopic display. When the game is finished, the other player starts the game, and when an effect with a three-dimensional display is executed, the other player performs a cancel operation for the first time. In spite of having performed, the addition to the cancellation frequency of the player who played before is implemented, and the very long 3D display stop period TS is set, and 3D display will not be implemented. In order to solve these problems, there is a possibility that the number of cancellations of the player who has played before may be carried over as the number of cancellations of other players. By resetting the number of cancellations on the condition that a player waiting demo designation command transmitted from the game control microcomputer 156 is received in response to the player changing and the pachinko machine 1 becoming inoperative It is possible to prevent these players from being carried over by players with different numbers of cancellations.

  Further, in this embodiment, when the customer waiting demonstration designation command is received, if it is during the 3D display stop period TS, the effect control CPU 86 ends the 3D display stop period TS, Control to enable stereoscopic display is performed.

  That is, in this embodiment, as described above, the 3D display suspension period TS is gradually increased as the number of cancellations increases in order to reduce the trouble of the player's cancellation operation. If the player changes during the set long 3D display stop period TS, the other player who started the next game will display the 3D display until the long 3D display stop period TS elapses. As a result, there is an inconvenience that the interest of the gaming machine will be significantly lowered, but the pachinko machine 1 is not in operation due to the change of the player. In response, the 3D display suspension period TS was changed to be replaced on condition that the customer waiting demonstration designation command transmitted from the game control microcomputer 156 was received. In the gaming skills who, since to be possible stereoscopic display from the start of the game, it is possible to avoid that the interest of the gaming machine as described above is significantly reduced.

  In the first embodiment, when the player presses the operation button 516 for a predetermined time, the display of the stereoscopic image displayed on the image liquid crystal panel 9a is switched to the display of the non-stereo image. You may make it provide separately the switch for exclusive use for switching the display of the stereo image displayed in 9a to the display of a non-stereo image.

  Furthermore, in the first embodiment, in the notice effect S1, the effect control CPU 86 draws a stereoscopic image and a non-stereo image in the VRAM area in the rendering control unit 206 in the effect periods T1, T3, and T5 in parallel. The rendering control unit 206 renders a stereoscopic image in the VRAM area in the rendering periods T2 and T4. If the rendering control unit 206 has sufficient processing capability, the rendering control CPU 86 In the notice effect S1, the regular drawing control unit 206 may cause the drawing of the stereoscopic image and the non-stereo image in the VRAM area in parallel.

  Next, the setting change of the number of parallaxes by the player will be described based on FIG. In the presentation periods T1, T3, and T5 in the notice presentation effect S1, the player presses the parallax number change button 517 for a predetermined time (holds down) to determine the number of parallaxes in the stereoscopic image on the variable display device 9 by the player. It is set as the period in which the number of parallaxes can be arbitrarily switched and changed. On the other hand, the production periods T2 and T4 in the notice effect S1 are three-dimensional images of the notice effect S1 because the load on the parallax image generation process in the parallax image generation unit 264 and the drawing process in the VDP 262 is relatively large. The number of parallaxes cannot be set by changing the number of parallaxes.

  The setting change of the number of parallaxes will be described in detail. First, in the production periods T1 and T2, the stereoscopic image display 1 is displayed with a predetermined number of parallaxes before the change. In addition, during the production period T1, a display capable of changing the number of parallaxes indicating that the number of parallaxes can be changed is displayed at a predetermined display location of the variable display device 9, and the CPU for production control 86 has a maximum number of parallaxes that can be set. A certain nine-parallax image is drawn in advance. In this way, display processing for displaying a parallax image that has been drawn in advance is performed regardless of the number of parallaxes up to a maximum of 9 parallaxes in the rendering period T1, which is a period in which the parallax number can be changed. Only by this, it is possible to perform quick display switching.

  Next, in the effect period T2 in which the number of parallaxes cannot be changed and an effect period T4 to be described later, the display capable of changing the number of parallaxes is not displayed, and the effect control CPU 86 performs drawing processing of parallax images with a maximum of 9 parallaxes. First, a parallax image having the number of parallaxes set in the production period is drawn.

  Next, in the production period T3, which is a period in which the number of parallaxes can be changed, the above-described display for changing the number of parallaxes is performed again, and the production control CPU 86 redraws the parallax image of 9 parallaxes that is the maximum number of parallaxes To process. The player presses the parallax number change button 517 as desired during the production period T3 in which the number of parallaxes can be changed, so that the stereoscopic image display 2 is performed with the changed number of parallaxes changed in the production period T3. Is displayed quickly.

  Next, in the production period T4, which is a period in which the number of parallaxes cannot be changed, the player presses the parallax number change button 517 as desired, so that the stereoscopic image display 2 still remains without being switched in the production period T4. However, the effect control CPU 86 receives and stores the changed number of parallaxes pressed by the player, and at the same time as the start of the effect period T5, which is the next changeable number of parallaxes, The stereoscopic image display 3 is quickly switched and displayed.

  In this way, even when a new parallax number is received from the player during the display of the stereoscopic image, by generating a parallax image corresponding to the number of sub-pixels, that is, the maximum number of parallax images, Compared to the case where a parallax image with a new number of parallaxes is generated after the acceptance, a parallax image with a new number of parallaxes can be quickly displayed on the sub-pixel. The migration can be carried out quickly.

  In addition, since the generation of the parallax image corresponding to the number of subpixels, that is, the generation of the maximum number of parallax images only needs to be performed during the period in which the number of parallaxes can be changed, The processing load for generating these parallax images can be reduced as compared with the case where it is always carried out.

  As described above, in the present embodiment, the effect control CPU 86 preliminarily draws a parallax image of 9 parallaxes that is the maximum parallax number that can be set in the period in which the parallax number can be changed. The CPU 86 may perform drawing processing only on the set number of parallax images of the predetermined number of parallaxes, and in this way, the load on the rendering processing of the effect control CPU 86 can be reduced.

  Furthermore, the effect control CPU 86 sets the number of parallaxes to be relatively small on condition that, for example, a predetermined game time (for example, 1 hour) elapses without the player setting the number of parallaxes as described above. (For example, 3 parallaxes) may be forcibly automatically changed. By doing so, it is possible to suppress eye strain given to the player. Alternatively, the effect control CPU 86 determines, for example, that the player who plays on the pachinko machine 1 has been changed on the condition that the non-operation of the hitting operation handle 5 continues for a certain period of time, and sets the number of parallaxes to a predetermined number of standard parallaxes. For example, it may be automatically changed to (e.g., 9 parallaxes), and by doing so, it is possible to provide a new player with a 3D image having a recommended standard parallax number.

  Next, the hold notice effect will be described with reference to FIG. 17. As described above, if a variable display cannot be started when a start winning is generated, the predetermined number 4 is set as the upper limit and the number of reserved memories is set. 1 is added, and a display corresponding to the added hold memory is displayed on the hold memory display unit of the variable display device 9.

  Whether or not a super reach occurs or a big hit in the variable display by the hold memory newly displayed on the hold memory display portion is determined by a pre-read lottery in the game control microcomputer 156 at the start winning of the hold memory. The lottery result is notified to the effect control board 80 as a start winning determination result command, so that the effect control CPU 86 can grasp the result, and it is high when the super reach occurs or is a big hit. When the super-reach or the big hit is not achieved, the square hold display different from the circle display, which is a normal hold display, is performed at a low rate.

  In addition, because the normal circle hold display is displayed as a non-stereo image, the circle hold display does not change even if it is moved to the left or right. Nine parallax images constituting the three-dimensional image of the reserved display stored in the image data ROM 263 are read and displayed in the sub-pixels included in the pixels for displaying the display, so that the left-right direction of the reserved display is displayed. By turning around, as shown in FIG. 17, it is possible to visually recognize that the holding display that has been seen in the square is a dice-like cube.

  When it is decided that the big hit will be finally made, a V-shaped mark is displayed on the side surface at a higher rate than the case where the big hit is decided. Depending on whether or not the V-shaped mark is displayed on the side of the cube that is the displayed hold display, it is suggested by the 3D display that there is a high possibility that the change display by the hold display will be a big hit. In order to confirm these suggestions, the player will go around in the left and right direction of the hold display, that is, the pachinko machine can not confirm the suggestion unless it goes around in the left and right direction of the hold display. 1 and can improve the interest of the pachinko machine 1.

  That is, in the hold notice effect of FIG. 17, the number of parallaxes of 9 that is the maximum number of parallaxes corresponding to the hold notice effect only for the sub-pixels of the pixels included in the display area for displaying the square hold display related to the specific effect. In this way, the display of the parallax image only needs to be performed for the pixels included in the display area for displaying the reserved display image. In the case where the parallax image is not read from the image data ROM 263 but is generated by the parallax image generation unit 264 as in the present embodiment, the sub-pixels of the pixels included in the display area are generated. Since only the parallax images to be displayed on the pixels need to be generated, the processing load for generating these parallax images can also be reduced.

  As described above, in the pachinko machine 1 according to the present embodiment, the possibility of becoming a big hit in the hold notice effect is suggested before the change due to the hold memory is started. In the super reach that occurs after the start of the fluctuation according to the above, it is suggested that the jackpot may be a big hit, and the points that suggest the possibility of the jackpot in the super reach are shown in FIGS. Based on

  FIG. 18 is an explanatory diagram showing random numbers used by the production control microcomputer 81. As shown in FIG. 18, in this embodiment, a random number SR1 for determining the number of parallaxes is used. Note that random numbers other than these may be used in order to enhance the effect.

  The parallax number determination random number SR1 is a random number used to determine the number of parallaxes serving as the stereoscopic degree of a predetermined character (space shuttle in this embodiment) displayed in the super reach, and has a numerical value range of 1 to 100. Takes a value.

  Note that a counter for generating random numbers of these SR1 is formed in the RAM 85. And the numerical value of each counter is updated in the random number update process in the timer interruption process which the microcomputer 81 for effect control implements by timer interruption for every predetermined time interval. That is, the value is incremented by one. When the count value of the counter exceeds the upper limit value of the random number (maximum value in the range shown in FIG. 18), the counter is returned to the lower limit value (minimum value in the range shown in FIG. 18). Reading the count value of the counter for generating the random number is called extracting the random number.

  The ROM 84 built in the effect control microcomputer 81 stores the parallax number determination table shown in FIGS. 19A to 19C. The parallax number determination table and the parallax number determination random number SR1 are stored. Is used to determine the number of parallaxes at a different rate depending on whether or not the big hit is finally reached.

  In the parallax number determination tables of the present embodiment, as shown in FIGS. 19A to 19C, there are different parallax number determination tables A to C for each of the parallax numbers set by the player as described above. For each of the parallax number determination tables A to C, each parallax is displayed for each of the “out of time” when the display result of the variable display is not the final jackpot display result and the “big hit time” as the big hit display result. The respective determination values of SR1 are assigned to the numbers “3 parallax”, “5 parallax”, “9 parallax”, and “9 parallax” so as to have the determination value number shown in FIG.

  The parallax number determination tables A to C used in the present embodiment will be described in detail. First, in the case where the player sets 9 parallaxes, the parallax number determination tables in the super reach are shown in FIG. The parallax number determination table A is used. In the parallax number determination table A, for “out of time”, 60 determination values for “3 parallax”, 25 determination values for “5 parallax”, and “7 parallax” 10 determination values are assigned to “9”, and 5 determination values are assigned to “9 parallax”. If there is a final deviation, “3 parallax”, “5” The space shuttle that appears in the super reach shown in FIG. 20 according to the items in which the extracted SR1 determination value is stored among the determination values stored in the “parallax”, “7 parallax”, and “9 parallax” items. As the number of parallaxes, “3 parallax”, “5 Difference "," 7 parallax "or" 9 parallax "is determined.

  For “big hit”, 5 determination values for “3 parallax”, 10 determination values for “5 parallax”, 25 determination values for “7 parallax”, and 60 determination values for “9 parallax” When the determination value is assigned and finally the big hit, the “3 parallax”, “5 parallax”, “7 parallax”, and “9 parallax” items corresponding to the “big hit” Of the stored determination values, “3 parallaxes”, “5 parallaxes”, “7” are set as the number of parallaxes of the space shuttle appearing in the super reach shown in FIG. 20 depending on the items in which the extracted SR1 determination values are stored. Either “parallax” or “9 parallax” is determined.

  Next, when the player sets 7 parallaxes, as shown in FIG. 19B, the parallax number determination table B is used. 20 determination values are assigned to “5 parallax”, 10 determination values are assigned to “7 parallax”, and 0 determination values, that is, determination values are not assigned to “9 parallax”, and eventually there is a shift. Stores the extracted SR1 determination value among the determination values stored in the items “3 parallax”, “5 parallax”, and “7 parallax” corresponding to the “out of time”. Depending on the item, “3 parallax”, “5 parallax”, or “7 parallax” is determined as the parallax number of the space shuttle that appears in the super reach shown in FIG.

  For “big hit”, 10 determination values are assigned to “3 parallax”, 20 determination values are assigned to “5 parallax”, and 70 determination values are assigned to “7 parallax”. When 0 judgment values, that is, judgment values are not assigned, and finally a big hit is made, each item of “3 parallax”, “5 parallax”, and “7 parallax” is associated with the “big hit time”. Of the stored determination values, “3 parallaxes”, “5 parallaxes”, “7” are set as the number of parallaxes of the space shuttle appearing in the super reach shown in FIG. 20 depending on the items in which the extracted SR1 determination values are stored. One of “parallax” is determined.

  Note that, as described above, in the parallax number determination table B used when the player sets 7 parallaxes, a determination value is assigned to “9 parallaxes” in both “out of time” and “big hit time”. Therefore, “9 parallax” is not determined as the parallax number of the space shuttle that appears in the super reach.

  Next, when the player sets 5 parallaxes, as shown in FIG. 19C, the parallax number determination table B is used. Twenty judgment values are assigned to “5 parallax”, and “7 parallax” and “9 parallax” are not assigned zero judgment values, that is, judgment values. Appears in the super reach shown in FIG. 20 according to the item in which the extracted SR1 decision value is stored among the decision values stored in the items “3 parallax” and “5 parallax” corresponding to “time”. Either “3 parallax” or “5 parallax” is determined as the parallax number of the space shuttle to be operated.

  For “big hit”, 20 determination values are assigned to “3 parallax”, 80 determination values are assigned to “5 parallax”, and “7 parallax” and “9 parallax” are 0 determination values, When the judgment value is not assigned and finally becomes a big hit, it is extracted from the judgment values stored in the items “3 parallax” and “5 parallax” corresponding to the “big hit” Depending on the item in which the determination value of SR1 is stored, either “3 parallax” or “5 parallax” is determined as the number of parallaxes of the space shuttle that appears in the super reach shown in FIG.

  Note that, as described above, in the parallax number determination table B used when the player sets 5 parallaxes, both “7 parallax” and “9 parallax” in both “out of time” and “big hit” are shown. Since no determination value is assigned, “7 parallax” and “9 parallax” are not determined as the number of parallaxes of the space shuttle that appears in the super reach.

  In this embodiment, as shown in FIGS. 19A to 19C, when there is a final shift, the number of determination values assigned to “3 parallax” which is a small number of parallaxes is the largest. In many cases, the number of determination values assigned to “5 parallax”, “7 parallax”, and “9 parallax”, which are larger than the “3 parallax”, is sequentially reduced, and finally the big hit In this case, the number of assigned determination values is the smallest for “3 parallax” which is a small number of parallaxes, and “5 parallax”, “7 parallax” and “9 parallax” which are larger than the “3 parallax”. ”Is sequentially set so that the number of assigned decision values is increased. By setting in this way, a small number of parallaxes can be easily determined when there is a final deviation, and finally a big hit. Sometimes a large number of parallaxes is easily determined.

  That is, as shown in FIG. 20 (A), after the same decorative design is derived and stopped in the “left” and “right” variable display areas (symbol display area), For example, when the shutter (not shown) is operated and the front surface of the variable display device 9 is closed, as shown in FIG. Display of a stereoscopic image (parallax image) is started from the time when the variable display device 9 is opened and the state where the variable display device 9 is visible, and an effect image in which the space shuttle by the stereoscopic image crosses the screen while avoiding enemy attacks is displayed. (FIG. 20C).

  At this time, the parallax number of the image of the space shuttle crossing these screens is the parallax image of the parallax number determined by the parallax number determination table and SR1 as described above at the start of the super reach production. 3D display.

  That is, when the number of parallaxes is large (for example, the number of parallaxes is 9), for example, by turning around in the traveling direction of the space shuttle, an image viewed from almost the front of the space shuttle can be visually recognized. As shown in (C1), an image with a high degree of three-dimensionality is displayed due to the large number of parallaxes, and after successfully fending off the enemy, landing is completed as shown in FIG. 20 (D1), and all the decorative symbols are arranged. When the ratio of big hits is high, but the number of parallaxes is small (for example, the number of parallaxes is 3), even when the space shuttle travels in the direction of travel, the image of the space shuttle viewed almost from the front cannot be viewed. An image viewed from a slight angle can be visually recognized, that is, as shown in FIG. 20C, an image with a low degree of stereology is displayed due to a small number of parallaxes, and then the enemies cannot be completely avoided. Figure 20 fails to land (D), the proportion of decorative pattern is 20 (E) out without align all increases.

  Therefore, when the number of parallax of the space shuttle appearing in Super Reach is large and the degree of stereo is high, the possibility of a big hit is high, and when the number of parallax of the space shuttle is small and the degree of stereo is small, there is a possibility that it is off. Since it becomes high, the possibility of a big hit is suggested by the number of parallaxes.

  That is, in the case of suggesting a so-called expectation degree that indicates whether or not there is a high possibility that a big hit, which is a gaming state advantageous to the player, due to the difference in the number of parallaxes in the production, as in the present embodiment, Is set for each number of parallaxes that can be set, and a parallax number determination table for determining the number of parallaxes in the effect at or below the number of parallaxes is expected, and the expectation is made using the parallax number determination table corresponding to the number of parallaxes set by the player Since the effects suggesting the degree are implemented, it is possible to eliminate the fact that the number of parallaxes is determined more than the number of parallaxes set by the player in the effects suggesting the degree of expectation. It is possible to prevent the occurrence of inconvenience that the presentation is performed with the number of parallaxes larger than the number of parallaxes set by the player, and the determined number of parallaxes is the number of parallaxes set by the player Ri is large process of determining whether or not there is no need to carry out such, can also be reduced processing load and the like necessary for these determination processing and the like.

  As a modification of the present invention, as shown in FIGS. 21 and 22, the same parallax number determination table D and correction rule may be used regardless of the parallax number set by the player.

  The parallax number determination table D and the correction rule will be described in detail. First, when the player sets 9 parallaxes, as shown in FIGS. 21 and 22, based on the correction rule “as determined parallax number of the determination table”. , The parallax number determination table D is used, and for “out of time”, 70 determination values for “3 parallax”, 15 determination values for “5 parallax”, 10 determination values for “7 parallax”, When five determination values are assigned to “9 parallax”, and finally a deviation occurs, “3 parallax”, “5 parallax”, “7 parallax”, Of the determination values stored in each item of “9 parallax”, “3 parallax” as the number of parallaxes of the space shuttle that appears in the super reach shown in FIG. 20 according to the item in which the extracted SR1 determination value is stored. , “5 parallax”, “7 parallax”, “9 parallax” One is determined.

  For “big hit”, 10 determination values for “3 parallax”, 20 determination values for “5 parallax”, 30 determination values for “7 parallax”, and 40 determination values for “9 parallax” When the determination value is assigned and finally the big hit, the “3 parallax”, “5 parallax”, “7 parallax”, and “9 parallax” items corresponding to the “big hit” Of the stored determination values, “3 parallaxes”, “5 parallaxes”, “7” are set as the number of parallaxes of the space shuttle appearing in the super reach shown in FIG. 20 depending on the items in which the extracted SR1 determination values are stored. Either “parallax” or “9 parallax” is determined.

  Next, when the player sets 7 parallaxes, as shown in FIG. 21 and FIG. 22, the parallax number determination table based on the correction rule “If the determined parallax number of the determination table is 9 parallaxes, it is corrected to 7 parallaxes”. D is used, and for “out of time”, 70 decision values for “3 parallax”, 15 decision values for “5 parallax”, and 10 decision values for “7 parallax”. When a total of 15 determination values including 5 determination values of “parallax” are assigned and finally a deviation occurs, “3 parallax” and “5 parallax” corresponding to the “out of phase” are provided. ”And“ 7 parallax ”, among the determination values stored in the items of“ 7 parallax ”, the number of parallaxes of the space shuttle that appears in the super reach shown in FIG. Any of “parallax”, “5 parallax”, and “7 parallax” is determined.

  For “big hit”, 10 determination values for “3 parallax”, 20 determination values for “5 parallax”, and “9 parallax” for 30 determination values for “7 parallax”. A total of 70 decision values including 40 decision values are assigned, and when the big hit is finally made, “3 parallax”, “5 parallax”, “ Among the determination values stored in each item of “7 parallax”, “3 parallax” as the number of parallaxes of the space shuttle appearing in the super reach shown in FIG. 20 according to the item storing the extracted SR1 determination value, Either “5 parallax” or “7 parallax” is determined.

  Note that, as described above, in the parallax number determination table D and the correction rule used when the player sets 7 parallaxes, the determination parallax number of the determination table is 9 for both “at the time of loss” and “at the time of big hit”. In the case of parallax, since the parallax is corrected to 7 parallax and no determination value is assigned to “9 parallax”, “9 parallax” is not determined as the number of parallaxes of the space shuttle that appears in super reach.

  Next, when the player sets 5 parallaxes, as shown in FIGS. 21 and 22, the number of parallaxes is based on the correction rule “corrected to 5 parallaxes when the determined parallax number is 9 or 7 parallaxes”. The determination table D is used. For “out of time”, 70 determination values are set for “3 parallax”, and “5 parallax” is 10 determination values for “7 parallax” and “7 parallax” and “ When a total of 30 determination values including 5 determination values of “9 parallax” are assigned and finally a deviation occurs, “3 parallax”, “5” Among the determination values stored in each item of “parallax”, “3 parallax” and “3 parallax” as the number of space shuttle parallax appearing in the super reach shown in FIG. 20 according to the item in which the extracted SR1 determination value is stored. One of “5 parallaxes” is determined.

  For “big hit”, 10 determination values for “3 parallax”, 30 determination values for “7 parallax” for “5 parallax”, and “9 parallax” for “7 parallax”. When 90 decision values including 40 decision values are assigned and finally the big hit, each of “3 parallax” and “5 parallax” corresponding to the “big hit” Of the determination values stored in the items, the number of the disparity of the space shuttle that appears in the super reach shown in FIG. 20 is “3 parallax” or “5 parallax” depending on the item in which the extracted SR1 determination value is stored. Either is determined.

  Note that, as described above, in the parallax number determination table D and the correction rule used when the player sets 5 parallaxes, the determination table has a determined parallax number of 9 for both “at the time of loss” and “at the time of big hit”. In the case of 7 parallaxes, the parallax is corrected to 5 parallaxes, and since no determination value is assigned to “9 parallax” and “7 parallax”, the number of parallaxes of the space shuttle that appears in super reach is “9 parallax”, “7 The “parallax” is never determined.

  Finally, when the player sets 3 parallaxes, as shown in FIGS. 21 and 22, the parallax number determination table is based on the correction rule “All the parallax numbers determined in the determination table are corrected to 3 parallax except for 3 parallaxes”. D is used, and for “3 parallax”, 70 judgment values, 15 judgment values of “5 parallax”, 10 judgment values of “7 parallax”, and “9 parallax” All the 100 judgment values including the five judgment values are assigned, and when there is a final deviation, the super reach shown in FIG. “3 parallax” is always determined as the parallax number of the appearing space shuttle.

  For “big hit”, “3 parallax” has 10 determination values, “5 parallax” has 20 determination values, “7 parallax” has 30 determination values, and “9 parallax” has 40 determination values. When a total of 100 judgment values including the judgment values are assigned and finally the big hit, the space appearing in the super reach shown in FIG. 20 corresponding to the “big hit time”. “3 parallax” is always determined as the parallax number of the shuttle.

  Note that, as described above, in the parallax number determination table D and the correction rule used when the player sets three parallaxes, the determination parallax number of the determination table is 3 for both “out of time” and “at the time of big hit”. Other than the parallax, since the parallax is corrected to 3 parallax and no determination value is assigned to “9 parallax”, “7 parallax”, and “5 parallax”, “9 parallax”, “7 parallax” and “5 parallax” are not determined.

  Thus, even if a determination table corresponding to each number of parallaxes that can be designated by the player using the parallax number change button 517 is not prepared and stored in advance, the suggestion effect that matches the number of parallaxes received by the player The suggestion effect by the stereoscopic image can be implemented.

  Next, a gaming machine according to the second embodiment will be described with reference to FIGS. In addition, the same structure as the said Example and the overlapping structure are abbreviate | omitted.

  A slot machine, which is a gaming machine to which the present invention is applied, will be described with reference to the drawings. A slot machine 1001 of this embodiment is rotatable to a housing 1001a having an open front surface and a side end of the housing 1001a. The front door 1001b is pivotally supported.

  Inside the casing 1001a of the slot machine 1001 of this embodiment, reels 1002L, 1002C, and 1002R (hereinafter, left reel, middle reel, and right reel) in which a plurality of types of symbols are arranged on the outer periphery are arranged in parallel in the horizontal direction. As shown in FIG. 26, three consecutive symbols out of the symbols arranged on the reels 1002L, 1002C, and 1002R are arranged so as to be seen from the see-through window 1003 provided on the front door 1001b.

  When a game is played in the slot machine 1001 of this embodiment, first, medals are inserted from the medal insertion unit 1004, or credits are used to set the number of bets. To use credit, the MAXBET switch 1006 may be operated. When a predetermined number of bets determined according to the gaming state are set, the pay lines L1 to L5 (see FIG. 26) become valid, and the operation of the start switch 1007 is valid, that is, the game can be started. It becomes a state. In the present embodiment, when the prescribed number of bets is set to three regardless of the gaming state and the prescribed number of bets is set, the pay lines L1 to L5 become valid. In addition, when a medal is inserted exceeding the maximum number out of the prescribed number corresponding to the gaming state, the amount is added to the credit.

  The winning line is a line that is set to determine whether the combination of symbols displayed on the perspective windows 1003 of the reels 1002L, 1002C, and 1002R is a winning symbol combination. In this embodiment, as shown in FIG. 26, a winning line L1 set across the symbols arranged in the middle stage of each reel 1002L, 1002C, 1002R, and the symbols arranged in the upper stage of each reel 1002L, 1002C, 1002R. The winning line L2 set in the above, the winning line L3 set across the symbols arranged in the lower stage of each reel 1002L, 1002C, 1002R, the upper stage of the reel 1002L, the middle stage of the reel 1002C, the lower stage of the reel 1002R, that is, lower right. There are five types of winning lines: a winning line L4 set across the arranged symbols, a lower stage of the reel 1002L, a middle stage of the reel 1002C, an upper stage of the reel 1002R, that is, a winning line L5 set across the symbols arranged in the upward direction. It is defined as.

  When the start switch 1007 is operated while the game can be started, the reels 1002L, 1002C, and 1002R rotate, and the symbols of the reels 1002L, 1002C, and 1002R continuously change. When one of the stop switches 1008L, 1008C, 1008R is operated in this state, the rotation of the corresponding reels 1002L, 1002C, 1002R is stopped, and the display result is derived and displayed on the fluoroscopic window 3.

  Then, when all the reels 1002L, 1002C, and 1002R are stopped, one game is finished, and a combination of symbols (hereinafter also referred to as roles) that are validated and predetermined on the winning line are each reels 1002L, 1002C, and 1002R. When the display result is stopped, a winning occurs, and a predetermined number of medals are awarded to the player and added to the credit. Further, when the credit reaches the upper limit number (50 in this embodiment), medals are paid out directly from the medal payout opening 1009 (see FIG. 26). In addition, when a combination of symbols with payout of medals is arranged on a plurality of winning lines that are activated, the number of payouts determined for each of the combinations of symbols that are activated and aligned on the winning line is totaled, The total number of medals will be awarded to the player. However, an upper limit (15 in this embodiment) is set for the number of medals to be awarded in one game, and when the total number of medals exceeds the upper limit, the upper limit number of medals is awarded. It will be. In addition, when the combination of symbols accompanied by the transition of the gaming state is stopped as a display result of each reel 1002L, 1002C, 1002R on the winning line, the gaming state is shifted according to the combination of symbols. ing.

  FIG. 27 is a block diagram showing the configuration of the slot machine 1001. As shown in FIG. 27, the slot machine 1001 is provided with a game control board 1040, an effect control board 1090, and a power supply board 1101. The game state is controlled by the game control board 1040, and the game state is controlled by the effect control board 1090. The power supply board 1101 generates drive power for the electrical components constituting the slot machine 1001 and supplies the drive power to each unit.

  The power supply board 101 is supplied with AC100V power from the outside, and a DC voltage necessary for driving electrical components constituting the slot machine 1001 is generated from the AC100V power supply, and the game control board 1040 and the game control board 1040 are generated. It is supplied to the production control board 1090 connected via the.

  Further, the above-described hopper motor 1034b, payout sensor 1034c, full tank sensor 1035a, setting key switch 1037, reset / setting switch 1038, and power switch 1039 are connected to the power supply board 1101.

  On the game control board 1040, the above-described MAXBET switch 1006, start switch 1007, stop switches 1008L, 1008C, 1008R, settlement switch 1010, reset switch 1023, stop switch 1036a, automatic settlement switch 1036b, insertion medal sensor 1031, door opening The detection switch 1025, reel sensors 1033L, 1033C, and 1033R are connected, and the above-described payout sensor 1034c, full tank sensor 1035a, setting key switch 1037, and reset / setting switch 1038 are connected via the power supply board 1101. Detection signals from these connected switches are input.

  The game control board 1040 includes the credit display 1011, the game auxiliary display 1012, the payout display 1013, 1 to 3 BET LEDs 1014 to 1016, the insertion request LED 1017, the start valid LED 1018, the waiting LED 1019, the replaying LED 1020, and the BET A switch valid LED 1021, left, middle, and right stop valid LEDs 1022L, 1022C, 1022R, a set value display 1024, a flow path switching solenoid 1030, reel motors 1032L, 1032C, 1032R are connected to each other, and are described above via the power supply board 1101. The hopper motor 1034b is connected, and these electric components are driven based on the control of a main control unit 1041 described later mounted on the game control board 1040.

  The game control board 1040 is composed of a microcomputer having a main CPU 1041a, ROM 1041b, RAM 1041c, and I / O port 1041d, and a main control unit 1041 for controlling the game, a random number in a predetermined range (0 to 65535 in this embodiment). , A pulse oscillator 1043 for supplying a constant frequency clock signal to the random number circuit 1042, and detection signals input from switches connected to the game control board 10040 directly or via the power supply board 1101 A switch detection circuit 1044, a motor drive circuit 1045 that controls the drive of the reel motors 1032L, 1032C, and 1032R, a solenoid drive circuit 1046 that controls the drive of the flow path switching solenoid 1030, various displays connected to the game control board 1040, The LED drive circuit 1047 that controls the driving of the ED and the power supply voltage supplied to the slot machine 1001 are monitored, and when a voltage drop is detected, a voltage drop signal indicating that is output to the main control unit 1041. A disconnection detection circuit 1048, a reset circuit 1049 for supplying a reset signal to the main CPU 1041a when power is turned on or when an initialization command is not input from the main CPU 1041a, and other various devices and circuits are mounted.

  The main CPU 1041a has an interrupt function (including an interrupt prohibition function) such as a timekeeping function and a timer interrupt, and executes a program (described later) stored in the ROM 1041b to perform various control processes related to the progress of the game. In addition, each part of the control circuit mounted on the game control board 1040 is controlled directly or indirectly. The ROM 1041b stores fixed data such as programs executed by the main CPU 1041a and various tables. The RAM 1041c is used as a work area when the main CPU 1041a executes a program. The I / O port 1041d inputs / outputs a control signal to / from each circuit connected via a signal input / output terminal included in the main control unit 1041.

  The main control unit 1041 is also supplied with backup power even during a power failure, and the data stored in the RAM 1041c is held while the backup power is being supplied.

  The main CPU 1041a transmits various commands to the effect control board 1090 via the I / O port 1041d.

  An effect switch 1056 is connected to the effect control board 1090, and when the detection signal corresponding to each direction of the cross key in the effect switch 1056 is input, the effect control board 1090 is operated by the player. It is possible to grasp the specified direction according to presence / absence and operation.

  In addition, on the effect control board 1090, the image liquid crystal panel 1051 (see FIG. 26) disposed on the front door 1001b of the slot machine 1001 and the light emission provided by being attached to substantially the entire front surface of the image liquid crystal panel 1051. An effect display device 1050 having a vertical lenticular sheet 1057 as a direction limiting element is connected to an effect device such as an effect effect LED 1052, speakers 1053 and 1054 (see FIG. 27), and the above-described reel LED 1055 as shown in FIG. These effect devices are driven based on control by a later-described sub-control unit 1091 mounted on the effect control board 1090.

  As shown in FIG. 26, a parallax number change button 1058 for setting the parallax number of the stereoscopic image is provided at the upper position of the effect switch 1056 on the front surface of the image liquid crystal panel 1051 so that the player can press it. It has been.

  In this embodiment, the sub-control unit 1091 mounted on the effect control board 1090 controls the output of the effect devices such as the image liquid crystal panel 1051, effect effect LED 1052, speakers 1053, 1054, and reel LED 1055. However, an output control unit that directly controls the output of the effect device is mounted on the effect control board 1090 or another board separately from the sub control part 1091, and the sub control part 1091 is based on a command from the main control part 1041. The output pattern of the effect device may be determined, and the output control unit may control the output of the effect device based on the output pattern determined by the sub control unit 1091. In such a configuration, the sub control unit 1091 and the output are controlled. The output control of the effect device is performed by both of the control units.

  In the present embodiment, the image liquid crystal panel 1051, the effect effect LED 1052, the speakers 1053 and 1054, and the reel LED 1055 are illustrated as the effect devices. However, the effect device is not limited to these, and is mechanically driven, for example. A display device or a mechanically driven item may be applied as the rendering device.

  Further, the image liquid crystal panel 1051 is an image display device for displaying a two-dimensional (2D) image or a stereoscopic (3D) image, and has a backlight (not shown) on the back thereof. On the front surface of the image liquid crystal panel 1051, a vertical lenticular sheet 1057 as an emission direction limiting element is attached to almost the entire surface of the image liquid crystal panel 1051 to enable integral imaging type autostereoscopic display. ing.

  The effect control board 1090 is composed of a microcomputer having a sub CPU 1091a, ROM 1091b, RAM 1091c, and I / O port 1091d in the same manner as the main control part 1041, and includes a sub control part 1091 for effect control and an effect control board 1090. Display control circuit 1092 for controlling the display of the image liquid crystal panel 1051 connected to the LED, an LED driving circuit 1093 for controlling the driving of the effect LED 1052 and the reel LED 1055, and an audio output circuit 1094 for controlling audio output from the speakers 1053 and 1054. From the reset circuit 1095 that gives a reset signal to the sub CPU 1091a when the power is turned on or when the initialization command from the sub CPU 1091a is not input for a certain period of time, and the effect switch 1056 connected to the effect control board 1090 A switch detection circuit 1096 that detects the detected detection signal, a clock device 1097 that outputs time information including date information and time information, and a power supply voltage supplied to the slot machine 1001 are monitored, and when a voltage drop is detected, A power interruption detection circuit 1098 that outputs a voltage drop signal indicating that to the sub CPU 1091a, a parallax number setting circuit 1099 for displaying a stereoscopic image with the parallax number set and changed by the parallax number change button 1058, and the passage width An input / output port 1090 ′ for inputting / outputting correction data accompanying a change in the viewpoint position of the passerby due to the difference, and other circuits are mounted, and the sub CPU 1091a is transmitted from the game control board 1040. In response to the command, it performs various controls for performing the performance and controls the control circuit mounted on the performance control board 1090. And it controls the respective units directly or indirectly. Among these, the ROM 1091b stores a time chart of each moving image and a 3D display stop period determination table in moving image reproduction to be described later, and a RAM 1091c stores a cancel counter (not shown).

  For the display of a stereoscopic image in the second embodiment, an integral imaging type naked eye is formed by an image liquid crystal panel 1051 and a vertical lenticular sheet 1057 as an emission direction limiting element provided in front of the image liquid crystal panel 1051. This is realized by an image display device including a stereoscopic display liquid crystal display device, and a specific display mode of the stereoscopic image is the same as that of the first embodiment described above.

  That is, the slot machine 1001 of the second embodiment is also capable of displaying a stereoscopic image by the integral imaging method similarly to the pachinko machine 1 of the first embodiment, and various similar to the pachinko machine 1 of the first embodiment. The game machine of the present invention is not limited to the pachinko machine 1 and may be a slot machine that uses medals as a game medium. The number of pachinko balls and medals that are enclosed and rented inside the gaming machine, and the number of pachinko balls and medals awarded in response to winnings, are added to these game media. Without using enclosed game machines where the number of medals is subtracted and memorized, pachinko balls and medals are used, for example, according to the value and winnings of points and points lent out in response to loan requests All the value of such point or points is stored as credits, that may be capable of gaming machine performing a game by using only the value stored as credits. In this case, these points, points, and the like correspond to game media, and credits become game value.

  Although the embodiments of the present invention have been described with reference to the drawings, the specific configuration is not limited to these embodiments, and modifications and additions within the scope of the present invention are included in the present invention. It is.

  For example, in the above embodiment, the plane side of the vertical lenticular sheet is attached to the image liquid crystal panels 9b and 1051, but the present invention is not limited to this, and as shown in FIG. The plane side of these vertical lenticular sheets may be arranged on the opposite side to the above-mentioned embodiment so that the player side is the curved surface side that bulges in a substantially bowl shape and is the image liquid crystal panel 9b, 1051 side. In this case, the display control of the parallax image displayed on the sub-pixels p1 to p9 is reversed left and right as compared with the case of the above-described embodiment. Specifically, the parallax image from the rightmost is set to the leftmost. Control may be performed so that the parallax image from the leftmost is displayed in the subpixel located and the parallax image from the leftmost is displayed in reverse in the subpixel located in the rightmost.

  In the above embodiment, the form of determining the number of parallaxes of characters appearing in super reach using the parallax number determination table is illustrated, but the present invention is not limited to this, The notice effect S1 may be used, or as the hold notice effect shown in FIG. 17, the number of parallaxes in these effects may be determined using a parallax number determination table.

  In the above embodiment, the cancelable period and the changeable period of the number of parallaxes are exemplified as the same period. However, the present invention is not limited to this, and these periods are completely included. It may be set as an individual period.

  Moreover, although the said Example illustrated the form which provided the parallax number change button 517 separately so that a player can change the parallax number even during execution of production, this invention is limited to this. In the parallax number change screen displayed on the variable display device 9 by operating the operation button 516 when the variable display on the variable display device 9 is not performed, the operation lever is not changed. By operating 600, the player may be able to change the number of parallaxes.

  Further, in the above-described embodiment, various character images related to the notice effect and the super reach effect during the variable display of the decorative symbols are illustrated as the three-dimensional image displayed on the variable display device 9 serving as the three-dimensional image display device in the present invention. However, the present invention is not limited to this, and these three-dimensional images include images that are displayed when the decorative symbols are not being displayed, for example, demonstration effects that are executed when the pachinko machine 1 is not in operation. May be a demo image of a game displayed at, a jackpot image displayed in a jackpot effect executed during the jackpot, or the like. That is, these stereoscopic images may be any images that include a stereoscopic image related to the game, but may include not only a stereoscopic image related to the game but also a stereoscopic image not related to the game.

DESCRIPTION OF SYMBOLS 1 Pachinko machine 6 Game board 9 Fluctuation display apparatus 9a Image liquid crystal panel 9b Vertical lenticular sheet 9c Backlight 10 Normal symbol display 13 Movable piece 80 Production control board 81 Production control microcomputer 156 Game control microcomputer 206 Drawing control part 210 SDRAM (VRAM)
211 Data transfer control unit 213 Display control unit 262 VDP
263 Image data ROM
H.264 Parallax image generation unit 516 Operation button 517 Parallax number change button 1001 Slot machine 1058 Parallax number change button

Claims (1)

A gaming machine capable of performing a predetermined game and capable of displaying a stereoscopic image,
An image display body in which pixels composed of a plurality of sub-pixels capable of displaying a plurality of parallax images having different viewpoints constituting the stereoscopic image are repeatedly arranged adjacent to each other, and an emission direction of each parallax image light emitted from each sub-pixel A stereoscopic image display device capable of displaying a stereoscopic image including the parallax image, and an emission direction limiting element that limits the emission direction to a predetermined direction corresponding to the parallax image;
Display control means for controlling display of the stereoscopic image display device;
A parallax number receiving means for receiving, from a player, the number of parallaxes that is the number of different parallax images displayed on the sub-pixels included in the pixel;
With
The gaming machine according to claim 1, wherein the display control unit performs control to display a parallax image having the number of parallaxes received by the parallax number receiving unit on the sub-pixel.

Images